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Archive for the ‘Systemic Inflammatory Response Related Disorders’ Category

Innovations in Tumor Immunology

Posted in Human Immune System in Health and in Disease, Systemic Inflammatory Response Related Disorders, tagged , , , , , , , on April 12, 2013| Leave a Comment »

Reporter: Aviva Lev-Ari, PhD, RN

 

The healing element is also the enemy – an enigma probed by Hebrew University Lautenberg Center researchers

April 3, 2013

Jerusalem – The same factor in our immune system that is instrumental in enabling us to fight off severe and dangerous inflammatory ailments is also a player in doing the opposite at a later stage, causing the suppression of our immune response.

Why and how this happens and what can be done to mediate this process for the benefit of mankind is the subject of an article published online in the journal Immunity by Ph.D. student Moshe Sade-Feldman and Professor Michal Baniyash of the Lautenberg Center for General and Tumor Immunology at The Hebrew University Faculty of Medicine.
Chronic inflammation poses a major global health problem and is common to different pathologies — such as autoimmune diseases (diabetes, rheumatoid arthritis, lupus and Crohn’s), chronic inflammatory disorders, chronic infections (HIV, leprosy, leishmaniasis) and cancer. Cumulative data indicate that at a certain stage of each of these diseases, the immune system becomes suppressed and results in disease progression.
In their previous work, The Hebrew University researchers had shown that in the course of chronic inflammation, unique immune system cells with suppressive features termed myeloid derived suppressor cells (MDSCs) are generated in the bone marrow and migrate into the body’s organs and blood, imposing a general immune suppression.
A complex network of inflammatory compounds persistently secreted by the body’s normal or cancerous cells support MDSC accumulation, activation and suppressive functions. One of these compounds is tumor necrosis factor-a (TNF-a), which under acute immune responses (short episodes), displays beneficial effects in the initiation of immune responses directed against invading pathogens and tumor cells.
However, TNF-a also displays harmful features under chronic responses, as described in pathologies such as rheumatoid arthritis, psoriasis, type II diabetes, Crohn’s disease and cancer, leading to complications and disease progression. Therefore, today several FDA- approved TNF-a blocking reagents are used in the clinic for the treatment of such pathologies.
What has remained unclear until now, however, is just how TNF-a plays its deleterious role in manipulating the host’s immune system towards the generation of a suppressive environment.
In their work, The Hebrew University researchers discovered the mechanisms underlying the TNF-a  function, a key to controlling this factor and manipulating it, perhaps, for the benefit of humans.  Using experimental mouse models, they showed unequivocally how TNF-a is critical in the induction of immune suppression generated during chronic inflammation. The TNF-a was seen to directly affect the accumulation and suppressive function of MDSCs, leading to an impaired host’s immune responses as reflected by the inability to respond against invading pathogens or against developing tumors.
Further, the direct role of how TNF-a works in humans was mimicked by injecting the FDA-approved anti-TNF-a drug, etanercept, into mice at the exacerbated stage of an inflammatory response, when MDSC accumulation was observed in the blood. The etanercept treatment changed the features of MDSCs and abolished their suppressive activity, leading to the restoration of the host’s immune function.
Taken together, the results show clearly how the TNF-a-mediated inflammatory response, whether acute or chronic, will dictate its beneficial or harmful consequence on the immune system. While during acute inflammation TNF-a is vital for immediate immune defense against pathogens and clearance of tumor cells, during chronic inflammation — under conditions where the host is unable to clear the pathogen or the tumor cells — TNF-a is harmful due to the induction of immune suppression.
These results, providing new insight into the relationship between TNF-a and the development of an immune suppression during chronic inflammation, may aid in the generation of better therapeutic strategies against various pathologies when elevated TNF-a and MDSC levels are detected, as seen, for example, in tumor growths.

 

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Nobel Laureate Jack Szostak Previews his Plenary Keynote for Drug Discovery Chemistry

Posted in Advanced Drug Manufacturing Technology, Biological Networks, Gene Regulation and Evolution, Biomarkers & Medical Diagnostics, BioSimilars, Chemical Biology and its relations to Metabolic Disease, Chemical Genetics, Computational Biology/Systems and Bioinformatics, Disease Biology, Small Molecules in Development of Therapeutic Drugs, Drug Delivery Platform Technology, Genome Biology, Genomic Testing: Methodology for Diagnosis, Interviews with Scientific Leaders, Molecular Genetics & Pharmaceutical, Personalized and Precision Medicine & Genomic Research, Pharmaceutical Industry Competitive Intelligence, Pharmaceutical R&D Investment, Proteomics, Scientist: Career considerations, Systemic Inflammatory Response Related Disorders, tagged , , , on April 9, 2013| 2 Comments »

Nobel Laureate Jack Szostak Previews his Plenary Keynote for Drug Discovery Chemistry

Reporter: Aviva Lev-Ari, PhD, RN

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Nobel Laureate Jack Szostak Previews his Plenary Keynote for Drug Discovery Chemistry

Word Cloud by Daniel Menzin

Drug Discovery Chemistry

Optimizing Small Molecules for Tomorrow’s Therapeutics

April 16-18, 2013 | San Diego, CA

Conference Brochure

http://www.drugdiscoverychemistry.com/uploadedFiles/Drug_Discovery_Chemistry/13/2013-Drug-Discovery-Chemistry-Brochure.pdf

Nobel Laureate Jack Szostak to Present Plenary Keynote at Eighth Annual Drug Discovery Chemistry Conference on April 16 – Record Attendance from More than 225 Organizations and 25 Countries is Expected

Drug Discovery Chemistry is one of the few conferences for medicinal chemists working in pharma and biotech, and is focused on discovery and optimization challenges of small molecule drug candidates. New this year are Constrained Peptides and Macrocyclics and GPCR-Based Drug Design which represent areas of chemistry where evolving technologies are leading to renewed interest. They complement the most popular meetings from the past few years: Anti-Inflammatories, Fragment-Based Drug Discovery, Kinase Inhibitor Chemistry and Protein-Protein Interactions:

 – Anti-Inflammatories  [View Agenda] 4/16-17

– Fragment-Based Drug Discovery  [View Agenda] 4/16-17

– Constrained Peptides and Macrocyclics Drug Discovery  [View Agenda] 4/16-17

– Kinase Inhibitor Chemistry  [View Agenda] 4/17-18

– Protein-Protein Interactions  [View Agenda] 4/17-18

– GPCR-Based Drug Design  [View Agenda] 4/17-18

In a recent interview with Bio-IT World’s Kevin Davies, Dr. Szostak shared his thoughts on evolutionary chemistry, cyclic peptides, discovery of new small molecules for therapeutics, and his upcoming plenary keynote address: mRNA Display: From Basic Principles to Macrocycle Drug Discovery.

MEDIA GALLERY: VIDEOS

Jack Szostak Previews his Plenary Keynote for Drug Discovery Chemistry on

mRNA Display: From Basic Principles to Macrocycle Drug Discovery.

VIEW VIDEO

Jack Szostak Previews his Plenary Keynote for Drug Discovery Chemistry

In a recent interview, nobel laureate Dr. Jack Szostak shared his thoughts with Bio-IT World’s Kevin Davies on evolutionary chemistry, cyclic peptides, discovery of new small molecules for therapeutics, his upcoming plenary keynote address, and much more. On April 16, at the Eighth Annual Drug Discovery Chemistry conference, Dr. Szostak will present mRNA Display: From Basic Principles to Macrocycle Drug Discovery.

For VIDEO of Doug Treco Discusses Constrained Peptides and Macrocyclics

SCROLL DOWN THE SAME PAGE AS THE PREVIOUS VIDEO

VIEW VIDEO

Dr. Doug Treco, president & CEO of Ra Pharmaceuticals, shares recent developments in constrained peptides, macrocyclics, and how to develop peptides into a more useful class of drug. Dr. Treco will present Direct Selection of Cyclomimetics™ from mRNA Display Libraries at the Eighth Annual Drug Discovery Chemistry conference in San Diego on April 17.

List of Attendees:

Record Attendance Expected this Year! Should your Organization be on this List?
(Partial List as of 4/5)

A Star – Head – Organic Chemistry
Abbvie – Scientist – Research
Abbvie Bioresearch Ctr – Sr Scientist III – Chemistry
Abbvie Bioresearch Ctr – Sr Scientist III
AbbVie Inc – Principal Research Scientist
AbbVie Inc – Sr Scientist III – Molecular Modeling
Actelion Pharmaceuticals Ltd – Lab Head – Medicinal Chemistry
Actelion Pharmaceuticals Ltd – Sr Lab Head
Activ Motif – PostDoctoral Assoc
Addex Therapeutics – Assoc Res Dir – Structural Science
Adnexus a Bristol Myers Squibb R&D Co – Staff Scientist – Discovery
Affymax Inc – Sr Scientist II
Aileron Therapeutics Inc – Sr VP & CSO
Ajinomoto Co Ltd – Sr. Researcher
Allergan Inc – Sr Scientist – Medicinal Chemistry
Amakem NV – CoFounder & Dir External R&D – External R&D
Ambrx Inc – CTO
Amgen Inc – Principal Scientist – Pharmacokinetics & Drug Metabolism
Amgen Inc – Sr Scientist – Protein Technologies
AMRI – Dir Discovery R&D – Chemistry
AnalytiCon Discovery LLC – Exec VP Bus Dev – Natural Products
Anaspec Inc – Sr Chemist
Ardea Biosciences Inc – VP Research – Research Operations
Arena Pharmaceuticals – Research Fellow
Argenta Discovery 2009 Ltd – Sr Dir Chemistry
ARIAD Pharmaceuticals Inc – Assoc Dir Chemistry
Array BioPharma Inc – Sr Dir Cellular & Translational Biology
Asahi Kasei Pharma Co Ltd – Researcher – Lab for Medicinal Chemistry
Astellas – Scientist – Drug Discovery Research
Astellas Research Institute of American LLC – Principal Scientist – Med Chem
AstraZeneca – Assoc Principal Scientist – R&I iMed Medicinal Chemistry
AstraZeneca R&D Moelndal – Project Leader & Principal Scientist – Medicinal Chemistry & CVGI iMed
Axikin Pharmaceuticals Inc – Sr Dir Drug Dev Technologies – Drug Dev Technologies
Bayer AG – Principal Scientist
Bayer HealthCare AG – Computational Chemistry
Beijing Hanmi Pharmaceutical Co Ltd – Grp Leader Medicinal Chemistry & Analytical Chem
Ben Gurion Univ – Assoc Prof – Microbiology & Immunology & Health Sciences
Bicycle Therapeutics Ltd – CSO
Bio Rad Labs – Sales Mgr
Biogen Idec Inc – Principal Scientist – Physical Biochemistry
Biogen Idec Inc – Principal Scientist
Biogen Idec Inc – Scientist II – Medicinal Chemistry & Drug Discovery
Biogen Idec Inc – Sr Scientist & Medicinal Chemist
Biotage LLC – Specialist – Peptide Applications
Boehringer Ingelheim Pharma – Principal Scientist – Structural Research
Boehringer Ingelheim Pharma – Sr Principal Scientist – Medicinal Chemistry
Boehringer Ingelheim Pharma – Sr Scientist – Medicinal Chemistry
Boehringer Ingelheim Pharma GmbH & CO KG – Scientist – Chemical Research
BPS Bioscience Inc – Sr Research Scientist I
Brigham & Womens Hospital – Asst Prof Neurology
Bristol Myers Squibb – Grp Leader – Medicinal Chemistry
C&C Research Labs – Sr Research Scientist – Medicinal Chemistry
C&C Research Labs – Sr Researcher – CADD
Cancer Research UK Beatson Labs – Head – Chemistry
Catholic Univ of Korea – Prof – Natl Lab for Molecular Virology
Celgene – Assoc Scientist – Chemistry
Celgene – Sr Scientist – Chemistry
Celgene Avilomics Research – Sr Dir Chemistry
Celgene Corp – Sr Principal Investigator – Translational Dev
Cell Assay Innovations LLC – Founder & President
Charnwood Molecular Ltd – Head – Medicinal Chemistry
Charnwood Molecular Ltd – Mgr – Bus Dev
ChemAxon – Account Mgr
ChemAxon Ltd – Dir – Sales
ChemAxon Ltd – Principal Application Scientist
ChemBridge Corp – Exec Dir Sales & Marketing
Chemical Computing Group Inc – Principal Scientist – Scientific Support
Chinese Academy of Science – Guangzhou Institute of Biomedicine & Health
Chugai Pharmaceutical Co Ltd – Medicinal Chemist – Research
Chugai Pharmaceutical Co Ltd – Researcher
City of Hope Beckman Research Institute – Prof – Immunology
City of Hope Natl Medical Ctr – Staff Scientist – Molecular Medicine
CMD Bioscience LLC – Dir – Bus Dev
CMD Bioscience LLC – Dir Computational Chemistry
CNRS – Principal Investigator – Cancer Research
CNRS IPBS – Chemistry
Computype Inc – Market Mgr – Life Sciences
Computype Inc – Regional Sales Mgr
Cubist Pharmaceuticals Inc – Sr Scientist – Discovey Chemistry
Daiichi Sankyo Co Ltd – Assoc Sr Researcher – Discovery Research Lab
Daiichi Sankyo Co Ltd – Assoc Sr Researcher – Lead Discovery & Optimization Research Labs I
Daiichi Sankyo Co Ltd – Sr Dir – Lead Discovery & Optimization Research Labs I
Dart NeuroScience LLC – Assoc Dir – Chemistry
Dart NeuroScience LLC – Assoc Dir Chemistry
Dart NeuroScience LLC – Scientist II
Dart NeuroScience LLC – Scientist III – Leade Discovery HTS
Dart NeuroScience LLC – Scientist III
Dart NeuroScience LLC – Senior Research Assoc – Chemistry
Dart NeuroScience LLC – Sr Research Assoc – Chemistry
DEL BioPharma – Owner
DiscoveRx Corp – Dir Marketing – LeadHunter
DiscoveRx Corp – Sr Product Mgr
Dong A Pharmaceutical Co Ltd – Research Scientist
Dotmatics Ltd
E Merge Tech Global Svcs – CEO
E Merge Tech Global Svcs – Mgr – R&D
Eisai Co Ltd – Researcher – Product Creation
Eli Lilly & Co – Computational Chemist & Crystallographer
Eli Lilly & Co – Endocrine
Eli Lilly & Co – Sr Advisor – DCR&T
Eli Lilly & Co – Sr Research Advisor – Discovery Chemistry
Eli Lilly & Co – Sr Research Advisor – Discovery Chemistry Research
Eli Lilly & Co – Sr Research Scientist – Discovery Chemistry
EMD Serono Research & Development Institute Inc – Chemistry
EMD Serono Research & Development Institute Inc – Head – Drug Target Innovation & External Innovations
EMD Serono Research & Development Institute Inc – Sr Scientist – Chemistry
EMD Serono Research & Development Institute Inc – Sr Scientist – Medicinal Chemistry
Emory Univ – Post Doc Fellow
Ensemble Therapeutics – CSO
Entelos Inc – Dir Marketing
ESBS – Research Dir Receptord & Membrane Proteins – CNRS Biotechnology
ETH Zurich – Sr Scientist – Pharmaceutical Sciences
Evotec Inc – Project Leader – Discovery
Ewha Womans University – Prof
F Hoffmann La Roche Inc – Consultant – Medical Affairs
F Hoffmann La Roche Inc – Sr Research Leader – PR&D Discovery Chemistry
F Hoffmann La Roche Inc – VP & Global Head of Discovery Technologies – pRED & Discovery Technologies
Ferring Research Institute – Sr Scientist – Medicinal Chemistry
FLAMMA – Dir – Bus Dev
Full Spectrum Genetics Inc – Head – Bioinformatics
GE Healthcare – Product Specialist
Genentech Inc – Assoc Dir Structural Biology
Genentech Inc – Postdoc Research Fellow – Structural Biology
Genentech Inc – Scientist – Medicinal Chemistry
Genentech Inc – Scientist – Protein Engineering
Genentech Inc – Scientist & Team Leader – Medicinal Chemistry
Genentech Inc – Sr Mgr – Bus Dev
Genomics Institute of the Novartis Research Foundation – Principal Investigator – Structural Biology
Gilead Sciences Inc – Dir Biology
Gilead Sciences Inc – Dir Medicinal Chemistry
Gilead Sciences Inc – Research Scientist II
GL Chemtech Intl Ltd – Dir Bus Dev
Gwangju Institute of Science & Technology – Prof – Life Sciences
Harvard Medical School – Hematology Oncology
Hauptman Woodward Institute – Sr Research Scientist – Structural Biology
Helmholtz Zentrum Muenchen GmbH – Head – Assy Dev & Sxcreening Platform
Helsinn Therapeutics Inc – Sr Assoc – Tech Affairs
Heptares Therapeutics Ltd – Head – Biomolecular Structure
Hewlett Packard Oregon
Imgenex Corp – Principal Consultant – Corp Dev
Imgenex Corp – Product Mgr – Marketing
In Silico Biosciences – CSO – Computational Neuropharmacology
Indiana University – Research Asst Prof – Biochemistry & Molecular Biology
Industry Canada – Sr Patent Examiner – Organic 02
INSERM – Principal Investigator – CRCM CNRS
INSERM – Prof
Integral BioSciences – Research Scientist – Med Chem
Iowa State University – Principal Investigator – Biomedical Sciences
Ironwood Pharmaceuticals Inc – MedChem
Janssen Pharmaceuticals Inc – Sr Scientist – Scale Up Synthesis
Japan Tobacco Inc – Research Scientist – Central Pharmaceutical Research Lab
Japan Tobacco Inc – Researcher
Japan Tobacco Inc – Sr Dir Project & Portfolio Mgmt – Project & Portfolio Mgmt
Johns Hopkins University – Prof – Biology
Johnson & Johnson Pharmaceutical R&D – Assoc Scientist – Chemistry
Johnson & Johnson Pharmaceutical R&D – Chemist – Med Chem
Johnson & Johnson Pharmaceutical R&D – Physiological Systems
Johnson & Johnson Pharmaceutical R&D – Principal Scientist – Immunology Chemistry
Johnson & Johnson Pharmaceutical R&D – Sr Scientist – Chemistry
JT Central Pharmaceutical Research Institute – Research Scientist – Chemistry
Jubilant Discovery
Kalexsyn Inc
King Saud University – Pharmaceutical Chemistry
Korea Research Institute of Chemical Technology – Principal Researcher Drug Discovery Research
Lexicon Pharmaceuticals – Assoc Dir – Chem Tech
Life Chemicals Inc – Mgr – Bus Dev & Sales
Life Chemicals Inc – VP Marketing & Sales
LipoScience – CSO
Los Alamos Natl Lab – PostDoc Research Assoc – Bioscience
Lundbeck Research USA – Principal Scientist – Discovery Chemistry & DMPK
Massachusetts General Hospital – Prof – Genetics
Mayo Clinic – Asst Prof – Immunology
Medivation Inc – Dir Medicinal Chemistry
Merck – Principal Scientist
Merck Serono Research – Sr Dir Lead Discovery Technologies – MS DTC Strategic Operations Global Tech
Mitsubishi Tanabe Pharma Corp – Research Scientist – Medicinal Chemistry
MorphoSys AG – Sr Scientist
Natl Institute of Biological Science – Sr Investigator
Natl Taiwan University – Research Assoc – Chemisty
Natl Univ of Singapore – Assoc Prof – Chemistry
NIH CIT – CIO & Dir
NIH NCATS – Research Scientist – Probe Dev Ctr
NIH NINDS – Investigator – Basic Neuroscience
Novartis Institute for Tropical Diseases Pte Ltd – Investigator III – Chemistry
Novartis Institutes for BioMedical Research Inc – Dir Bus Dev
Novartis Institutes for BioMedical Research Inc – Presidential Postdoctoral Fellow
Novartis Pharma AG – Investigator III – Global Discovery Chemistry
Novartis Pharma AG – Proteomic Chemistry
Novartis Pharma AG – Research Investigator – NIBR
Nuevolution AS – Research Scientist
Nuevolution AS – Sr Scientist – Molecular Design
Oncodesign SA – CSO
Onyx Scientific Ltd – Dir Bus Dev
OpenEye Scientific Software Inc – Dir Emerging Markets – Emerging Markets
OpenEye Scientific Software Inc – Sr Applications Scientist
Ora Inc – Dir Pre Clinical Svcs
Original Biomedical Corp – Bus Dev
Peptron Inc – CEO
Pfizer Animal Health – Sr Principal Scientist
Pfizer Global R&D Groton Labs – Sr Principal Scientist – Structure Biology & Biophysics
Pfizer Inc – Assoc Dir – Prizer Animal Health
Pfizer Inc – Assoc Research Scientist – Chemical Sciences
Pfizer Inc – VP Chemistry
Pfizer Research Labs – Principal Scientist – Worldwide Medicinal Chemistry
PharmaCore Inc – Dir Bus Dev
PharmaCore Inc – President
Pharmacyclics Inc – Research Scientist III – Medicinal Chemistry
Polish Academy Of Sciences – Institute of Organic Chemistry
Polyphor Ltd – CSO & CoFounder
POSTECH – Assoc Prof
Prestwick Chemical – Head – Medicinal Chemistry
Prestwick Chemical – VP US Operations
Principia BioPharma Inc – Assoc Dir
Protagonist Therapeutics Inc – President & CEO
Purdue University – Assoc Prof – Medicinal Chemistry & Molecular Pharmacology
Quantum Tessera Consulting LLC – President and CSO
RA Pharmaceuticals Inc – President & CEO
RA Pharmaceuticals Inc – Scientist II
Receptos Inc – Assoc Dir – Biology
Receptos Inc – Dir Structural Biology
Receptos Inc – Scientist I
Roche Diagnostics GmbH – Dir Bio Analysis – Antibody Dev
Roche NimbleGen Inc – Sr Scientist
Rockefeller University – Richard M & Isabel P Furlaud Prof – Molecular Biology & Biochemistry
Rutgers University – Asst Research Prof – CABM
Sanofi Aventis – Head – In Silico Drug Discovery
sanofi aventis Grp – Project Leader
Santen Pharmaceutical – Researcher – Synthetic Chemistry Group
Schrodinger Inc – Applications Scientist
Science for Solutions LLC – President
Scripps Research Institute – Asst Prof – Molecular Biology
Scripps Research Institute – PostDoc Assoc – Molecular Therapeutics
Scripps Research Institute – Prof – Chemical Physiology
Scripps Research Institute – Research Assoc – Chemistry
Scripps Research Institute – Visiting Scientist – Chemical Physiology
Selcia Ltd – Grp Leader – Biology
Senomyx Inc – Principal Scientist – Chemistry
SENSIQ – COO
SENSIQ – CSO – Bioinstrumentation
SENSIQ – VP Marketing – Sales & Marketing
Shionogi & Co Ltd
SIGA Technologies Inc – CSO
Simulations Plus Inc – Research Fellow – Life Sciences
Simulations Plus Inc – Team Leader – Cheminformatics Study
Sookmyung Womens University – Student – College of Pharmacy
SRI Intl – Program Dir Medicinal Chemistry
St Jude Childrens Research Hospital – Post Doc Fellow – Chemical Biology & Therapeutics
St Jude Childrens Research Hospital – Postdoc – Chem Bio & Therapeutics
St Jude Childrens Research Hospital – Research Asst – Chemical Biology & Therapeutics
St Petersburg State Institute of Technology – Lab of Molecular Pharmacology
Stanford University – Assoc Prof – Bioengineering
Stanford University – Graduate Student – Kobilka Lab
Stanford University – Research Assoc – Chemical & Systems Biology
Structural Genomics Consortium – Postdoc Research Assoc – Epigenetics Probes Team
Sygene Intl Ltd – Sr Lead Investigator – Medchem
Sygnature Discovery Ltd – CEO
Sygnature Discovery Ltd – Dir New Bus Dev
SYNthesis Shanghai – Managing Dir
Synthonix – Bus Dev Mgr
Synthonix – CoFounder & President & CEO
Taiho Pharmaceutical Co Ltd – Sr Scientist – Medicinal Chemistry
Takeda California – Assoc Scientist
Takeda California – Scientist – Discovery Biology
Takeda California – Sr Scientist – Chemistry
Takeda California – Sr Scientist – SB & Ab Core Science & Technology
Takeda Pharmaceutical Co Ltd – Principal Scientist – Structural Biology
Takeda Pharmaceutical Co Ltd – Researcher – Medicinal Chemistry Lab
Takeda Pharmaceutical Co Ltd – Researcher – Pharmaceutical Research
Takeda San Diego – Dir Immunology Chemistry
Takeda San Diego – Scientist II
TC Scientific Inc – CEO
Theravance Inc – Research Assoc – Medicinal Chemistry
Theravance Inc – Scientist – Med Chem
Theravance Inc – Sr Research Advisor – Medicinal Chemistry
Theravance Inc – VP Molecular & Cellular Biology
Thermo Fisher Scientific Inc – Bus Mgr
Topharman USA
Tranzyme Pharma Inc – Sr VP Research & Preclinical Dev
Tranzyme Pharma Inc – VP IP & Operations
Tsinghua Univ – Medicinal Chemistry
UCB Pharma – Principal Scientist – CADD
UCB Pharma – Computational Medicinal Chemist
University of California Los Angeles – Prof – Molecular Imaging
University of California San Diego – Asst Prof – Chemistry & Biochemistry
University of California San Diego – Postdoc – Chemistry & Biochemistry
University of California San Diego – Prof – Clinical Medicine & Rheumatology
University of California San Diego – Prof – Molecular Biology
University of California San Francisco – Assoc Adjunct Prof – Lab Medicine
University of Central Florida – GRA – Chemistry
University of Cincinnati – Assoc Prof – Environmental Health
University of Essex – Prof – Computational Chemistry
University of Illinois Chicago – Prof – Biopharmaceutical Sciences
University of Maryland Baltimore – Grollman Glick Prof – Pharmaceutical Sciences
University of Miami – Dir Drug Discovery – Diabetes Research Institute
University of Navarra – Dir – Small Molecule Discovery
University of New South Wales – Postgraduate Student – Chemistry
University of Paris Diderot – Sr Research Assoc – Inserm UMR S973
University of Pittsburgh – Prof & Chair – Microbiology & Molecular Genetics
University of Pittsburgh – Research Asst Prof – Computational & Systems Biology
University of Southern California – Assoc Prof – Pharmacology & Pharmaceutical Sciences
University of Southern California – Scientist – Molecular & Computational Biology
University of Southern California – Molecular Microbiology & Immunology
University of Texas Dallas – Assoc Prof – Psychiatry & Neurology & Neurotherapeutics
University of Texas Houston – Asst Prof – Stem Cell Research
University of Toronto – Principal Investigator – Medical Biophysics
University of Utah – Research Assoc
University of Warsaw – Institute of Genetics and Biotechnology
University of York – Prof – Chemistry
University of Zurich – Scientist – Biochemistry
University Pompeu Fabra – Research Assoc – Medicinal Chemistry
Vanderbilt University – Research Fellow – Ctr for Neuroscience Drug Discovery
Vertex Pharmaceuticals Inc – Med Chem
Vertex Pharmaceuticals Inc – Research Fellow II – Biology
Vertex Pharmaceuticals Inc – Research Scientist – Chemistry
Vertex Pharmaceuticals Inc – Research Scientist I – Biology
Vidya Bharati College – Asst Prof – Chemistry
Vrije University Brussels – Exec Dir & Prof – Mol & Cellular Interactions
Vrije University Brussels – Prof Research Grp of Organic Chemistry – Bioengineering Sciences & Chemistry
Wayne State University – Research Scientist – Pathology & Oncology
Wichita State University – WSU Foundation Distinguished Prof – Chemistry
Wistar Institute – Staff Scientist
WuXi AppTec – Dir Bus Dev – Chemistry Svcs
X Chem Pharmaceuticals Inc – Dir Chemistry
X Chem Pharmaceuticals Inc – Sr Dir Lead Discovery
Yale University – Assoc Prof – Lab Medicine & Pharmacology
Yonsei University – Prof – Biochemistry
Yonsei University – Prof – Biotechnology

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Cholesteryl Ester Transfer Protein (CETP) Inhibitor: Potential of Anacetrapib to treat Atherosclerosis and CAD

Posted in Atherogenic Processes & Pathology, Biomarkers & Medical Diagnostics, Cardiovascular Pharmacogenomics, Cell Biology, Signaling & Cell Circuits, Chemical Biology and its relations to Metabolic Disease, Chemical Genetics, FDA Regulatory Affairs, Frontiers in Cardiology and Cardiovascular Disorders, Genome Biology, Genomic Testing: Methodology for Diagnosis, Liver & Digestive Diseases Research, Medical and Population Genetics, Metabolomics, Origins of Cardiovascular Disease, Personalized and Precision Medicine & Genomic Research, Pharmacogenomics, Pharmacotherapy of Cardiovascular Disease, Population Health Management, Genetics & Pharmaceutical, Regulated Clinical Trials: Design, Methods, Components and IRB related issues, Statistical Methods for Research Evaluation, Systemic Inflammatory Response Related Disorders, tagged , , , , , , , on April 7, 2013| 15 Comments »

Curator: Aviva Lev-Ari, PhD, RN

 

UPDATED on 7/29/2018

 

HDL-C: Is It Time to Stop Calling It the ‘Good’ Cholesterol? – Medscape – Jul 27, 2018.

 

In Eli Lilly’s Pipeline: DISCONTINUING Evacetrapib, a CETP inhibitor that’s meant to boost HDL

Reporter: Aviva Lev-Ari, PhD, RN

https://pharmaceuticalintelligence.com/2015/10/12/in-eli-lillys-pipeline-discontinuing-evacetrapib-a-cetp-inhibitor-thats-meant-to-boost-hdl/

 

On April 3, 2012 we published

Fight against Atherosclerotic Cardiovascular Disease: A Biologics not a Small Molecule – Recombinant Human lecithin-cholesterol acyltransferase (rhLCAT) attracted AstraZeneca to acquire AlphaCore

ACP-501, a recombinant human lecithin-cholesterol acyltransferase (LCAT) enzyme.

LCAT, an enzyme in the bloodstream, is a key component in the reverse cholesterol transport (RCT) system, which is thought to play a major role in driving the removal of cholesterol from the body and may be critical in the management of high-density lipoprotein (HDL) cholesterol levels.  The LCAT enzyme could also play a role in a rare, hereditary disorder called familial LCAT deficiency (FLD) in which the LCAT enzyme is absent.

http://pharmaceuticalintelligence.com/2013/04/03/fight-against-atherosclerotic-cardiovascular-disease-a-biologics-not-a-small-molecule-recombinant-human-lecithin-cholesterol-acyltransferase-rhlcat-attracted-astrazeneca-to-acquire-alphacore/

On April 4, 2013, the next day, a new study was published on a novel class of compounds, cholesteryl ester transfer protein (CETP) inhibitors, has demonstrated many potentially beneficial lipid-modifying effects was published on Anacetrapib, a compound that causes near-complete CETP inhibition, has among its effects, robust reductions in LDL-C and lipoprotein(a) as well as dramatic increases in HDL-C. The ability of anacetrapib to reduce coronary disease events is being tested in the Randomized EValuation of the Effects of Anacetrapib Through Lipid-modification (REVEAL) trial (NCT01252953).

Writer’s VIEWS:

    • AstraZeneca acquisition of AlphaCore represents its market entry into the CETP inhibitor segment via an acquisition where the company did not have presence or inhouse research. The results of the second study will position Merck at a superior position upon completion of Phase III Clinical Trials for Anacetrapib
    • If Biologics will help increase HDL in wide market penetration, the market share of Statins will be negatively impacted. Patent expiration and generic market availability of Statin erode future profits
    • Anacetrapib in in Phase III clinical Trial, if successfully completed — will be the FIRST biologics to use CETP inhibition biology of lipid metabolism in the quest to fight atherosclerosis by improving CVD outcomes
    • A connection between this two events and cites in Disclosure, AstraZeneca, Merck, supporting the research of Christopher P Cannon on the study on Anacetrapib.
    • Full Article PDF file was published in Research Reports in Clinical Cardiology, one of the Journals on Beall’s list publisher, where scientists pay to have the article been published, Dove Press, on its Web site says, “There are no limits on the number or size of the papers we can publish.” See reference for Beall’s list publishers http://www.nytimes.com/2013/04/08/health/for-scientists-an-exploding-world-of-pseudo-academia.html?pagewanted=1&_r=0&emc=eta1

Study Goals:

  • testing the hypothesis that CETP inhibition may reduce atherosclerotic outcomes. 
  • answer important questions regarding the role of CETP in the biology of lipid metabolism and atherosclerosis.

Research Reports in Clinical Cardiology, 4 April 2013 Volume 2013:4 Pages 39 – 53

Dylan L Steen,1 Amit V Khera,2 Christopher P Cannon1

1TIMI Study Group, Cardiovascular Division, 2Department of Medicine, Brigham and Women’s Hospital, Boston, MA, USA

Disclosure

Dr Cannon is a member of the advisory boards of and has received grant support from Alnylam, Bristol-Myers Squibb, Pfizer, and CSL Behring; has received grant support from Accumetrics, AstraZeneca, Essentialis, GlaxoSmithKline, Merck, Regeneron, Sanofi, and Takeda; and is a clinical advisor to Automated Medical Systems. All other authors have reported that they have no relationships relevant to the contents of this paper.

Abstract: Despite major advances in cardiovascular care in recent decades, atherosclerotic cardiovascular disease remains the leading cause of morbidity and mortality worldwide. Statins have been shown to reduce cardiovascular events by 25%–40% in a dose-dependent fashion; yet additional therapies are needed to reduce vascular disease progression and acute thrombotic events. In addition to low-density lipoprotein cholesterol (LDL-C) reduction, other lipid risk factors, such as low high-density lipoprotein cholesterol (HDL-C), have created interest as therapeutic targets to lower cardiovascular risk. However, the absence of compelling data for incremental benefit of non-LDL-centric therapies in the statin era has limited their clinical use. A novel class of compounds, cholesteryl ester transfer protein (CETP) inhibitors, has demonstrated many potentially beneficial lipid-modifying effects. While in vitro and animal data for CETP inhibition have been encouraging, the initial enthusiasm for the class has been tempered by the failure of two CETP inhibitors (torcetrapib and dalcetrapib) in Phase III trials to reduce cardiovascular outcomes. Anacetrapib, a compound that causes near-complete CETP inhibition, has among its effects, robust reductions in LDL-C and lipoprotein(a) as well as dramatic increases in HDL-C. The ability of anacetrapib to reduce coronary disease events is being tested in the Randomized EValuation of the Effects of Anacetrapib Through Lipid-modification (REVEAL) trial (NCT01252953).

Keywords: anacetrapib, cholesteryl ester transfer protein, cholesteryl ester transfer protein inhibitor, atherosclerosis

  • Niacin, which augments HDL-C by 20%–25%, recently failed to lower atherosclerotic events in both the Atherothrombosis Intervention in Metabolic Syndrome with Low HDL/High Triglycerides and Impact on Global Health Outcomes (AIM-HIGH)6 and Treatment of HDL to Reduce the Incidence of Vascular Events (HPS2-THRIVE) trials.7,8
  • Lp(a) lowering has not yet been evaluated in randomized controlled trials, but observational and genetic (including Mendelian randomization) analyses have demonstrated an independent association of increased Lp(a) levels with increased CV events, suggesting Lp(a) lowering may confer benefit.9
  • surprising failure of the first two CETP inhibitors (torcetrapib and dalcetrapib) in Phase III outcomes trials has somewhat tempered this initial excitement and forced a re-evaluation of the complex effects of CETP inhibition on lipid metabolism and vascular biology.
  • Anacetrapib results in near-complete CETP inhibition with more pronounced lipid effects than its predecessors and is currently in a Phase III study for secondary prevention of coronary events. If successful it is likely that anacetrapib will also be considered for statin-intolerant patients and for primary prevention in patients who require LDL-C lowering beyond statin monotherapy
  • Human CETP is a 476-residue, 74 kDa, hydrophobic glycoprotein primarily secreted by the liver and adipose tissue.13 CETP was first cloned in 1987.14 The structure of CETP allows formation of a tunnel with the opening on one end interacting with HDL and the other with a very low-density lipoprotein (VLDL), intermediate-density lipoprotein (IDL), or LDL particle. The hydrophobic central cavity of this tunnel is large enough to allow transfer of neutral lipids (eg, cholesteryl esters [CEs], triglycerides [TGs]) from donor to acceptor particles, but conformational changes may occur to accommodate larger lipoprotein particles. The concave surface of CETP matches the curvature of the HDL particles to which it is primarily bound in the bloodstream.15,16
  • The overall effect of CETP is a net transfer of CE from HDL to these apolipoprotein B (apoB)-containing particles and TG to HDL and LDL
  • An important driver of the transfer of CE from HDL to apoB-containing particles is the production of CE from free cholesterol within HDL by lecithin acetyltransferase (LCAT).17

    The role of CETP in reverse cholesterol transport.

    Beginning in the peripheral tissues, free cholesterol is predominantly taken up by small “immature” HDL particles (eg, pre-β-HDL) via the ABCA1 transporter. Alternatively, it can be taken up by larger “mature” HDL particles (eg, HDL2) via the ABCG1 transporter. LCAT converts free cholesterol into cholesteryl ester, which is then shuttled to apoB-lipoproteins (eg, LDL, VLDL) in exchange for triglycerides. Only a minority of cholesteryl ester is delivered directly to the liver by HDL via the SR-BI; the majority is delivered indirectly to the liver by apoB-lipoproteins via the LDL recepter.

    Abbreviations: CETP, cholesteryl ester transfer protein; HDL, high-density lipoprotein; ABCA1, ATP-binding cassette transporter A1; ABCG1, ATP-binding cassette transporter G1; LCAT, lecithin acetyltransferase; apoB, apolipoprotein B; LDL, low-density lipoprotein; VLDL, very low density lipoprotein; SR-BI, scavenger receptor-BI; FC, free cholesterol; CE, cholesteryl ester.

  • One of the interesting questions in CETP deficiency is whether the HDL particles produced by potent CETP inhibition are functional. Regardless of whether reverse cholesterol transport is increased, the initial steps of cholesterol efflux from foam cells may be one of the key anti-atherogenic functions of HDL.5
  • This increased efflux is related to the very high content of LCAT and apoE in these large HDL particles, presumably driving net cholesterol efflux by promoting cholesterol esterification.36
  • effect of CETP deficiency on liver uptake of cholesteryl ester, an important downstream step in a reverse cholesterol transport. These studies suggest that there may be increased CE uptake via SR-BI as well as through a high affinity of large apoE-rich HDL for LDL receptors.20
  • meta-analysis established that three CETP genotypes were not only associated with decreased CETP activity and increased HDL but also with a lower risk of myocardial infarction (MI). For example, for each allele inherited, individuals with the TaqIB polymorphism had lower mean CETP activity (−8.6%), higher mean HDL-C (4.5%), higher mean apoA-I (2.4%), and an odds ratio for coronary disease of 0.95 (95% confidence intervals [CI], 0.92, 0.99). Similar associations were found for the other two CETP genotypes.40
  • Subsequent studies have confirmed that genetic variants leading to reduced CETP activity and its corresponding anti-atherogenic lipid profile are associated with reduced atherosclerotic outcomes.41–43
  • In ILLUSTRATE, an inverse association between HDL-C achieved and the primary endpoint of atheroma volume (r = −0.17, P , 0.001) was found. In addition, the highest quartile of HDL-C achieved (.86 mg/dL) demonstrated atheroma regression, suggesting that there may be a “threshold effect” to HDL-C elevation.68
  • Other CETP inhibitors:

Dalcetrapib
was developed by Hoffmann–La Roche until May 2012. It did not raise blood pressure and did raise HDL, but it showed no clinically meaningful efficacy.

Evacetrapib 

is under development by Eli Lilly & Company.
Torcetrapib
was developed by Pfizer until December 2006 but caused unacceptable increases in blood pressure and had net cardiovascular detriment.
Anacetrapib At the 16th International Symposium on Drugs Affecting Lipid Metabolism (New York, Oct 4-7, 2007), Merck reported on a Phase IIb study. The eight week study reported dosage correlated reduction in LDL-C and increases in HDL-C levels with no corresponding increases in blood pressure in any cohort. The increase in HDL was particularly significant, averaging 44 percent, 86 percent, 139 percent and 133 percent at doses of 10 mg, 40 mg, 150 mg and 300 mg. Merck performed a dose-ranging study of anacetrapib, with the results presented in 2009.

Anacetrapib 

Anacetrapib is a 3,5-bis-trifluoromethyl-benzene derivative with similar binding properties to CETP as torcetrapib. The compound was developed when it was found that a substitution modification of the oxazolidinone ring increased its potency for CETP inhibition in a transgenic mouse model.85 In terms of its pharmacokinetics and pharmacodynamics, anacetrapib is rapidly absorbed with a time-to-peak plasma concentration of about 4 hours. The oral bioavailability of anacetrapib is poor, with only about 20% being absorbed; however at this exposure, LDL-C is reduced up to 40% and HDL-C increased up to 140%. It is recommended that anacetrapib be taken with food (ie, low-fat diet) to increase drug exposure (and efficacy) as well as compliance.86

Anacetrapib is highly protein bound (eg, CETP) in the plasma (.99.5%). It is cleared by oxidative metabolism via Cytochrome P450 3A4 (CYP3A4) with excretion of the metabolites via the biliary/fecal route. Only a trace amount is eliminated by urinary excretion.87 Importantly, while anacetrapib is a sensitive CYP3A4 substrate, anacetrapib neither inhibits nor induces CYP3A4 activity. No meaningful interactions have been found between anacetrapib and simvastatin, digoxin, or warfarin.86 Anacetrapib in part to its redistribution to adipose tissue has a long terminal half-life.88

In terms of safety endpoints, anacetrapib demonstrated no increase in side effects (including myalgia), drug-related adverse effects, adverse events leading to drug discontinuation, or other important safety endpoints, such as BP, electrolyte, aldosterone, creatinine kinase, or transaminase levels. A very small increase in C-reactive protein of undetermined significance was seen with anacetrapib, which notably was also reported with torcetrapib and dalcetrapib in their Phase III studies. It is unknown whether this is a class effect as the small sample size in the evacetrapib Phase II study limits evaluation of small C-reactive protein changes.

It is expected that the REVEAL (the Phase III) population will also have lower starting LDL-C levels, both because statin-intolerant subjects will not be enrolled and because of more stringent lipid entry criteria. The final major difference is that the primary endpoint in REVEAL is focused on coronary events, while ACCELERATE has a broader primary endpoint. A broader primary endpoint along with a slightly higher risk population will allow for a shorter follow-up duration and much smaller sample size in ACCELERATE.

Conclusion

  • CETP remains a valid target and that the lipid changes resulting from its inhibition may be protective. The biology of CETP inhibition is complex, and questions remain regarding which lipid changes (eg, reductions in LDL and Lp(a), increases in HDL) are most likely to be important and whether there are still unknown effects that may negate any overall clinical benefit.
  • if potent CETP inhibition is found to be beneficial, it is still unclear whether this effect will be homogeneous or vary based on individual metabolism.
  • anacetrapib-induced HDL (especially the apoE-rich HDL2 particles) may have an enhanced ability for reverse cholesterol transport without any known adverse effects. Importantly, if a threshold effect for HDL-C augmentation exists, the vast majority of patients taking anacetrapib would be expected to cross it.
  • Despite a difficult beginning for the class of CETP inhibitors, anacetrapib and evacetrapib hold promise as future therapies for patients with atherosclerosis
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How Methionine Imbalance with Sulfur-Insufficiency Leads to Hyperhomocysteinemia

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How Methionine Imbalance with Sulfur-Insufficiency Leads to Hyperhomocysteinemia

Curator: Larry H Bernstein, MD, FACP

The Open Clinical Chemistry Journal, 2011; 4: 34-44

http://occj.com/1874-2416/11 2011/
http://dx.doi.org/11.2011/occl/1874-2416/
Bentham Open   Open Access

Introduction:  The following document is a seminal article concerning the relationship between hyoerhomocysteinemia and cardiovascular and other diseases. It provides a new insight based on the metabolism of S8 and geographic factors affecting the distribution, the differences of plant and animal sources of dietary intake,
and the great impact on methylation reactions.  The result is the finding that hyperhomocysteine is a “signal”, just as CRP is a measure of IL-6, IL-1, TNFa -mediated inflammatory response.  A deficiency of S8 due to the unavailability of S8, leads to CVD, and is seen in sulfur deficient regions with inadequate soil content and with veganism.  Hyperhomocysteinemia is also an indicator of CVD risk in the well fed populations, and that gives us a good reason to ASK WHY?

I have trimmed the content to make the necessary points that would be sufficient for this content.  The article can be viewed at OCCJ online.

The Oxidative Stress of Hyperhomocysteinemia Results from Reduced Bioavailability of Sulfur-Containing Reductants

Yves Ingenbleek*
Laboratory of Nutrition, Faculty of Pharmacy, University Louis Pasteur Strasbourg, France

Abstract

A combination of subclinical malnutrition and S8-deficiency

  • maximizes the defective production of Cys, GSH and H2S reductants,
  • explaining persistence of unabated oxidative burden.

The clinical entity

  • increases the risk of developing cardiovascular diseases (CVD) and stroke
    • in underprivileged plant-eating populations
    • regardless of Framingham criteria and vitamin-B status.

Although unrecognized up to now,

  • the nutritional disorder is one of the commonest worldwide,
  • reaching top prevalence in populated regions of Southeastern Asia.

Increased risk of hyperhomocysteinemia and oxidative stress may also affect

  • individuals suffering from intestinal malabsorption or
  • westernized communities having adopted vegan dietary lifestyles.

Vegetarian subjects

  • consuming subnormal amounts of methionine (Met) are characterized by
  • subclinical protein malnutrition causing reduction in size of their lean body mass (LBM) best
  • identified by the serial measurement of plasma transthyretin (TTR).

As a result, the transsulfuration pathway is depressed at cystathionine-beta-synthase (CbS) level

  • triggering the upstream sequestration of homocysteine (Hcy) in biological fluids and
  • promoting its conversion to Met.

Maintenance of beneficial Met homeostasis is

  • counterpoised by the drop of cysteine (Cys) and glutathione (GSH) values downstream to
  • CbS causing in turn declining generation of hydrogen sulfide (H2S) from enzymatic sources.

The biogenesis of H2S via non-enzymatic reduction is further inhibited in areas where

  • earth’s crust is depleted in elemental sulfur (S8) and sulfate oxyanions.

Keywords: Vegetarianism, malnutrition, sulfur-deficiency, hyperhomocysteinemia, oxidative stress, hydrogen sulfide, cardiovascular diseases, developing countries, Asia.

Homocysteine (Hcy) Generated by Transmethylation Pathway and Degraded via Transsulfuration Pathway

Homocysteine (Hcy) is a nonproteogenic sulfur containing amino acid (SAA)

  • generated by the intrahepatic transmethylation (TM) of dietary Met.
  • It may either be recycled to Met following remethylation (RM) pathways or
  • catabolized along the transsulfuration (TS) cascade.

Under normal circumstances, the Met-Hcy cycle stands under the regulatory control of three water soluble B-vitamins:

  • folates (5-methyl-tetrahydrofolates, B9) are regarded as the main factor working as donor of the CH3 group involved in the remethylation process,
  • pyridoxine (pyridoxal-5’-phosphate, PLP, B6) plays the role of co-factor of both
  • cystathionase enzymes belonging to the TS pathway and cobalamins (B12) ensure that of methionine-synthase.

Met-Hcy-Met Cycle

The main steps of the Met _ Hcy _Met cycle are summarized in Fig. (1).

FIGURE 1 NR H2S

Fig. (1). Schematic representation of the methionine cycle and homocysteine degradation pathways.

Compounds: ATP, adenosyltriphosphate; THF, tetrahydrofolate; SAM, S- adenosylmethionine; SAH, adenosylhomocysteine; Cysta, cystathionine; Cys, cysteine;
GSH, glutathione; H2S, hydrogen sulfide; Tau, taurine; SO4-2 , sulfate oxyanions.
Enzymes: (1) Met-adenosyltransferase; (2) SAM-methyltransferases; (3) adenosyl-homocysteinase; (4) methylene-THF reductase; (5) Metsynthase; (6) cystathionine
-b-synthase, CbS;  (7) cystathionine-b-lyase, CbL; (8) g-glutamyl-synthase; (9) g-glutamyl-transpeptidase; (10)oxidase; (11) reductase; (12) cysteine-dioxygenase, CDO.

Metabolic pathways

Met molecules supplied by dietary proteins are

  • submitted to TM processes
  • releasing Hcy which may in turn either
    • undergo Hcy_Met RM pathways or be
    • irreversibly committed into TS decay.

Impairment of CbS activity in protein malnutrition, entails

  • supranormal accumulation of Hcy in body fluids,
  • stimulation of (5) activity and maintenance of Met homeostasis.

This last beneficial effect is counteracted by

  • decreased concentration of most components generated downstream to CbS,
  • explaining the depressed CbS- and CbL-mediated enzymatic production of *H2S along the TS cascade.

The restricted dietary intake of elemental S is a limiting factor for

  • its non-enzymatic reduction to **H2S which contributes to
  • downsizing a common body pool (dotted circle).(Fig 1)

Combined protein- and S-deficiencies work in concert

  • to deplete Cys, GSH and H2S from their body reserves,
  • impeding these reducing molecules from countering
  • the oxidative stress imposed by hyperhomocysteinemia.

Hyperhomocysteinemia

Hyperhomocysteinemia (HHcy) is an acquired metabolic anomaly first identified by McCully [1]

The current consensus is that dietary deficiency in any of
three water soluble vitamins may operate as causal factor of HHcy.

  • PLP–deficiency may trigger the upstream accumulation of Hcy in biological fluids [2] whereas
  • the shortage of vitamins B9 or B12 is held responsible for its downstream sequestration [3,4].

HHcy is regarded as a major causal determinant of CVD

  1. working as an independent and graded risk factor
  2. unrelated to the classical Framingham criteria such as
  • hypercholesterolemia,
  • dyslipidemia,
  • sedentary lifestyle,
  • diabetes and
  • smoking.

Hcy may invade the intracellular space of many tissues and locally generate [5]

  • endothelial dysfunction working as early harbinger of blood vessel injuries and atherosclerosis.

Most investigators contend

  • that production of harmful reactive oxygen and nitrogen species (ROS, NOS), notably
    • hydrogen peroxide (H2O2), superoxide anion (O2 .-) and peroxinitrite (ONOO.-),
    • constitutes a major culprit in the development of HHcy-induced vascular damages [7-10].

Accumulation of ROS
associated with increased risk for

  • cardiovascular diseases [11]
  • stroke [12],
  • arterial hypertension [6],
  • kidney dysfunction [13],
  • Alzheimer’s disease [14],
  • cognitive deterioration [15],
  • inflammatory bowel disease [16] and
  • bone remodeling [17].

These effects overlook the protective roles played by

  • extra- and intracellular reductants such as cysteine (Cys) and glutathione (GSH)
    • in the sequence of events leading from HHcy to tissue damage.

Hydrogen Sulfide (H2S)

After the discovery of nitric oxide (NO) and carbon oxide (CO), hydrogen sulfide (H2S) is the

  • third gaseous signaling messenger found in mammalian tissues [18].

H2S is a reducing molecule displaying strong scavenging properties

  • as the gasotransmitter significantly attenuates [19, 20] or
  • even abolishes [21,22] the oxidative injury imposed by HHcy burden.

The endogenous production of the naturally occurring H2S reductant depends on

  • Cys bioavailability through
  • the mediation of TS enzymes [23,24].

H2S may also be produced in human tissues starting from elemental sulfur,

  • by a non-enzymatic reaction requiring the presence of Cys, GSH, and glucose [25,26].

It would be worth disentangling the respective roles played by

  1. Cys,
  2. GSH
  3. H2S
  • for the prevention and restoration of HHcy-induced oxidative lesions.
  •  but the plasma concentration of Cys and GSH is severely depressed in
  • subclinically malnourished HHcy patients [27],
    •  impeding appropriate biogenesis of H2S molecules.

The present paper reviews the biological consequences

  • resulting from the complex interplay existing between the 3 reducing molecules,
  • to gain insight into the pathophysiologic mechanisms associated with HHcy states.

CLINICAL BACKGROUND

Numerous surveys have conclusively shown that the water soluble vitamin deficiency concept,

  • provides only partial causal account of the HHcy metabolic anomaly.

The components of body composition, mainly

  • the size of lean body mass (LBM),
  • constitutes a critical determinant of HHcy status [28,29].

Because nitrogen (N) and sulfur (S) concentrations

  • maintain tightly correlated ratios in tissues, we hypothesize 
  • defective N intake and accretion rate would cause concomitant and
  • proportionate depletion of total body N (TBN) and total body S (TBS) stores [30].

Our clinical investigation undertaken in Central Africa in apparently healthy but

  • nevertheless subclinically malnourished vegetarian subjects has
  • documented that reduced size of LBM could lead to HHcy states [27].

The field study conducted in the Republic of Chad, populated by the Sara ethnic group [27], is a  semi-arid region and

  • the staple food consists mainly of cassava, sweet potatoes, beans, millets and groundnuts.

Participants were invited to fill in a detailed dietary questionnaire whose results were compared with values reported in food composition tables [32-34] [27].
The dietary inquiry indicates that participants

  • consumed a significantly lower mean SAA intake (10.4 mg.kg-1.d-1)[27]
  • than the Recommended Dietary Allowances (RDAs) (13 mg.kg-1.d-1)[33,34].

Blood Analytes

The blood lipid profiles of rural subjects were confined within normal ranges

  • ruling out this class of parameters as causal risk factors for CVD disorders.

The normal levels measured for pyridoxine, folates, and cobalamins

  •  precluded these vitamins from playing any significant role in the rise of Hcy

plasma concentrations [27]. Analysis of plasma SAAs revealed

  • unmodified methioninemia, significantly 
  • elevated Hcy values (18.6 umol/L)
  • contrasting with significantly decreased plasma Cys and GSH values [27].

The significant lowering of classical

  • anthropometric parameters
    •  (body weight, BW;
    • body mass index, BMI)
  • together with that of the main plasma and urinary biomarkers of
    • metabolic (visceral) and
    • structural (muscular) compartments point to

an estimated 10 % shrinking of LBM [27].

Transthyretin (TTR)  and Lean Body Mass (LBM)

We have attached peculiar importance to the measurement of plasma transthyretin (TTR)

  1. this indicator integrates the evolutionary trends outlined by body protein reserves [35],
  2. providing from birth until death an overall and balanced estimate of LBM fluctuations [29].
  • In the absence of any superimposed inflammatory condition,
    • LBM and TTR profiles indeed reveal striking similarities [29].

Scientists belonging to the Foundation for Blood Research (Scarborough, Maine, 04074, USA) have recently published a large number of TTR results recorded
in 68,720 healthy US citizens aged 0-100 yr which constitute a comprehensive reference material to follow the shape of LBM fluctuations in relation with sex and age [29].

  • TTR concentrations plotted against Hcy values reveal a strongly negative correlation (r = –0.71)  [29,30], confirming that
      • the depletion of TBN and TBS stores plays a predominant role in the development of HHcy states.

The body of a reference man weighing 70 kg contains 64 M of N (1,800 g) and 4,400 mM of S (140 g) [36]. Our vegetarian subjects consume diets providing
low fat and high fiber content conferring a large spectrum of well described health benefits notably for the prevention of several chronic disorders such as
cancer and diabetes, together with an effective protection against the risk of hypercholesterolemia-induced CVD [37,38].
Plant-based regimens, however, do not supply appropriate amounts of

  • nitrogenous substrates of good biological value which are required to adequately fulfill mammalian tissue needs [30].
  • vegetable items contain suboptimal concentrations of both SAAs [33,34,39] below the customary RDA guidelines.

This dietary handicap may be further deteriorated by

  • unsuitable food processing [40] and by
  • the presence in plant products of naturally occurring anti-nutritional factors
    • such as tannins in cereal grains and
    • anti-trypsin or anti-chymotrypsin inhibitors in soybeans and kidney beans [41].

LBM loss

LBM shrinking may be the result of either

  • dysmaturation of body protein tissues as an effect of protracted dietary SAA deprivation
  • or of cytokine-induced depletion of body stores.

Although causally unrelated and evolving along dissimilar adaptive processes,

  • both physiopathologic entities lead to comparable LBM downsizing best
    • identified by declining plasma TTR ( measured alone or within combined formulas )
    • and subsequently rising Hcy values.

All parameters are downregulated with the sole exception of RM flux rates, indicating that

  • maintenance of Met homeostasis remains a high metabolic priority in protein-depleted states.

Stressful disorders are characterized by

  • overstimulation of all
  1. TM
  2. RM
  3. TS flux rates.

The severity and duration of initial impact determine the magnitude of protein tissue breakdown,

  • rendering an account of N : S urinary losses,
  • fluctuations of albuminuria and of
  • insulin resistance striving to contain LBM integrity.

Both physiopathologic entities are compromized in reducing the oxidative burden imposed by HHcy states owing to

  • defective synthesis and/or
  • enhanced overconsumption of Cys-GSH-H2S reducing molecules,
  • a condition still worsened by its co-existence with elemental S-deficiency.

IMPAIRMENT OF THE TRANSSULFURATION PATHWAY

The hypothesis that subclinical protein malnutrition might be involved in the occurrence of HHcy states via inhibition of cystathionine-b-synthase (CbS) activity
first arose in Senegal in 1986 [42] and was later corroborated in Central Africa [43]. The concept was clearly counterintuitive in that it was unexpected that

  • high Hcy plasma values might result from low intake of its precursor Met molecule.

Despite the low SAA intake of our vegetarian patients [27], plasma Met concentrations disclosed noticeable stability permitting

  • maintenance of the synthesis and functioning of myriads of Met dependent molecular, structural and metabolic compounds

These clinical investigations have received strong support from recent mouse [45] and rat [46] experiments submitted to Met-restricted regimens.
At the end of the Met-deprivation period, both animal species did manifest meaningful HHcy states (p<0.001) contrasting with

  • significantly lower BW (p<0.001) reduced by 33 % [45] and 44 % [46] of control, respectively.
  • the uniqueness of Met behavior stands in accordance with balance studies performed on large mammalian species showing
  • that the complete withdrawal of Met from otherwise normal diets causes the greatest rate of body loss,
    • nearly equal to that generated by protein-free regimens [47,48].

This efficient Met homeostatic mechanism is classically ascribed to a PLP-like inhibition of CbS activity exerted through

  • allosteric binding of S-adenosylmethionine (SAM) to the C-terminal regulatory domain of the enzyme [49,50].

The loss of CbS activity may develop via a (post)translational defect

  • independently from intrahepatic SAM concentrations [45].

We have postulated the existence of an independent sensor mechanism set in motion by TBS pool shrinkage and

  • reduced bioavailability of Met – its main building block – working as an inhibitory feedback loop of CbS activity [30].

Such Met-bodystat, likely to be centrally mediated, is to maintain unaltered Met disposal in conditions of

  • decreased dietary provision implies the fulfillment
  • of high metabolic priorities of survival value [30,44].

Whereas HHcy may be regarded as the dark side of a beneficial adaptive machinery [43],

  • impairment of the TS pathway also depresses the production of compounds situated downstream to the CbS blockade level,
  • notably Cys and GSH, keeping in mind that Cys may undergo reversible GSH conversion (Fig. 1).

The plasma concentration of both Cys and GSH reductants is indeed significantly decreased in our vegetarian subjects

  • by 33 % and 67 % of control, displaying negative correlations (r = –0.67 and –0.37, respectively) with HHcy values [27].

Reduced dietary intake of the preformed Cys molecule [27] and diminished Cys release from protein breakdown in malnourished states [51]

  • may contribute to the lowering effect.

The significantly decreased GSH blood levels may similarly be attributed to dietary composition since the tripeptide is mainly found in meat products

  • but is virtually absent from cereals, roots, milk and dairy items [52] and
  • because regimens lacking SAAs may lessen the production of blood GSH and its intrahepatic sequestration [53].

BIOGENESIS OF HYDROGEN SULFIDE

The TS degradation pathway schematically proceeds along two main PLP-dependent enzymatic reactions working in succession (Fig. 1).

  • The first is catalyzed by CbS (EC 4.2.1.22) governing the replacement of the hydroxyl group of serine with Hcy to generate Cysta plus H2O.
    • Cys may however substitute for serine and the replacement of its sulfhydryl group with Hcy releases Cysta and H2S instead of water [54].
  • The second is regulated by cystathionine-g-lyase (CgL, EC 4.4.1.1.) hydrolyzing Cysta to release Cys and alpha-ketobutyrate plus ammonia as side-products [55].
    •  Cys may also undergo nonoxidative desulfuration pathways leading to H2S or sulfanesulfur production [56] under the control of CbS or CgL enzymes.
    •  Cys may otherwise undergo oxidative conversion regulated by cysteine-dioxygenase (CDO, EC 1.13.11.20) which
      • catalyzes the replacement of the SH- group of Cys by SO3 – to yield cysteine-sulfinate [56].

This last compound may be further decarboxylated to hypotaurine that is finally oxidized to Tau (67 %) and SO4 2- oxyanions (33 %) [56]. CbS and CgL,  both cytosolic enzymes,

  • their relative contribution to the generation of H2S may vary according to
    • animal strains,
    • tissue specificities and
    • nutritional or physiopathological circumstances [23,24].

CbS and CgL are expressed in most organs such as liver, kidneys, brain, heart, large vessels, ileum and pancreas [57,58] potentially

  • subjected to HHcy-induced ROS injury while keeping the capacity to desulfurate Cys and to
  • locally produce H2S as cytoprotectant signaling agent.

CbS is the principal TS enzyme found in

  • cerebral glial cells and astrocytes [59].

CgL predominates in the

  • vascular system [60] whereas
      • both enzymes are present in the renal proximal tubules [61].

H2S is the third gaseous substrate found in the biosphere [18] after NO and CO. All three gases are characterized by

  • severe toxicity when inhaled at high concentrations.

In particular, H2S produced by anaerobic fermentation is

  • capable of causing respiratory death by
  • inhibition of mitochondrial cytochrome C oxidase [62].

NO, CO and H2S are synthesized from arginine, glycine and Cys, respectively, exerting at low concentrations major biological functions in living organisms.
Most of our knowledge on these atypical signal messengers [63] are derived from animal experiments and tissue cultures. These transmitter molecules may

  • share some properties in common such as penetration of cellular membranes independently from specific receptors [64].

They are also manifesting dissimilar activities: whereas NO and CO activate guanylyl cyclase to generate biological responses via cGMP-dependent kinases,

  • H2S induces Ca2+-dependent effects through ATP-sensitive K+ channels [65].

Some of these potentialities may work in concert while others operate antagonistically. For instance,

  • NO and H2S express vasorelaxant tone on endogenous smooth muscle [66]
  • but reveal different effects on large artery vessels [67].

These gaseous substances maintain whole body homeostasis through complex interactions and multifaceted crosstalks between signaling pathways.
Elemental S (32.064 as atomic mass) is a primordial constituent of lava flows in areas of volcanic or sedimental origin usually presenting as crown-shaped
stable octamolecules – hence its S8 symbolic denomination – which may conglomerate to form brimstone rocks. The vegetable kingdom is

  • unable to assimilate S8 and requires as prior step its natural or bacterial oxidation to SO4 2- derivatives before launching
  • the synthesis of SAA molecules along narrowly regulated metabolic pathways [30,44].

Distinct anabolic processes are identified in mammalian tissues which lack the enzymatic equipment required to organize sulfate oxyanions

  • but possess the capacity of direct S8 conversion into H2S.

S8 is poorly soluble in tap waters [68] may be taken up and transported to mammalian tissues loosely fastened to serum albumin (SA) [69].
S may also be covalently bound to intracellular S-atoms taking the form of sulfane-sulfur compounds [70] either

  • firmly attached to cytosolic organelles or in
  • untied form to mitochondria [57,58,71,72] to undergo
  • later release in response to specific endogenous requirements [71].

Sulfane-sulfur compounds are somewhat unstable and may decompose in the presence of reducing agents allowing the restitution of S [70,71].
S may either endorse the role of stimulatory factor of several mammalian apoenzyme activities as shown for

    • succinic dehydrogenase [73] and NADH dehydrogenase [74] or
  • operate as inhibitory agent of other mammalian apoenzymes such as
    • adenylate kinase [75] and liver tyrosine aminotransferase [76].

Elemental S resulting from dietary supply or from sulfane-sulfur decay may be subjected to

non-enzymatic reduction in the presence of Cys and GSH [25,26] and/or reducing equivalents obtained from

  • glucose oxidation [25], hence yielding at physiological pH additional provision of H2S.

The gaseous mediator is a weakly acidic molecule endowed with strong lipophilic affinities. In experimental models, the blockade of the TS cascade

  • at CbS or CgL levels significantly depresses or even
  • abolishes the vitally required production of Cys
  • operating at the crossroad of multiple converting processes (Fig. 1).

Addition of Cys to the incubation milieu

  • resumes the generation of H2S [19] in a Cys concentration-dependent manner [77].

The compounds situated downstream both cystathionases in the context of SAA deprivation

  • keep their functional potentialities
  • but are unable to express their converting Cys – H2S capacities
    • in the absence of precursor substrate.

Summing up

inhibition of CbS activity contributes to

  • promote efficient RM processes and
  • maintenance of Met homeostasis

but entails as side-effects

  1. upstream sequestration of Hcy molecules in biological fluids
  2. while decreasing the bioavailability of Cys and GSH
    • working as limiting factors for H2S production.

These last adverse effects thus constitute the Achilles heel of a remarkable adaptive machinery.

ROLES PLAYED BY HYDROGEN SULFIDE

The first demonstration that human tissues may reduce S to H2S was incidentally provided in 1924 when a man given colloid sulfur

  • for the treatment of polyarthritis did rapidly exhale the typical rotten egg malodor [78].
  • H2S may be produced by the intestinal flora [79] and serves as a metabolic fuel for colonocytes [80].
  • Prevention of endogenous poisoning by excessive enteral production is insured by the detoxifying activities of mucosal cells [81],
    • hindering any systemic effect of the gaseous substrate.

The normal H2S concentration measured in mammalian plasmas usually ranges from 10 to 100 μM with a mean average turning around 40-50 μM [19,21,82,83].
This H2S plasma level, appearing as the net product of organs possessing CbS and CgL enzymes and supplemented by the non-enzymatic conversion of S,

  • flows transiently into the vasculature and freely penetrates into all body cells.
  • Supposing that the gaseous reductant is evenly distributed in total body water (45 L in a 70 kg reference man) allows an estimate of
    • bioavailable H2S pool turning around 2 mM which represents, in terms of S participation, largely less than 1 / 1,000 of TBS.

The peculiar adaptive physiology of vegetarian subjects renders very unlikely that their TBS pool might be solicited to release

  • S-substrates prone to undergo conversion to nascent H2S molecules since
  •  they adapt to declining energy and nutrient intakes
  • by switching overall body economy toward downregulated steady state activities.

The release from TBS of substantial amounts of S-compounds occurs

  • only during the onset of hypercatabolic states as documented in trauma patients [31]
  • and in infectious diseases [84], exacting as preliminary step
  • cytokine-induced breakdown of tissue proteins, a selective hallmark of stressful disorders [85].

H2S in fulfilling ROS Scavenger Tasks

The limited disposal of H2S endogenously produced might be readily exhausted in fulfilling ROS scavenging tasks at the site of oxidative lesions.
All body organs generating H2S from TS enzymes are

  • simultaneously producers and consumers of the gaseous substrate whose actual concentration
  • reflects the balance between synthetic and catabolic rates [86].

Clinical investigations show that H2S concentrations found in cerebral homogenates from Alzheimer’s disease (AD) patients are

  • very much lower than expected from values measured in healthy brains [87], suggesting that
  • the gaseous messenger is locally submitted to enhanced consumption rates reflecting disease severity.

The concept is strongly supported by studies pointing to the

  • negative correlation linking the severity of AD to H2S plasma values [88].
  • in pediatric [89] and elderly [90] hypertensive patients as well
  • more severe HHcy-dependent oxidative burden is
    • associated with more intense H2S uptake rates.
  • These H2S cleansing properties are mainly exerted by mitochondrial organelles
    • known to be centrally involved in oxidative disorders [20,91].

Malnourished subjects deprived of Cys and GSH disposal thus incur the risk of H2S-deficiency

  • rendering them unable to properly overcome HHcy-imposed oxidative lesions.

The rapid exhaustion of H2S stores have detrimental consequences as shown disclosing

  • the beneficial effects of exogenous administration of commonly used sulfide salt donors (Na2S and NaHS)
  • generating H2S gas once in solution.

Such supply significantly augments

  • H2S plasma concentrations allowing to counteract ROS damages. 

H2S was primarily recognized as a physiological substrate working as

  • neuromodulator [92] and soon later as
  • vasorelaxant factor [65].

H2S is now regarded as endowed with a broader spectrum of biological properties [18],

  • operating as a general protective mediator
    • against most degenerative organ injuries,
  • being capable of neutralizing or
  • abolishing most ROS harmful effects.

Table 1 collects findings displaying that H2S may promote the synthesis and activity of several

  • anti-oxidative enzymes (catalases, Cu- and Mn-superoxide dismutases, GSH-peroxidases) and
  • stimulate the production of anti-inflammatory reactants (interleukin-10) or
  • conversely downregulate
    • pro-oxidative enzymes (collagenases, elastases),
    • pro-inflammatory cytokines (interleukine-1b, tumor-necrosis factor a) and
    • immune reactions (hyperleukocytosis, diapedesis, phagocytosis).

It has been calculated that 81.5% of H2S undergoes catabolic disintegration in the form of hydrosulfide anion (HS-) or sulfide anion (S2-) [117].
Since S is the main element in the diprotonated H2S molecule (34.08 as molecular mass), it may be considered that

  • partial or complete repair of HHcy-induced lesions constitutes the therapeutic proof that
  • S-deficiency is causally involved in the development of ROS damages.

The concept is sustained by the observation that all synthetic drugs (diclofenac, indomethacine, sildenafil) utilized as surrogate providers of H2S [64,118] are

  • characterized by a large diversity of molecular conformations but
  • share in common the presence of Satom(s) mimicking, once released,
  • H2S-like pharmacological properties.

It remains to be clarified whether the beneficial effects of S-fortification to S-deficient subjects are mediated, among other possible mechanisms, via

  • stimulation [73,74] of anti-oxidative enzymes or inhibition [75,76] of pro-oxidative enzymes.

It is only very recently that the essentiality of S has been recognized, causing Hcy elevation in deficient individuals [119]. It is worth reminding that the

  • gaseous NO substrate may work in concert or antagonistically [66,83] to fine-tuning the helpful properties exerted by H2S on body tissues.

Preliminary studies suggest for instance that NO operates, in combination with H2S, as a potential modulator of endothelial remodeling since

  •  NO-synthase isoforms contribute to the activation of  metalloproteinases involved in the regulation of the collagen/elastin balance defining vascular elastance [83,120].

SUBCLINICAL MALNUTRITION AS WORLDWIDE  SCOURGE

A growing body of data collected along the last decades indicates that

large proportions of mankind still suffer varying degrees of protein and energy deficiency that is associated with

  • increased morbidity and mortality rates.

The determinants of malnutrition are complex and interrelated, comprising

  • socioeconomic and political conditions,
  • insufficient dietary intakes,
  • inadequate caring practices and
  • superimposed inflammatory burden.

Children living in developing countries are paying a heavy toll to chronic malnutrition [121,122] whereas adult populations are handicapped by

  • feeble physical and working capacities,
  • increased vulnerability to infectious complications and
  • reduced life expectancy [123,124].

Cross-sectional studies collected in the eighties indicate that chronic malnutrition remains a worldwide scourge with

  • top prevalence recorded in Asia, whereas
  • sub-Saharan Africa endures medium nutritional distress and
  • Latin America appears as the least affected [125,126].

Along the last decades, significant progresses have been achieved in some countries such as Vietnam [127] and Bangladesh [128]

  • owing to appropriate education programs and improved economic development.

Inequalities however persist between middle class population groups mainly located in affluent urban areas and

  • underprivileged rural communities remaining stagnant on the sidelines of household income growth.

Representative models of these socio-economic disparities in global nutrition and health are illustrated in the two most populated countries in the world, China and India.
Large surveys undertaken in 105 counties of China and recently published have concluded that the rural communities haven’t yet reached the stage of overall welfare [129].
In India, similar investigations have documented that extreme poverty still prevails in the northern mountainous states of the subcontinent [130]. Taken together, southern
Asian countries fail to overcome malnutrition burden [131]. In some African countries, there exists even upward trends suggesting nutritional

deterioration over the years [132] still aggravated by a severe drought. The assessment of malnutrition in children usually rely on anthropometric criteria such as height-for-age, weight for-height, mid upper arm circumference and skinfold thickness allowing to draw the degree of stunting and wasting from these estimates. In adult subjects, BW and BMI are currently selected parameters to which some biochemical measurements are frequently added, notably SA, classical marker of protein nutritional status, and creatininuria (u-Cr), held as indicator of sarcopenia. The former biometric approaches are very useful in that they correctly provide a static picture of the declared stages of malnutrition but fail to recognize the dynamic mechanisms occurring during the preceding months and the adaptive alterations running behind.

Table 1. Reversal of HHcy-Induced Oxidative Damages by Administration of Exogenous H2S

BRAIN EFFECTS

H2S is overproduced in response to neuronal excitation [93], and

  1. increases the sensitivity of N-methyl-D-aspartate (NMDA) reactions to glutamate in hippocampal neurons [23,94].
  2.  improves long-term potentiation, a synaptic model of memory [92,93]
  3. stimulates the inhibitory effects of catalase and superoxide dismutase (SOD) in oxidative stress of endothelial cells [95].
  4.  regulates Ca 2+ homeostasis in microglial cells [96]and it inhibits TNFa expression in microglial cultures [97].
  5.  protects brain cells from neurotoxicity by preventing the rise of ROS in mitochondria [98].

CARDIOVASCULAR EFFECTS

  1. H2S releases vascular smooth muscle,
  2. inhibits platelet aggregation and
  3. reduces the force output of the left ventricule of the heart [18].
  4. maintains vascular smooth muscle tone [66] and
  5. insures protection against arterial hypertension [99].
  6. modifies leucocyte-vascular epithelium interactions in vivo  by
    1. modulating leucocyte adhesion and
    2. diapedesis at the site of inflammation [100].
  7. attenuates myocardial ischemia-reperfusion injury by
    1. depressing IL-1b and mitochondrial function [20].
  8. upregulates the expression of depressed anti-oxidative enzymes in heart infarction and
    1. inhibits myocardial injury [21].
  9. alleviates smooth muscle pain by
    1. stimulating K+ ATP channels [101].
  10. prevents apoptosis of human neutrophil cells
    1. by inhibiting p38 MAP kinase and caspase 3 [102].
  11. potentiates angiogenesis and wound healing [103].

RENAL EFFECTS

  1. H2S downregulates the increased activity of metalloproteinases 2 and 9 involved in extracellular matrix degradation (elastases, collagenases) [19].
  2. Prevents apoptotic cell death in renal cortical tissues [19].
  3. Improves the expression of desmin (marker of podocyte injury) and
  4. restores the drop of nephrin (component of normal slit diaphragm) in the cortical tissues
    1. resulting in reduced proteinuria [19].
  5. Induces hypometabolism revealing protective effects on renal function and survival [104].
  6. Normalizes GSH status and production of ROS in renal diseases [19].
  7. Controls renal ischemia-reperfusion injury and dysfunction [105].
  8. Depresses the expression of inflammatory molecules involved in glomerulosclerosis [106].
  9. Increases renal blood flow, glomerular filtration and urinary Na+ excretion [77].

OTHER ORGAN EFFECTS
Gastrointestinal

  1. H2S insures protection against ROS stress in gastric mucosal epithelia [22].
  2. Accelerates gastric ulcer healing [107].
  3. Reduces gastric injury caused by nonsteroidal anti-inflammatory drugs [108].
  4. Relaxes ileal smooth muscle tone and increases colonic secretions [79].
  5. Attenuates intestinal ischemia-reperfusion injury by increasing SOD and GSH peroxidase status [109].
  6. Stimulates insulin secretion [110] and controls inflammatory events associated with acute pancreatitis [111].
  7. Alleviates hepatic ischemia-reperfusion injury [112].

Pulmonary

  1. Prevents lung oxidative stress in hypoxic pulmonary hypertension caused by low GSH content [113].
  2. Promotes SOD and catalase activities and reduces the production of malondialdehyde in oxidative lung injury [114].
  3. Reduces lung inflammation and remodeling in asthmatic animals [115] and in pulmonary hypertension [116].  ..(see OCCJ 2011;4:34-44)

Assessing Protein-Depleted States

  1.  SA is an insensitive marker of protein-depleted states compared to TTR [134]
  2. SA is an indicator of population than of individual protein status in subclinical PEM.
  3. u-Cr is likewise a meagerly informative tool as 10 % loss of muscle mass is required before it reaches significantly decreased urinary concentrations [135].

The data imply that the magnitude of subclinical malnutrition is largely

  • underscored when classical biometric and laboratory investigations are performed.

Moreover, ruling out the protein component involved in HHcy epidemiology and confining solely attention to the B-vitamin triad led to unachieved conclusions.

  • surveys undertaken in Taiwan [136] and in India [137] established HHcy variance turning around 30 %, indicating that
  • a sizeable percentage of subjects do not come within the vitamin shortage concept.
  • only one recent review recommending the use of TTR in vegetarian subjects [138].

The main reason for making the choice of TTR is grounded on the striking similar plasma profile disclosed by this marker with both LBM and Hcy [29].
Under healthy conditions, the 3 parameters –

  • TTR,
  • LBM,
  • Hcy –
    • indeed show low  concentrations at birth,
    • linear increase without sexual difference in preadolescent children,
    • gender dimorphism in teenagers with higher values recorded in adolescent male subjects
    • thereafter maintenance of distinct plateau levels during adulthood [29,139,140].

Under morbid circumstances, the plasma concentrations of

  • Hcy manifest gradual elevation
  • negatively correlated with LBM downsizing and
  • TTR decline.

In vegetarian subjects and subclinically malnourished patients,

  • rising Hcy and
  • diminished TTR plasma concentrations look as mirror image of each other,
    • revealing divergent distortion from normal and
    • allowing early detection of preclinical steps
    • at the very same time both SA and u-Cr markers still remain silent.

Any disease process characterized by quantitative or qualitative dietary protein restriction or intestinal malabsorption

  • may cause LBM shrinking,
  • downregulation of TTR concentrations and
  • subsequent HHcy upsurge.

These conditions are documented in frank kwashiorkor [141], subclinical protein restriction [27,43] and anorexia nervosa [142].
In patients submitted to weight-reducing programs,

  • LBM was found the sole independent variable
  • negatively correlated with rising Hcy values [143].

Morbid obesity may be alleviated by medical treatment [143] or surgical gastroplasty [144,145],

  • conditions frequently associated with secondary malabsorptive syndromes and malnutrition [146],

How does this account play out in the typical patient with excessive body fat, lipoprotein disoreder, and perhaps diabetes and disordered sleep – an account of acquired HHcy?
Have the studies been done?  Would you expect to see a clear benefit from reduced HHcy_emia  based on a 30 min daily walk, and

  • eating of well fat trimmed meats, fruits and vegetables, and fish, flax seed, or krill oil?

In westernized countries, subclinical protein-depleted states are illustrated in immigrants originating from

  • developing regions but keeping alive their traditional feeding practices [147] or
  • by communities having adopted, for socio-cultural reasons, strict vegan dietary lifestyles [148].

THE ADDITIONAL BURDEN OF S-DEFICIENCY

After N, K and P, elemental S is recognized as the fourth most important macronutrient required for plant development. The essentiality of S in the vegetable kingdom
arose from observations made many decades ago by pedologists and agronomists [149,150] revealing that the withdrawal of sulfate salts from nutrient sources produces
rapid growth retardation,

  • depressed chlorophyllous synthesis,
  • yellowing of leaves and
  • reduction in fertility and crop yields.

A large number of field studies, mainly initiated for economical reasons, has provided continuing gain in fundamental and applied knowledge and led to the overall consensus

  • that SO4 2- -deficiency is a major wordwide problem [151,152].

Field investigations have shown that the concentration of SO4 2- oxyanions in soils and drinking waters

  • may reveal considerable variations ranging from less than 2 mg/L to more than 1 g/L,
  • meaning a ratio exceeding 1 / 500 under extreme circumstances [30].

The main causal factors responsible for unequal distribution of SO4 2- oxyanions are geographical distance from eruptive sites and

  • intensity of soil weathering in rainy countries.

SO4 2- -dependent nutritional deficiencies entail detrimental effects to most African and Latin American crops [151]

  • reaching nevertheless top incidence in southeastern Asia [151,153].
  • and the Indo-Gangetic plain extending from Pakistan to Bangladesh and covering the North of India and Nepal [154].
  1. Intensive agricultural production,
  2. lack of animal manure and
  3. use of fertilizers providing N, K and P substrates
  4. but devoid of sulfate salts may further aggravate that imbalanced situation.

As global population increases steadily and the production of staple plants predicted to escalate considerably,

  • SO4 2- deficient disorders are expected to become more pregnant along the coming years [155] with significant harmful impact for mankind.

Nevertheless, effective preventive efforts are developed in some countries aiming at fortification of soils mainly

  • by ammonium sulfate or calcium sulfate (gypsum) salts,
  • resulting in meaningful improvements in crop yield,
  • SAAs content and biological value and
  • opening more optimistic perspectives for livestock and human consumption [152,155-158].

Contrasting with the tremendously high amounts of data accumulated over decades by pedologists and agronomists on sulfate requirements and metabolism,
the available knowledge on elemental sulfur in human nutrition looks like a black hole. Despite the fact that S8 follows H, C, O, N, Ca and P as the seven most
abundant element in mammalian tissues, it appears as a forgotten item. Not the slightest attention is dedicated to S8 in the authoritative “Present Knowledge
in Nutrition” series of monographs even though they go over most oligo- and trace-elements in minute detail.

The geographical distribution of S8 throughout the earth’s crust is not well-known

  • as extreme paucity of measurements in soils and tap waters prevents reaching a comprehensive overview.

Nevertheless, and because S8 is the obligatory precursor substrate for the oxidative production of sulfate salts,

a decremental dispersion pattern paralleling those of SO4 2- oxyanions is likely to occur with

  • highest values recorded in the vicinity of volcano sources
  •  and lowest values found in remote and washed-out areas.

Obviously, a great deal of research on elemental S remains to be completed by clinical biochemists before rejoining the status of plant agronomy.
Taken together, these data imply that subclinically malnourished subjects living in areas recognized as

  • SO4 2- -deficient for the vegetable kingdom also
  • incur increased risks to become S8-depleted.

This clinical entity most probably prevails in all regions, notably Northern India, where protein malnutrition [130] and sulfur-deficiency [154] coexist.
Combination of both nutritional deprivations explains why the bulk of local dwellers, including young subjects [159,160], may develop HHcy states and CVD disorders

  • characterized by strong refractoriness to vitamin-B supplementation [160] or
  • high incidence of stroke [161] unrelated to the classical Framingham criteria.

The current consensus is that “the problem of CVD in South Asia is different in etiology and magnitude from other parts of the world” [162]. These disquieting findings are
confirmed in several Asian countries [163] and have prompted local cardiologists to exhort their governments to focus more attention on CVD epidemiology [164].

CONCLUDING REMARKS

  1.  vegetarian subjects are not protected against the risk of CVD and stroke which should no longer be regarded as solely affecting populations living in westernized societies
  • whose morbidity and mortality risks are stratified by classical Framingham criteria.
  • Likewise hypercholesterolemia, hyperhomocysteinemia should be incriminated as
    • emblematic risk factor for a panoply of CVD and related disorders.
  • Whereas the causality of cholesterol and lipid fractions largely prevails in affluent societies consuming high amounts of animal-based items,
    • that of homocysteine predominates in population groups whose dietary lifestyle gives more importance to plant products.

 MAIN PHYSICO-CHEMICAL AND METABOLIC CHARACTERISTICS* OF 3 CARRIER-PROTEINS INVOLVED IN THE STRESS RESPONSE

CBG

TTR

RBP
Molecular mass (Da.)

42,650

54,980

21,200
Conformation

monomeric

tetrameric

monomeric
Amino acid sequence

383

4 x 127

182
Carbohydrate load

18 % glycosylated

unglycosylated

unglycosylated
Hormonal binding sites

one for cortisol

two for TH

one for retinol
Association constant (M-1)

3 x 107

7 x 107 (T4)

1.9 x 107
Normal plasma concentration

30 mg/L.

300 mg/L.

50 mg/L.
Biological half-life

5 days

2 days

14 hrs
Bound ligand  concentration

120 µg/L.

80 µg TT4/L.

500 µg/L.
Free ligand concentration

5 µg/L.

20 ng FT4/L.

1 µg/L.
Ratio free : bound ligands

4 %

0.034 %

0.14 %
Distribution volume of free moieties

18 L.

12 L.

18 L.

STIMULATORY AND INHIBITORY EFFECTS MODULATED

BY GLUCOCORTICOIDS

TARGET SYSTEMS

 

INDUCED EFFECTS

REF.
Thymidine kinase

_

 transcription of induced DNA into RNA

112
Alkaline phosphodiesterase I

_

 cleavage of phosphodiester bonds

113
Tyrosine transaminase

_

 transfer of tyrosine amino group

114
Tryptophane oxygenase

_

 formylkynurenine and Trp catabolites

115
Alkaline phosphatase

_

 release of P from phosphoric esters

116
Phosphoenolpyruvate carboxykinase (liver)

_

 glycolysis from pyruvate and ATP production

117
Mannolsyltransferases

_

 dolichol-linked glycosylation of APRs

118
Haptoglobin

_

 APR combining with hemoglobin

119
α1-Anti (chymo) trypsin (α1 AT, α1 ACT)

_

 serpin molecules allowing N-sparing effects

120
α1-Acid glycoprotein (AGP)

_

 glycosylated APR with antibody-like actions

121
Serum amyloid protein (SAA)

_

 defense systems against oxidative burst

122
γ-Fibrinogen

_

 clotting processes and tissue repair

123
C-Reactive Protein (CRP)

_

 complement processes and opsonization

124
Corticosteroid-binding globulin (CBG)

_

 CBG levels, favoring free hypercortisolemia

100
Phosphoenolpyruvate carboxykinase (adipocytes)

_

 ATP turnover and glycolysis

113

THE DUAL MORBID ENTITIES CAUSING LBM DOWNSIZING AND SUBSEQUENT Hcy UPSURGE 

Primary causal factor

  1. Reduced dietary intake of methionine (39,151,152)
  2. Cytokine-induced tissue breakdown (164,165)

Main clinical conditions

  1. Protein malnutrition,
  2. veganism,
  3. intestinal malabsorption (139,155,156,158-160,281)
  4. Trauma,
  5. sepsis,
  6. burns,
  7. Inflammatory & neoplastic disorders (163,166,170,176,179,180)

Physiopathologic mechanisms

  1. Unachieved LBM replenishment (30,33)
  2. Excessive LBM losses (33,167,179)

Overall protein metabolic status

  1. Downregulated
  2. Upregulated

Plasma biomarker(s) of protein status

  1. Transthyretin (TTR) (144,145)
  2. TTR coupled with CRP or other inflammatory indices (31,177,178,284,285)

Insulin resistance status

  1. Normal or low (286)
  2. Increased in proportion of tissue breakdown (177,178,181-183)

status of Cys-GSH-H2S reducing molecules

  1. Decreased enzymatic and non-enzymatic production (39,161,162,287)
  2. Increased production cancelled out by tissue overconsumption (78,171)

Urinary SO42- and S-compounds

  1. Decreased kidney output (76,78,79)
  2. Variable depending on exogenous SAA supply and
  • extent of tissue breakdown (78,163,168,173)

Transmethylation pathway

  1. Depressed (48,93)
  2. Overstimulated (169)

Remethylation pathway

  1. Stimulated (76,83,153)
  2. Overstimulated (169)

Transsulfuration pathway

  1. Inhibited (49,76,83)
  2. Overstimulated (170,173)


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Received: September 30, 2011 Revised: October 12, 2011 Accepted: October 12, 2011
© Yves Ingenbleek; Licensee Bentham Open.
This is an open access article licensed under the terms of the Creative Commons Attribution Non-Commercial License (http://creativecommons.org/licenses/
by-nc/3.0/) which permits unrestricted, non-commercial use, distribution and reproduction in any medium, provided the work is properly cited.

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English: Biosynthesis of cysteine from homocysteine and serine via cystathione intermediate (Photo credit: Wikipedia)

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Fight against Atherosclerotic Cardiovascular Disease: A Biologics not a Small Molecule – Recombinant Human lecithin-cholesterol acyltransferase (rhLCAT) attracted AstraZeneca to acquire AlphaCore

Posted in Atherogenic Processes & Pathology, Chemical Biology and its relations to Metabolic Disease, Disease Biology, Small Molecules in Development of Therapeutic Drugs, Frontiers in Cardiology and Cardiovascular Disorders, Origins of Cardiovascular Disease, Personalized and Precision Medicine & Genomic Research, Pharmaceutical R&D Investment, Pharmacotherapy of Cardiovascular Disease, Systemic Inflammatory Response Related Disorders, tagged , , , , , on April 3, 2013| 7 Comments »

Curator: Aviva Lev-Ari, PhD, RN

If Biologics will help increase HDL in wide market penetration, the market share of Statins will be negatively impacted.

The biologics was developed by NIH funding, as reported on 2/14/2012, see last section, below.

NHLBI SMARTT Program Awards AlphaCore Pharma Funding to Manufacture Potential Treatment for Familial Lecithin-Cholesterol Acyltransferase (LCAT) Deficiency

 

In an Interview I had with the VP of Scientific Affairs at AstraZenaca on 3/18/2013, the Executive Dr. D.S., MD, PhD, told me that the Cardiovascular Therapeutic Area at AstraZeneca is at present and in the future, probably the most important one of all of its businesses to date, thus, the position he is interviewing for, Director of Scientific Affairs Cardiovascular, will be the most powerful one within the Scientific Affairs Office.

Per my discussion of BRILINTA (ticagrelor), referring the VP to my post on this topic on 12/28/2012,

PLATO Trial on ACS: BRILINTA (ticagrelor) better than Plavix® (clopidogrel bisulfate): Lowering chances of having another heart attack

VP said, “the position will be beyond BRILINTA, or Cardiovascular.” A candidate not found yet. AZ keeps on calling, Keeps searching.

AstraZeneca – The Biggest R&D Spenders In Biopharma

Company: AstraZeneca

2011 spending: $5.5 billion
2010 spending: $5.3 billion
Change: +3.6%
Percentage of revenue: 16.3%

Like several other top 10 pharma companies, AstraZeneca ($AZN) saw its R&D expenses climb somewhat in 2011. But this year, as CEO David Brennan unveiled the annual results for 2011, he started with a new restructuring plan. And R&D is intended to bear some of the biggest cuts.

Hit with sliding profits and eviscerated by analysts for one of the weakest late-stage pipelines in the Big Pharma business, Brennan had to do something significant. Of more than 7,000 pink slips being readied, 2,200 were being reserved for R&D as the company moved to shutter R&D facilities in Soedertaelje in Sweden and Montreal. Neuroscience, once a key feature in the pipeline, is being scaled way back, with plans to field a “virtual” team in key hubs.

AstraZeneca became the poster child for the R&D quagmire when Forbes‘ Matthew Herper concluded that AstraZeneca had the worst ratio of R&D costs to approvals in the industry. For a company that went 6 years without a drug approval ahead of the 2009 OK for Onglyza, accumulated setbacks have reached a breaking point.

AstraZeneca, though, can’t cut its way to a turnaround in R&D. That’s going to take new programs and new technologies. It only began to address the issue with a licensing pact for a slate of Amgen antibodies. Research chief Martin Mackay was quick to follow up by telling Reuters‘ Ben Hirschler that more deals were coming. And indeed just weeks later, AstraZeneca acquired a late-stage gout drug with the $1.26 billion buyout of Ardea. The fact that AstraZeneca didn’t bother to stick with its disease strategy, and quickly indicated that it wouldn’t in the future, underscored just how crucial it is to move fast.

Nevertheless, AstraZeneca will find it hard to shake its legacy of failures. Just weeks ago the company was forced to wash its hands of a billion-dollar deal with Targacept ($TRGT) for a prospective depression drug that failed 4 out of 4 late-stage studies. And as criticism mounted, Brennan has been forced to adopt a defensive posture.

“I read and hear and see lots of things, but we’re here trying to change policy, make good decisions and execute our strategy,” the CEO told Bloomberg, vowing to stick to the game plan. “Maybe somebody sees something different, but spending more money does not have a linear increase in the number of returns you get from a research and development perspective.”

AstraZeneca – The Biggest R&D Spenders In Biopharma – FierceBiotech http://www.fiercebiotech.com/special-reports/biggest-rd-spenders-biopharma/astrazeneca-biggest-rd-spenders-biopharma#ixzz2PQN8is2U

On April 3, 2013, FierceBiotech reported that

MEDIMMUNE, ASTRAZENECA’S BIOLOGICS ARM, ACQUIRES ALPHACORE PHARMA

3 April 2013

AstraZeneca today announced that MedImmune, its global biologics research and development arm, has acquired AlphaCore Pharma, an Ann Arbor, Michigan-based biotechnology company focused on the development of ACP-501, a recombinant human lecithin-cholesterol acyltransferase (LCAT) enzyme.

LCAT, an enzyme in the bloodstream, is a key component in the reverse cholesterol transport (RCT) system, which is thought to play a major role in driving the removal of cholesterol from the body and may be critical in the management of high-density lipoprotein (HDL) cholesterol levels.  The LCAT enzyme could also play a role in a rare, hereditary disorder called familial LCAT deficiency (FLD) in which the LCAT enzyme is absent.

Cardiovascular and metabolic disease is a core therapy area for AstraZeneca’s small and large molecule research.

“As the science in this area continues to evolve, we are committed to exploring unique pathways that could lead to new combination or standalone therapies for patients living with chronic and acute cardiovascular diseases,” said Dr. Bahija Jallal, Executive Vice President, MedImmune. “Cardiovascular disease is projected to remain the single leading cause of death worldwide over the next decade and beyond. Through novel approaches like LCAT, we hope to shift the treatment paradigms in this area to help prevent and treat these conditions.”

In 2012, results from a Phase I clinical trial of ACP-501 met the primary safety and tolerability endpoints.  No serious adverse events were reported.  ACP-501 also met the study’s secondary endpoints by rapidly and substantially elevating HDL cholesterol.  The data from this study support ongoing clinical development of ACP-501.

MEDIMMUNE, ASTRAZENECA’S BIOLOGICS ARM, ACQUIRES ALPHACORE PHARMA – FierceBiotech http://www.fiercebiotech.com/press-releases/medimmune-astrazenecas-biologics-arm-acquires-alphacore-pharma#ixzz2PQL73X3f

 AstraZeneca gambles on cardio therapy in AlphaCore buyout

By Ryan McBride

In another early-stage bet, AstraZeneca’s MedImmune unit acquired the biotech AlphaCore Pharma. The deal comes as AstraZeneca ($AZN) reboots a floundering R&D effort and adds a recombinant LCAT enzyme therapy from AlphaCore that could combat cardiovascular disease.

MedImmune, the biologics division of Astra, faces years of additional development before AlphaCore’s ACP-501 becomes part of the London-based pharma group’s late-stage pipeline, which has many holes yet to be filled. Last year, Ann Arbor, MI-based AlphaCore touted Phase I work on ACP-501, reporting that the enzyme therapy was well-tolerated and quickly boosted levels of HDL or “good” cholesterol in patients.

AZ CEO Pascal Soriot

New AstraZeneca CEO Pascal Soriot has signaled his desire to wager on new science amid an overhaul of R&D announced last month that will cost 1,600 research jobs across the company and after the ouster of former R&D chief Martin Mackay in January. Bahija Jallal, executive vice president of MedImmune, survived the round of cutbacks and plans to pursue new biologics such as ACP-501, which she stated could treat both acute and chronic cardiovascular disease.

“Cardiovascular disease is projected to remain the single leading cause of death worldwide over the next decade and beyond,” Jallal said. “Through novel approaches like LCAT, we hope to shift the treatment paradigms in this area to help prevent and treat these conditions.”

The ACP-501 is an engineered version of the natural LCAT enzyme from the liver that plays a role in ridding the body of cholesterol and keeping up levels of beneficial HDL cholesterol. The candidate could aid millions of patients with cholesterol problems as well as those with a rare inherited disease called familial LCAT deficiency that robs the body of the enzyme.

Bahija Jallal, EVP of MedImmune

The AlphaCore buyout comes on the heels of AstraZeneca’s sizable $240 million upfront payment to Moderna Therapeutics to get in early on the startup’s preclinical programs that use messenger RNA to turn cells in the body into makers of healing proteins. The financial details of the AlphaCore buyout weren’t disclosed.

Still, analysts expect Soriot to pull the trigger on larger deals to bolster the late-stage pipeline or even provide marketed products as AstraZeneca faces the impact of patent expirations on blockbuster cholesterol pill Crestor and the heartburn med Nexium. As Reuters noted, the company has only 6 drugs in late-stage development and aims to double that number by 2016.

 SOURCE:
February 14, 2012 09:17 AM Eastern Daylight Time

NHLBI SMARTT Program Awards AlphaCore Pharma Funding to Manufacture Potential Treatment for Familial Lecithin-Cholesterol Acyltransferase (LCAT) Deficiency

ANN ARBOR, Mich. & ROCKVILLE, Md.–(BUSINESS WIRE)–AlphaCore Pharma, a biopharmaceutical company, and Advanced Bioscience Laboratories (ABL), a biomedical contract research and manufacturing company, today announce funding from the National Institutes of Health, National Heart, Lung and Blood Institute (NHLBI) “Science Moving towards Research Translation and Therapy” (SMARTT) program, to manufacture recombinant human lecithin-cholesterol acyltransferase (rhLCAT) for the treatment of familial LCAT deficiency.

“This is a significant step towards developing a treatment for familial LCAT deficiency. We are pleased by the strong support from the NHLBI and ABL and look forward to advancing this program.”

Also known as ACP-501, rhLCAT represents a promising new approach in the fight against atherosclerotic cardiovascular disease, and has demonstrated preclinical efficacy in promoting HDL maturation and cholesterol flux, a natural process by which cholesterol is removed from the body. Currently, ACP-501 is in Phase 1 clinical development with the eventual goal of reducing the risk of cardiovascular events in patients presenting with acute coronary syndrome. Manufacturing support from the NHLBI SMARTT program will enable production of additional material that will be used to determine the safety and efficacy of rhLCAT enzyme replacement therapy for patients with familial LCAT deficiency – a potentially life-threatening illness for which there is no FDA-approved treatment.

“This is a significant step towards developing a treatment for familial LCAT deficiency. We are pleased by the strong support from the NHLBI and ABL and look forward to advancing this program.” said AlphaCore President, Bruce Auerbach.

The enzyme, rhLCAT, will be produced by ABL in its Rockville, MD biologics production facility under a contract from the NHLBI SMARTT program. Dr. Thomas VanCott, ABL’s President and Chief Executive Officer stated, “ABL is privileged to be working with AlphaCore Pharma in support of their ACP-501 (rhLCAT) program. Research in rare genetic diseases can encounter funding hurdles, yet through this NHLBI-sponsored manufacturing project we have the potential to advance an urgently needed enzyme replacement therapy. This effort further demonstrates ABL’s expertise of partnering with the NIH to support major development programs and our commitment to deliver the highest quality cGMP biologics to our clients in a cost-effective manner.”


Peter Greenleaf, chief executive of MedImmune. (Jeffrey MacMillan – JEFFREY MACMILLAN)Peter Greenleaf is stepping down down as president of Gaithersburg-based biotechnology giant MedImmune, according to a company spokesman, to take the helm of parent company AstraZeneca’s Latin America business.

He will be replaced by Bahija Jallal, who currently serves as MedImmune’s executive vice president of research and development. Jallal joined the company in 2006 as vice president of translational sciences.

The leadership change comes as MedImmune was formally designated a biologics research and development site for AstraZeneca, meaning Jallal will report directly to AstraZeneca chief executive Pascal Soriot, said company spokesman Mike O’Brien.

He added that MedImmune’s commercial organization will now report into AstraZeneca’s North American business and its manufacturing group will be folded into AstraZeneca’s global operations group.

“There’s no new news on jobs today,” O’Brien said. “The driver for these changes is not cost but even faster decision-making in key areas of the business and a need to reduce complexity.”

O’Brien said Greenleaf will continue to be based in Maryland, where he has become a figure­head of sorts for the life sciences industry.

Greenleaf was an advocate for Democratic Gov. Martin O’Malley’s InvestMaryland initiative, which allocates state money for investment in local upstarts. He serves as chairman of the Maryland Venture Fund Authority, a nine-member board assigned to oversee its implementation.

MedImmune has long been an anchor of Maryland’s biotechnology hub along the Interstate 270 corridor. The company was purchased by AstraZeneca in 2007 for $15.6 billion, a sales price that some industry observers still question.

The Washington Business Journal reported the personnel changes earlier.

 SOURCE:

REFERENCES

Mineo C, Yuhanna IS, Quon MJ, Shaul PW., (2003). HDL-induced eNOS activation is mediated by Akt and MAP kinases. J. Biol. Chem., 278:9142–9149.

Shaul, PW and Mineo, C, (2004). HDL action on the vascular wall: is the answer NO? J Clin Invest., 15; 113(4): 509–513.

Other related articles to this topic on the Open Access Online Scientific Journal include the following:

Aviva Lev-Ari, PhD, RN, 4/7/2013

 

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Amyloidosis with Cardiomyopathy

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Amyloidosis with Cardiomyopathy

Author: Larry H Bernstein, MD, FACP
Introduction
Amyloidosis describes the various clinical syndromes that occur as a result of damage by amyloid deposits in tissues and organs throughout the body.  Systemic amyloidosis is a relatively rare multisystem disease caused by the deposition of misfolded protein in various tissues and organs. The term amyloid describes the deposition in the extracellular space of certain proteins in a highly characteristic, insoluble fibrillar form.  The disease entity is a disorder of misfolded or misassembled proteins.  There is extracellular amyloid fiber laid down as cross β-sheets disrupting organ function, which may affect the pancreas, kidney, autonomic nervous system, the heart, and in one form causes carpal tunnel syndrome.
It may present to almost any specialty, and diagnosis is frequently delayed. Cardiac involvement is a leading cause of morbidity and mortality, especially in primary light chain (AL) amyloidosis and in both wild-type and hereditary transthyretin amyloidosis. The heart is also occasionally involved in acquired serum amyloid A type (AA) amyloidosis and other rare hereditary types. Clinical phenotype varies greatly between different types of amyloidosis, and even the cardiac presentation has a great spectrum. The incidence of amyloidosis is uncertain, but it is thought that the most frequently diagnosed AL amyloidosis has an annual incidence of 6 to 10 cases per million population in the United Kingdom and United States.
The molecular basis for this particular phenomenon came with the extensive work done on multiple myeloma, antibody structure, and light chains.  In 1950, the discovery of a familial amyloid polyneuropathy was described in Portugal, and there were similar diseases in Sweden and Japan.  There were 72 known variants of transthyretin (TTR) in 1995, and now there are 100.  In addition, the occurance of different TTR associated variants with and without (amyloid) is found is Brazil, UK, US, Israel, Spain, France, Germany, Denmark, and Africa.  The table of variants, organ damage, and geographic location is too large to place on this document. If we refer to amyloid cardiomyopathy, it is exclusively a primary amyloidopathy, not secondary to light chain disorders or an inflammatory disease.  If we consider amyloidosis, we also have to consider family history, organ dysfunction, and we have to make a distinction between primary cardiac involvement, autonomic nervous system instability, and the two coexisting.  Familial amyloid polyneuropathy (FAP) is an extremely debilitating and progressive disease that is only treatable by liver transplantation.  Primary amyloid cardiomyopathy has been treated by heart transplant.  The qualifying statement here is, it depends.

Primary and Secondary Amyloidoses

Amyloid was originally described by pathologists based on microscopy. Amyloidoses are a systemic primary or secondary disease. There are distinctions to be made based on location and type.  The clinical significance of amyloid disease varies enormously, ranging from incidental asymptomatic deposits to localized disease through to rapidly fatal systemic forms that can affect multiple vital organs.
Common causes of secondary amyloidosis are – light chain production (AL) as in plasma cell dyscrasia, amyloid A (AA), senile systemic amyloidosis (diagnosed rarely in life).  The systemic amyloidoses are designated by a capital A (for amyloid) followed by the abbreviation for the chemical identity of the fibril protein. Thus, TTR amyloidosis is abbreviated ATTR, and immunoglobulin light chain type amyloidosis is abbreviated AL. Both normal-sequence TTR and variant-sequence TTR form amyloidosis. Normal-sequence TTR forms cardiac amyloidosis in elderly people, termed senile cardiac amyloidosis (SCA). When it was recognized that SCA is often accompanied by microscopic deposits in many other organs, the alternative name senile systemic amyloidosis (SSA) was proposed. Both terms are now used.
Currently available therapy is focused on reducing the supply of the respective amyloid fibril precursor protein and supportive medical care, which together have greatly improved survival. Chemotherapy and anti-inflammatory treatment for the disorders that underlie AL and AA amyloidosis are guided by serial measurements of the respective circulating amyloid precursor proteins, i.e. serial serum free light chains in AL and serum amyloid A protein in AA type.
Quality of life and prognosis of some forms of hereditary systemic amyloidosis can be improved by liver and other organ transplants. Various new therapies, ranging from silencing RNA, protein stabilizers to monoclonal antibodies, aimed at inhibiting fibril precursor supply, fibril formation or the persistence of amyloid deposits, are in development; some are already in clinical phase.
Ann Clin Biochem May 2012; 49(3 ): 229-241   http://acb.2011.011225v1 49/3/229

What is transthyretin (TTR)?

TTR is a  tetramer of 4 127 amino acid subunits synthesized by the liver that circulates as a transporter of thyroxin, and with retinol-binding protein, transports vitamin A.  It was originally defined by the migration in electrophoresis more anodal to albumin, hence, prealbumin.  It is present in cerebrospinal fluid, secreted by the choroid plexus.  The TTR monomer contains 8 antiparallel beta pleated sheet domains. TTR can be found in plasma and in cerebrospinal fluid and is synthesized by the choroid plexus of the brain and, to a lesser degree, by the retina. Its gene is located on the long arm of chromosome 18 and contains 4 exons and 3 introns.
The concentration in serum can be expected to be above 20 mg/dL in a health adult, but the protein decreases by 1 mg/dL/day postoperatively, and it decreases with acute or chronic renal failure, pneumonia or sepsis, rising again with the onset of anabolism.  Patients in the pulmonary intensive care unit have TTR levels that remain low for 7-10 days, but followup data for the remainder of the hospital stay or in relationship to readmission in the six months after release from hospital care was not part of the study.
A decrease in TTR is associated with the systemic inflammatory response, whereby, the liver reprioritizes the synthesis of proteins with an increase in acute phase reactants (APRs), namely, C-reactive protein (CRP) and a-1 acid glycoprotein, and decreased albumin and TTR.  The inflammatory condition maintains a euthyroid status with decreased TTR because of the availability of free thyroxine in equilibrium with the lower binding protein.  This has been referred to sick euthyroid status. The role in thyroxine transport is not insignificant, as chronic protein malnutrition is associated with hypothyroidism, as originally described by Prof. Yves Ingenbleek, Univ. Louis Pateur, Starsbourg, Fr. in Senegalese children with Kwashiorkor.  However, the importance of TTR as a unique biomarker is not to be downgraded because of what is often refered to as “an inverted APR”.
Transthyretin was discovered to be a good reflection of the “lean body mass”, by Vernon Young, MIT, and Ingenbleek, as a result of 3 decades of study. The ratio of S:N being 1:20 in plant proteins and 1:12.5 in animal sources, is closely related to methylation reactions and sustained deficiency of S intake results in elevated homocysteine level.

What is FAP?

Familial amyloid polyneuropathy (FAP), also called transthyretin-related hereditary amyloidosis, transthyretin amyloidosis or Corino de Andrade’s disease, is an autosomal dominant neurodegenerative disease. It is a form of amyloidosis, and was first identified and described by Portuguese neurologist Mário Corino da Costa Andrade, in the 1950s.FAP is distinct from senile systemic amyloidosis (SAS), which is not inherited, and which was determined to be the primary cause of death for 70% of supercentenarians who have been autopsied.
Familial amyloid polyneuropathy (FAP) is an extremely debilitating and progressive disease that is only treatable by liver transplantation.  Primary amyloid cardiomyopathy has been treated by heart transplant.  The qualifying statement here is, it depends.  Those patients with TTR-amyloidopathy have a specific gene substitution in the TTR gene. Consequently, there is circulation TTR, but it is not effectively involved in thyroxine transport.

Characteristics.

Usually manifesting itself between 20 and 40 years of age, it is characterized by pain, paresthesia, muscular weakness and autonomic dysfunction. In its terminal state, the kidneys and the heart are affected. FAP is characterized by the systemic deposition of amyloidogenic variants of the transthyretin protein, especially in the peripheral nervous system, causing a progressive sensory and motor polyneuropathy. The age at symptom onset, pattern of organ involvement, and disease course vary, but most mutations are associated with cardiac and/or nerve involvement. The gastrointestinal tract, vitreous, lungs, and carpal ligament are also frequently affected. When the peripheral nerves are prominently affected, the disease is termed familial amyloidotic polyneuropathy (FAP). When the heart is involved heavily but the nerves are not, the disease is called familial amyloid cardiomyopathy (FAC). Regardless of which organ is primarily targeted, the general term is simply amyloidosis-transthyretin type, abbreviated ATTR.

Genetics.

  1. TTR mutations accelerate the process of TTR amyloid formation and are the most important risk factor for the development of clinically significant ATTR. More than 85 amyloidogenic TTR variants cause systemic familial amyloidosis. The variant TTR is mostly produced by the liver. Amyloidogenic TTR mutations destabilize TTR monomers or tetramers, allowing the molecule to more easily attain an amyloidogenic intermediate conformation. The tetramer has to dissociate into misfolded monomers to aggregate into a variety of structures including amyloid fibrils. Because most patients are heterozygotes, they deposit both mutant and wild type TTR subnits.
  2. Familial amyloid polyneuropathy has an autosomal dominant pattern of inheritance. FAP is caused by a mutation of the TTR gene, located on human chromosome 18q12.1-11.2. A replacement of valine by methionine at position 30 (TTR V30M) is the mutation most commonly found in FAP.
  3. The disease in the TTR V30M kindreds was termed FAP because early symptoms arose from peripheral neuropathy, but these patients actually have systemic amyloidosis, with widespread deposits often involving the heart, gastrointestinal tract, eye, and other organs.
  4. TTR V122I: This variant, carried by 3.9% of African Americans and over 5% of the population in some areas of West Africa, increases the risk of late-onset (after age 60 years) cardiac amyloidosis. It appears to be the most common amyloid-associated TTR variant worldwide. Affected patients usually do not have peripheral neuropathy.
  5. TTR T60A: This variant causes late-onset systemic amyloidosis with cardiac, and sometimes neuropathic, involvement. This variant originated in northwest Ireland and is found in Irish and Irish American patients.
  6. TTR L58H: Typically affecting the carpal ligament and nerves of the upper extremities, this variant originated in Germany. It has spread throughout the United States but is most common in the mid-Atlantic region.
  7. TTR G6S: This is the most common TTR variant, but it appears to be a neutral polymorphism not associated with amyloidosis. It is carried by about 10% of people of white European descent.

Cardiac transthyretin (TTR) amyloidosis

Cardiac amyloidosis of transthyretin fibril protein (ATTR) type is an infiltrative cardiomyopathy characterised by ventricular wall thickening and diastolic heart failure. More than 27 different precursor proteins have the propensity to form amyloid fibrils. The particular precursor protein that misfolds to form amyloid fibrils defines the amyloid type and predicts the patient’s clinical course. Several types of amyloid can infiltrate the heart, resulting in progressive diastolic and systolic dysfunction, congestive heart failure, and death.  Increased access to cardiovascular magnetic resonance imaging has led to a marked increase in referrals to St George’s University of London, London (Dr. Jason Dungu) of Caucasian patients with wild-type ATTR (senile systemic) amyloidosis and Afro-Caribbean patients with the hereditary ATTR V122I type. Both subtypes present predominantly as isolated cardiomyopathy. The differential diagnosis includes cardiac amyloid light-chain (AL) amyloidosis, which has a poorer prognosis and can be amenable to chemotherapy.

Clinical Presentation

Cardiac amyloidosis, irrespective of type, presents as a restrictive cardiomyopathy characterized by progressive diastolic and subsequently systolic biventricular dysfunction and arrhythmia.1 Key “red flags” to possible systemic amyloidosis include nephrotic syndrome, autonomic neuropathy (eg, postural hypotension, diarrhea), soft-tissue infiltrations (eg, macroglossia, carpal tunnel syndrome, respiratory disease), bleeding (eg, cutaneous, such as periorbital, gastrointestinal), malnutrition/cachexia and genetic predisposition (eg, family history, ethnicity). Initial presentations may be cardiac, with progressive exercise intolerance and heart failure. Other organ involvement, particularly in AL amyloidosis, may cloud the cardiac presentation (eg, nephrotic syndrome, autonomic neuropathy, pulmonary or bronchial involvement). Pulmonary edema is not common early in the disease process, but pleural and pericardial effusions and atrial arrhythmias are often seen. Syncope is common and a poor prognostic sign. It is typically exertional or postprandial as part of restrictive cardiomyopathy, sensitivity to intravascular fluid depletion from loop diuretics combined with autonomic neuropathy, or conduction tissue involvement (atrioventricular or sinoatrial nodes) or ventricular arrhythmia. The latter may rarely cause recurrent syncope. Disproportionate septal amyloid accumulation mimicking hypertrophic cardiomyopathy with dynamic left ventricular (LV) outflow tract obstruction is rare but well documented. Myocardial ischemia can result from amyloid deposits within the microvasculature. Atrial thrombus is common, particularly in AL amyloidosis

Diagnosis and Treatment

imaging – Cardiovascular Magnetic Resonance in Cardiac Amyloidosis*.

Cardiac amyloidosis can be diagnostically challenging. Cardiovascular magnetic resonance (CMR) can assess abnormal myocardial interstitium. In cardiac amyloidosis, CMR shows a characteristic pattern of global subendocardial late enhancement coupled with abnormal myocardial and blood-pool gadolinium kinetics. The findings agree with the transmural histological distribution of amyloid protein and the cardiac amyloid load.
 *AM Maceira; J Joshi; SK Prasad; J Charles Moon, et al. Royal Brompton Hospital, London;
The diagnosis of amyloidosis requires histological identification of amyloid deposits. Congo Red staining renders amyloid deposits salmon pink by light microscopy, with a characteristic apple green birefringence under polarized light conditions. Additional immunohistochemical staining for precursor proteins identifies the type of amyloidosis.  Ultimately, immunogold electron microscopy and mass spectrometry confer the greatest sensitivity and specificity for amyloid typing.
Treatment of cardiac amyloidosis is dictated by the amyloid type and degree of involvement. Consequently, early recognition and accurate classification are essential.
Novel diagnostic and surveillance approaches using imaging (echocardiography, cardiovascular magnetic resonance), biomarkers (brain natriuretic peptide [BNP], high-sensitivity troponin), new histological typing techniques, and current and future treatments, including approaches directly targeting the amyloid deposits.

Etiology

Amyloidosis is caused by the extracellular deposition of autologous protein in an abnormal insoluble β-pleated sheet fibrillary conformation—that is, as amyloid fibrils. More than 30 proteins are known to be able to form amyloid fibrils in vivo, which cause disease by progressively damaging the structure and function of affected tissues. Amyloid deposits also contain minor nonfibrillary constituents, including serum amyloid P component (SAP), apolipoprotein E, connective tissue components (glycosaminoglycans, collagen), and basement membrane components (fibronectin, laminin). Amyloid deposits can be massive, and cardiac or other tissues may become substantially replaced. Amyloid fibrils bind Congo red stain, yielding the pathognomonic apple-green birefringence under cross-polarized light microscopy that remains the gold standard for identifying amyloid deposits.

AL Amyloidosis

AL amyloidosis is caused by deposition of fibrils composed of monoclonal immunoglobulin light chains and is associated with clonal plasma cell or other B-cell dyscrasias. The spectrum and pattern of organ involvement is very wide, but cardiac involvement occurs in half of cases and is sometimes the only presenting feature. Cardiac AL amyloidosis may be rapidly progressive. Low QRS voltages, particularly in the limb leads, are common. Thickening of the LV wall is typically mild to moderate and is rarely >18 mm even in advanced disease. Cardiac AL amyloid deposition is accompanied by marked elevation of the biomarkers BNP and cardiac troponin, even at an early stage. Involvement of the heart is the commonest cause of death in AL amyloidosis and is a major determinant of prognosis; without cardiac involvement, patients with AL amyloidosis have a median survival of around 4 years, but the prognosis among affected patients with markedly elevated BNP and cardiac troponin (Mayo stage III disease) is on the order of 8 months.

Hereditary Amyloidoses

Mutations in several genes, such as transthyretin, fibrinogen, apolipoprotein A1, and apolipoprotein A2 can be responsible for hereditary amyloidosis, but by far the most common cause is variant ATTR amyloidosis (variant ATTR) caused by mutations in the transthyretin gene causing neuropathy and, often, cardiac involvement.

TTR gene mutation

 The most common is the Val122Ile mutation. In a large autopsy study that included individuals with cardiac amyloidosis, the TTR Val122Ile allele was present in 3.9% of all African Americans and 23% of African Americans with cardiac amyloidosis. Penetrance of the mutation is not truly known and is associated with a late-onset cardiomyopathy that is indistinguishable from senile cardiac amyloidosis.

Pathology, Presentation, and Management of Amyloidoses

More than 100 genetic variants of TTR are associated with amyloidosis. Most present as the clinical syndrome of progressive peripheral and autonomic neuropathy. Unlike wild-type ATTR or variant ATTR Val122Ile, the features of other variant ATTR include vitreous amyloid deposits or, rarely, deposits in other organs. Cardiac involvement in variant ATTR varies by mutations and can be the presenting or indeed the only clinical feature. For example, cardiac involvement is rare in variant ATTR associated with Val30Met (a common variant in Portugal or Sweden), but it is almost universal and develops early in individuals with variant ATTR due to Thr60Ala mutation (a mutation common in Ireland).

Senile Systemic Amyloidosis (Wild-Type ATTR)

Wild-type TTR amyloid deposits are found at autopsy in about 25% of individuals >80 years of age.  The prevalence of wild-type TTR deposits leading to the clinical syndrome of wild-type ATTR cardiac amyloidosis is unknown. Wild-type ATTR is a predominantly cardiac disease, and the only other significant extracardiac feature is a history of carpal tunnel syndrome, often preceding heart failure by 3 to 5 years. Extracardiac involvement is most unusual.
Both wild-type ATTR and ATTR due to Val122Ile are diseases of the >60-year age group and are often misdiagnosed as hypertensive heart disease. Wild-type ATTR has a strong male predominance, and the natural history remains poorly understood, but studies suggest a median survival of about 7 years from presentation. Recent developments in cardiac magnetic resonance (CMR), which have greatly improved detection of cardiac amyloid during life, suggest that wild-type ATTR is more common than previously thought: It accounted for 0.5% of all patients seen at the UK amyloidosis center until 2001 but now accounts for 7% of 1100 cases with amyloidosis seen since the end of 2009. There appears to be an association between wild-type ATTR and history of myocardial infarctions, G/G (Val/Val) exon 24 polymorphism in the alpha2-macroglobulin (alpha2M), and the H2 haplotype of the tau gene36; the association of tau with Alzheimer’s disease raises interesting questions as both are amyloid-associated diseases of aging.
ECG of a patient with cardiac AL amyloidosis showing small QRS voltages (defined as ≤6 mm height), predominantly in the limb leads and pseudoinfarction pattern in the anterior leads.
Echocardiography is characteristic. Typical findings include concentric ventricular thickening with right ventricular involvement, poor biventricular long-axis function with normal/near-normal ejection fraction and valvular thickening (particularly in wild-type or variant ATTR). Diastolic dysfunction is the earliest echocardiographic abnormality and may occur before cardiac symptoms develop. Biatrial dilatation in presence of biventricular, valvular, and interatrial septal thickening 53 is a useful clue to the diagnosis.
Transthoracic echocardiogram with speckle tracking. The red and yellow lines represent longitudinal motion in the basal segments, whereas the purple and green lines represent apical motion. This shows loss of longitudinal ventricular contraction at the base compared to apex.

Biomarkers.

High-sensitivity troponin is abnormal in >90% of cardiac AL patients, and the combination of BNP/NT-proBNP plus troponin measurements is used to stage and risk-stratify patients with AL amyloidosis at diagnosis. Very interestingly, the concentration of BNP/NT-proBNP in AL amyloidosis may fall dramatically within weeks after chemotherapy that substantially reduces the production of amyloidogenic light chains. The basis for this very rapid phenomenon, which is not mirrored by changes on echocardiography or CMR, remains uncertain, but a substantial fall is associated with improved outcomes.

Cardiac Magnetic Resonance.

CMR provides functional and morphological information on cardiac amyloid in a similar way to echocardiography, though the latter is superior for evaluating and quantifying diastolic abnormalities. An advantage of CMR is in myocardial tissue characterization. Amyloidotic myocardium reveals subtle precontrast abnormalities (T1, T2), but extravascular contrast agents based on chelated gadolinium provide the key information.

CMR with the classic amyloid global, subendocardial late gadolinium enhancement pattern in the left ventricle with blood and mid-/epimyocardium nulling together.
Recently, the technique of equilibrium contrast CMR has demonstrated much higher extracellular myocardial volume in cardiac amyloid than any other measured disease. It is anticipated that accurate measurements of the expanded interstitium in amyloidosis will prove useful in serial quantification of cardiac amyloid burden.
Sequential static images from a CMR TI scout sequence. As the inversion time (TI) increases, myocardium nulls first (arrow in image 3), followed by blood afterwards (arrow in image 6), implying that there is more gadolinium contrast in the myocardium than blood—a degree of interstitial expansion such that the “myocrit” is smaller than the hematocrit.

Tissue biopsy.

To confirm amyloidosis, including familial TTR amyloidosis, the demonstration of amyloid deposition on biopsied tissues is essential. With Congo red staining, amyloid deposits show a characteristic yellow-green birefringence under polarized light. Tissues suitable for biopsy include: subcutaneous fatty tissue of the abdominal wall, skin, gastric or rectal mucosa, sural nerve, and peritendinous fat from specimens obtained at carpal tunnel surgery. Sensitivity of endoscopic biopsy of gastrointestinal mucosa is around 85%; biopsy of the sural nerve is less sensitive. It is ideal to show that these amyloid deposits are specifically immunolabeled by anti-TTR antibodies.

Serum variant TTR protein.

TTR protein normally circulates in serum or plasma as a soluble protein having a tetrameric structure [Kelly 1998, Rochet & Lansbury 2000]. Normal plasma TTR concentration is 20-40 mg/dL (0.20-0.40 mg/mL).  Pathogenic mutations in TTR cause conformational change in the TTR protein molecule, disrupting the stability of the TTR tetramer, which is then more easily dissociated into pro-amyloidogenic monomers.

After immunoprecipitation with anti-TTR antibody, serum variant TTR protein can be detected by mass spectrometry. Approximately 90% of TTR variants so far identified are confirmed by this method. Mass shift associated with each variant TTR protein is indicated.

Molecular genetic testing.

  • TTR is the only gene in which mutations are known to cause familial TTR amyloidosis.
  • Identified in many individuals of different ethnic backgrounds; found in large clusters in Portugal, Sweden, and Japan.
  • The gene has four exons; and all the hitherto-identified mutations are in exons 2, 3, or 4.
GeneReviews designates a molecular genetic test as clinically available only if the test is listed in the GeneTests Laboratory Directory by either a US CLIA-licensed laboratory or a non-US clinical laboratory.
  • Molecular genetic testing of TTR by sequence analysis (may be preceded by targeted mutation analysis)
  • Although deletion/duplication testing is available clinically, no exonic or whole-gene deletions or duplications involving TTR have been reported to cause familial transthyretin amyloidosis.
  • However, with newly available deletion/duplication testing methods, it is theoretically possible that such mutations may be identified in affected individuals in whom prior testing by sequence analysis of the entire coding region was negative.
  • Predictive testing for at-risk asymptomatic adult family members requires prior identification of the disease-causing mutation in the family.
  • Prenatal diagnosis and preimplantation genetic diagnosis (PGD) for at-risk pregnancies require prior identification of the disease-causing mutation in the family.

Genetically Related (Allelic) Disorders

Familial euthyroid hyperthyroxinemia is caused by normal allelic variants in TTR, including Gly6Ser, Ala109Thr, Ala109Val, and Thr119Met (see Table 5) [Nakazato 1998, Benson 2001, Saraiva 2001]. The TTR protein binds approximately 15% of serum thyroxine. These mutations increase total serum thyroxine concentration because of their increased affinity for thyroxine, however, they increase neither free thyroxine nor free triiodothyronine. Therefore, individuals with these sequence variants develop no clinical symptoms (i.e., they are euthyroid).
Senile systemic amyloidosis (SSA; previously called senile cardiac amyloidosis) results from the pathologic deposition of wild-type TTR, predominantly in the heart. Pathologic deposits are also seen in the lungs, blood vessels, and the renal medulla of the kidneys [Westermark et al 2003]. SSA affects mainly the elderly but is rarely diagnosed during life.
Sensorimotor neuropathy and autonomic neuropathy progress over ten to 20 years. Various types of cardiac conduction block frequently appear. Cachexia is a common feature at the late stage of the disease. Affected individuals usually die of cardiac failure, renal failure, or infection.

Cardiac amyloidosis.

Cardiac amyloidosis, mainly characterized by progressive cardiomyopathy, has been reported with more than two thirds of TTR mutations. In some families with specific TTR mutations, such as Asp18Asn, Val20Ile, Pro24Ser, Ala45Thr, Ala45Ser, His56Arg, Gly57Arg, Ile68Leu, Ala81Thr, Ala81Val, His88Arg, Glu92Lys, Arg103Ser, Leu111Met, or Val122Ile, cardiomyopathy without peripheral neuropathy is a main feature of the disease.

Cardiac amyloidosis is usually late onset. Most individuals develop cardiac symptoms after age 50 years; cardiac amyloidosis generally presents with restrictive cardiomyopathy. The typical electrocardiogram shows a pseudoinfarction pattern with prominent Q wave in leads II, III, aVF, and V1-V3, presumably resulting from dense amyloid deposition in the anterobasal or anteroseptal wall of the left ventricle. The echocardiogram reveals left ventricular hypertrophy with preserved systolic function. The thickened walls present “a granular sparkling appearance.”
Among the mutations responsible for cardiac amyloidosis, Val122Ile is notable for its prevalence in African Americans. Approximately 3.0%-3.9% of African Americans are heterozygous for Val122Ile . The high frequency of Val122Ile partly explains the observation that in individuals in the US older than age 60 years, cardiac amyloidosis is four times more common among blacks than whites.

Leptomeningeal (oculoleptomeningeal) amyloidosis.

Amyloid deposition is seen in the pial and arachnoid membrane, as well as in the walls of vessels in the subarachnoid space associated with TTR mutations including Leu12Pro, Asp18Gly, Ala25Thr, Val30Gly, Ala36Pro, Gly53Glu, Gly53Ala, Phe64Ser, Tyr69His, or Tyr114Cys.  Individuals with leptomeningeal amyloidosis show CNS signs and symptoms including: dementia, psychosis, visual impairment, headache, seizures, motor paresis, ataxia, myelopathy, hydrocephalus, or intracranial hemorrhage. When associated with vitreous amyloid deposits, leptomeningeal amyloidosis is known as familial oculolepto-meningeal amyloidosis (FOLMA). In leptomeningeal amyloidosis protein concentration in the cerebrospinal fluid is usually high, and gadolinium-enhanced MRI typically shows extensive enhancement of the surface of the brain, ventricles, and spinal cord.

Genotype-Phenotype Correlations.

In subsets of families with the Val30Met mutation, considerable variation in phenotypic manifestations and age of onset is observed. It is hypothesized that genetic modifiers and non-genetic factors contribute to the pathogenesis and progression of familial TTR amyloidosis. The vast majority of individuals with familial TTR amyloidosis are heterozygous for a TTR mutation. It has been clinically and experimentally demonstrated that the normal allelic variant c.416C>T (Thr119Met) has a protective effect on amyloidogenesis in individuals who have the Val30Met mutation.

Cardiac amyloidosis is caused by Asp18Asn, Val20Ile, Pro24Ser, Ala45Thr, Ala45Ser, His56Arg, Gly57Arg, Ile68Leu, Ala81Thr, Ala81Val, His88Arg, Glu92Lys, Arg103Ser, Leu111Met, or Val122Ile. Peripheral and autonomic neuropathy are absent or less evident in persons with these mutations.
Leptomeningeal amyloidosis is associated with Leu12Pro, Asp18Gly, Ala25Thr, Val30Gly, Ala36Pro, Gly53Glu, Gly53Ala, Phe64Ser, Tyr69His, or Tyr114Cys.

Penetrance.

It is generally accepted that the penetrance is much higher in individuals in endemic foci than outside of endemic foci. In Portugal, cumulative disease risk in individuals with the Val30Met mutation is estimated at 80% by age 50 and 91% by age 70 years, whereas the risk in French heterozygotes is 14% by age 50 and 50% by age 70 years. In Sweden, the penetrance is much lower: 1.7% by age 30, 5% by age 40, 11% by age 50, 22% by age 60, 36% by age 70, 52% by age 80, and 69% by age 90, respectively.

Nomenclature

The neuropathy associated with TTR mutations, now called familial TTR amyloidosis, was formerly referred to as one of the following:
  • Familial amyloid polyneuropathy type I (or the Portuguese-Swedish-Japanese type)
  • Familial amyloid polyneuropathy type II (or the Indiana/Swiss or Maryland/German type)

Prevalence

The Val30Met mutation, found worldwide, is the most widely studied TTR variant and is responsible for the well-known large foci of individuals with TTR amyloid polyneuropathy in Portugal, Sweden, and Japan. Numerous families with various non-Val30Met mutations have also been identified worldwide.

 Small transthyretin (TTR) ligands as possible therapeutic agents in TTR amyloidoses.

Almeida MR, Gales L, Damas AM, Cardoso I, Saraiva MJ. Porto, Portugal.
Curr Drug Targets CNS Neurol Disord. 2005 Oct;4(5):587-96.
In transthyretin (TTR) amyloidosis TTR variants deposit as amyloid fibrils giving origin, in most cases, to peripheral polyneuropathy, cardiomyopathy, carpal tunnel syndrome and/or amyloid deposition in the eye. The amino acid substitutions in the TTR variants destabilize the tetramer, which may dissociate into non native monomeric intermediates that aggregate and polymerize in amyloid fibrils that further elongate. Since this is a multi-step process there is the possibility to impair TTR amyloid fibril formation at different stages of the process namely by tetramer stabilization, inhibition of fibril formation or fibril disruption. Based on the proposed mechanism for TTR amyloid fibril formation we discuss the action of some of the proposed TTR stabilizers such as derivatives of some NSAIDs (diflunisal, diclofenac, flufenamic acid, and derivatives) and the action of amyloid disrupters such as 4′-iodo-4′-deoxydoxorubicin (I-DOX) and tetracyclines. Among all these compounds, TTR stabilizers seem to be the most interesting since they would impair very early the process of amyloid formation and could also have a prophylactic effect.

Clusterin regulates transthyretin amyloidosis.

Lee KW, Lee DH, Son H, Kim YS, Park JY, et al.  Gyeongnam National University, South Korea
Biochem Biophys Res Commun 2009;388(2):256-60.   http://dx.doi.org/10.1016/j.bbrc.2009.07.166.
Clusterin has recently been proposed to play a role as an extracellular molecular chaperone, affecting the fibril formation of amyloidogenic proteins. The ability of clusterin to influence amyloid fibril formation prompted us to investigate whether clusterin is capable of inhibiting TTR amyloidosis. Here, we report that clusterin strongly interacts with wild-type TTR and TTR variants V30M and L55P under acidic conditions, and blocks the amyloid fibril formation of TTR variants. In particular, the amyloid fibril formation of V30M TTR in the presence of clusterin is reduced to level similar to wild-type TTR. We also demonstrated that clusterin is an effective inhibitor of L55P TTR amyloidosis, the most aggressive form of TTR diseases. The mechanism by which clusterin inhibits TTR amyloidosis appears to be through stabilization of TTR tetrameric structure.

Prognosis.

Cardiac amyloidosis in general has a poor prognosis, but this differs according to amyloid type and availability and response to therapy. Treatment may be classified as follows: supportive therapy (ie, modified heart-failure treatment including device therapy); therapies that suppress production of the respective amyloid fibril precursor protein (eg, chemotherapy in AL amyloidosis); and novel strategies to inhibit amyloid fibril formation or to directly target the amyloid deposits or stabilize the precursor protein (especially in ATTR with drugs such as tafamidis or diflunisal). Cardiac transplantation, although rarely feasible, can be very successful in carefully selected patients.

Reducing Amyloid Fibril Precursor Protein Production

Treatment of amyloidosis is currently based on the concept of reducing the supply of the respective amyloid fibril precursor protein. In AL amyloidosis, therapy is directed toward the clonal plasma cells using either cyclical combination chemotherapy or high-dose therapy with autologous stem cell transplantation.
The newer treatment options include bortezomib (a proteosome inhibitor)105 and the newer immunomodulatory drugs lenalidomide and pomalidomide. Bortezomib combinations appear to be especially efficient in amyloidosis with high rates of near-complete clonal responses, which appear to translate into early cardiac responses.106–108 Phase II (bortezomib in combination with cyclophosphamide or doxorubicin) and phase III (bortezomib, melphalan, and dexamethasone compared to melphalan and dexamethasone as front-line treatment) trials are underway.
AA amyloidosis is the only other type of amyloidosis in which production of the fibril precursor protein can be effectively suppressed by currently available therapies. Anti-inflammatory therapies, such as anti-tumor necrosis factor agents in rheumatoid arthritis, can substantially suppress serum amyloid A protein production, but very little experience has been obtained regarding cardiac involvement, which is very rare in this particular type of amyloidosis.
TTR is produced almost exclusively in the liver, and TTR amyloidosis has lately become a focus for novel drug developments aimed at reducing production of TTR through silencing RNA and antisense oligonucleotide therapies. ALN-TTR01, a systemically delivered silencing RNA therapeutic, is already in phase I clinical trial. Liver transplantation has been used as a treatment for variant ATTR for 20 years, to remove genetically variant TTR from the plasma. Although this is a successful approach in ATTR Val30Met, it has had disappointing results in patients with other ATTR variants, which often involve the heart. The procedure commonly results in progressive cardiac amyloidosis through ongoing accumulation of wild-type TTR on the existing template of variant TTR amyloid. The role of liver transplantation in non-Val30Met–associated hereditary TTR amyloidosis thus remains very uncertain.

Inhibition of Amyloid Formation

Amyloid fibril formation involves massive conformational transformation of the respective precursor protein into a completely different form with predominant β-sheet structure. The hypothesis that this conversion might be inhibited by stabilizing the fibril precursor protein through specific binding to a pharmaceutical has lately been explored in TTR amyloidosis. A key step in TTR amyloid fibril formation is the dissociation of the normal TTR tetramer into monomeric species that can autoaggregate in a misfolded form. In vitro studies identified that diflunisal, a now little used nonsteroidal anti-inflammatory analgesic, is bound by TTR in plasma, and that this enhances the stability of the normal soluble structure of the protein. Studies of diflunisal in ATTR are in progress. Tafamidis is a new compound without anti-inflammatory analgesic properties that has a similar mechanism of action. Tafamidis has just been licensed for neuropathic ATTR, but its role in cardiac amyloidosis remains uncertain, and clinical trial results are eagerly awaited. Higher-affinity “superstabilizers” are also in development.

Conclusion

Cardiac amyloidosis remains challenging to diagnose and to treat. Key “red flags” that should raise suspicion include clinical features indicating multisystem disease and concentric LV thickening on echocardiography in the absence of increased voltage on ECG; the pattern of gadolinium enhancement on CMR appears to be very characteristic. Confirmation of amyloid type is now possible in most cases through a combination of immunohistochemistry, DNA analysis, and proteomics. A variety of novel specific therapies are on the near horizon, with potential to both inhibit new amyloid formation and enhance clearance of existing deposits.

Future Prospects

Jeffery W. Kelly, the former Dean of Graduate Studies (2000-2008) and Vice President of Academic Affairs (2000-2006), currently is the Chairman of Molecular and Experimental Medicine and the Lita Annenberg Hazen Professor of Chemistry within the Skaggs Institute of Chemical Biology at The Scripps Research Institute in La Jolla, California.
The work on folding proteins by the Kelly Group focuses on
[1] understanding protein misfolding and aggregation and on developing both chemical
[2] and biological strategies
[3] to ameliorate diseases caused by protein misfolding and/or aggregation.
Besides studying the structural and energetic basis behind protein folding, his laboratory also studies the etiology of neurodegenerative diseases linked to protein aggregation, including Alzheimer’s disease, Parkinson’s Disease, and the familial gelsolin and transthyretin-based amyloidoses–publishing over 250 peer-reviewed papers in this area to date. He has also provided insight into genetic diseases associated with loss of protein function, such as lysosomal storage diseases.
Kelly has cofounded three biotechnology companies, FoldRx Pharmaceuticals (with Susan Lindquist), now owned by Pfizer, Proteostasis Therapeutics, Inc. (with Andrew Dillin and Richard Morimoto) (a private corporation) and Misfolding Diagnostics (with Xin Jiang and Justin Chapman; a private corporation). The Kelly laboratory discovered the first regulatory agency-approved drug that slows the progression of a human amyloid disease using a structure-based design approach. This drug, now called Tafamidis or Vyndaqel, slowed the progression of familial amyloid polyneuropathy in an 18 month placebo controlled trial and in an 18 month extension study sponsored by FoldRx Pharmaceuticals (acquired by Pfizer in 2010). Vyndaqel or Tafamidis  was approved for the treatment of Familial amyloid Polyneuropathy by the European Medicines Agency in late 2011. Kelly also discovered that diflunisal kinetically stabilizes transthyretin, enabling a placebo controlled clinical trial with it to ameliorate familial amyloid polyneuropathy–the results of which will be announced in 2013. Proteostasis Therapeutics, Inc. is developing first-in-class drugs that adapt the proteostasis network to ameliorate both loss-of-function misfolding diseases and gain-of-toxic function diseases linked to protein aggregation.
In addition to discovering the first drug that slows the progression of a human amyloid disease, the Kelly Laboratory is credited with demonstrating that transthyretin conformational changes alone are sufficient for amyloidogenesis, discovering the first example of functional amyloid in mammals, making major contributions toward understanding β-sheet folding, discovering the “enhanced aromatic sequon”–sequences that are more efficiently glycosylated by cells and sequences which stabilize the proteins that they are incorporated into as a consequence of N-glycosylation and was corresponding author on and contributed some of the key experimental data demonstrating that altering cellular proteostasis capacity has the potential to alleviate protein misfolding and aggregation diseases.
Native state kinetic stabilization as a strategy to ameliorate protein misfolding diseases: a focus on the transthyretin amyloidoses. Johnson SM, Wiseman RL, Sekijima Y, Green NS, Adamski-Werner SL, Kelly JW.  http://www.ncbi.nlm.nih.gov/pubmed/16359163
Small molecule-mediated protein stabilization inside or outside of the cell is a promising strategy to treat protein misfolding/misassembly diseases. Herein we focus on the transthyretin (TTR) amyloidoses and demonstrate that preferential ligand binding to and stabilization of the native state over the dissociative transition state raises the kinetic barrier of dissociation (rate-limiting for amyloidogenesis), slowing and in many cases preventing TTR amyloid fibril formation. Since T119M-TTR subunit incorporation into tetramers otherwise composed of disease-associated subunits also imparts kinetic stability on the tetramer and ameliorates amyloidosis in humans, it is likely that small molecule-mediated native state kinetic stabilization will also alleviate TTR amyloidoses.
Energetic characteristics of the new transthyretin variant A25T may explain its atypical central nervous system pathology.
Sekijima Y, Hammarström P, Matsumura M, Shimizu Y, Iwata M, Tokuda T, Ikeda S, Kelly JW.
Lab Invest. 2003 Mar;83(3):409-17.   http://www.ncbi.nlm.nih.gov/pubmed/12649341
Transthyretin (TTR) is a tetrameric protein that must misfold to form amyloid fibrils. Misfolding includes rate-limiting tetramer dissociation, followed by fast tertiary structural changes that enable aggregation. Amyloidogenesis of wild-type (WT) TTR causes a late-onset cardiac disease called senile systemic amyloidosis. The aggregation of one of > 80 TTR variants leads to familial amyloidosis encompassing a collection of disorders characterized by peripheral neuropathy and/or cardiomyopathy. Prominent central nervous system (CNS) impairment is rare in TTR amyloidosis. Herein, we identify a new A25T TTR variant in a Japanese patient who presented with CNS amyloidosis at age 42 and peripheral neuropathy at age 44. The A25T variant is the most destabilized and fastest dissociating TTR tetramer published to date, yet, surprising, disease onset is in the fifth decade. Quantification of A25T TTR in the serum of this heterozygote reveals low levels relative to WT, suggesting that protein concentration influences disease phenotype. Another recently characterized TTR CNS variant (D18G TTR) exhibits strictly analogous characteristics, suggesting that instability coupled with low serum concentrations is the signature of CNS pathology and protects against early-onset systemic amyloidosis. The low A25T serum concentration may be explained either by impaired secretion from the liver or by increased clearance, both scenarios consistent with A25T’s low kinetic and thermodynamic stability. Liver transplantation is the only known treatment for familial amyloid polyneuropathy. This is a form of gene therapy that removes the variant protein from serum preventing systemic amyloidosis. Unfortunately, the choroid plexus would have to be resected to remove A25T from the CSF-the source of the CNS TTR amyloid. Herein we demonstrate that small-molecule tetramer stabilizers represent an attractive therapeutic strategy to inhibit A25T misfolding and CNS amyloidosis. Specifically, 2-[(3,5-dichlorophenyl)amino]benzoic acid is an excellent inhibitor of A25T TTR amyloidosis in vitro.
Prevention of Transthyretin Amyloid Disease by Changing Protein Misfolding Energetics
Per Hammarström*, R. Luke Wiseman*, Evan T. Powers, Jeffery W. Kelly†
Science 31 Jan 2003; 299(5607):713-716    http://dx.doi.org/10.1126/science.1079589
Genetic evidence suggests that inhibition of amyloid fibril formation by small molecules should be effective against amyloid diseases. Known amyloid inhibitors appear to function by shifting the aggregation equilibrium away from the amyloid state. Here, we describe a series of transthyretin amyloidosis inhibitors that functioned by increasing the kinetic barrier associated with misfolding, preventing amyloidogenesis by stabilizing the native state. The trans-suppressor mutation, threonine 119 → methionine 119, which is known to ameliorate familial amyloid disease, also functioned through kinetic stabilization, implying that this small-molecule strategy should be effective in treating amyloid diseases.
R104H may suppress transthyretin amyloidogenesis by thermodynamic stabilization, but not by the kinetic mechanism characterizing T119 interallelic trans-suppression.
Sekijima Y, Dendle MT, Wiseman RL, White JT, D’Haeze W, Kelly JW.
Amyloid. Jun 2006;13(2):57-66.    http://www.ncbi.nlm.nih.gov/pubmed/16911959
The tetrameric protein transthyretin (TTR) forms amyloid fibrils upon dissociation and subsequent monomer misfolding, enabling misassembly. Remarkably, the aggregation of one of over 100 destabilized TTR variants leads to familial amyloid disease. It is known that trans-suppression mediated by the incorporation of T119M subunits into tetramers otherwise composed of the most common familial variant V30M, ameliorates disease by substantially slowing the rate of tetramer dissociation, a mechanism referred to as kinetic stabilization of the native state. R104H TTR has been reported to be non-pathogenic, and recently, this variant has been invoked as a trans-suppressor of amyloid fibril formation. Here, we demonstrate that the trans-suppression mechanism of R104H does not involve kinetic stabilization of the tetrameric structure, instead its modest trans-suppression most likely results from the thermodynamic stabilization of the tetrameric TTR structure. Thermodynamic stabilization increases the fraction of tetramer at the expense of the misfolding competent monomer decreasing the ability of TTR to aggregate into amyloid fibrils. As a consequence of this stabilization mechanism, R104H may be capable of protecting patients with modestly destabilizing mutations against amyloidosis by slightly lowering the overall population of monomeric protein that can misfold and form amyloid.
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Treatment for Infective Endocarditis

Posted in Aortic Valve: TAVR, TAVI vs Open Heart Surgery, Cardiac & Vascular Repair Tools Subsegment, Coagulation Therapy and Internal Bleeding, Health Economics and Outcomes Research, Infectious Disease & New Antibiotic Targets, Medical Devices R&D and Inventions, Mitral Valve: Repair and Replacement, Regulated Clinical Trials: Design, Methods, Components and IRB related issues, Statistical Methods for Research Evaluation, Systemic Inflammatory Response Related Disorders, tagged , , , , , , , , , , on March 30, 2013| Leave a Comment »

Treatment for Infective Endocarditis

Curator: Larry H Bernstein, MD, FACP

UPDATED on 3/4/2019

WATCH VIDEO

https://consultqd.clevelandclinic.org/tricuspid-valve-reconstruction-for-infective-endocarditis-operative-highlights-video/amp/?__twitter_impression=true

Tricuspid Valve Reconstruction for Infective Endocarditis: Operative Highlights (Video)

There are no easy solutions for acute infective tricuspid valve endocarditis in IV drug users, as the risk of prosthetic endocarditis in this population is high. Complete valve resection without replacement is feasible but leads to progressive right-sided heart failure. Reconstruction of the tricuspid valve with autologous pericardium is an alternative option, as demonstrated in the video case study below.

A 29-year-old female drug abuser with fever, hemoptysis and MRSA bacteremia was started on IV antibiotics. She looked frail and had prominent jugular venous pressure as well as 95 percent saturation on 2 liters of nasal cannula oxygen. She was not on inotropes and had a pulmonary artery pressure of 40/20 mmHg with a good cardiac index. Chest CT showed a large left pleural effusion with associated atelectasis of the left lung. The right lung had manifestations of septic emboli and a smaller pleural effusion.

A Cleveland Clinic surgical team led by cardiothoracic surgeon Faisal Bakaeen, MD, proceeded to excise the patient’s extensive infected and devitalized tissue around the tricuspid valve, leaving only a portion of the anterior leaflet to serve as a reference for reconstruction using autologous pericardium. Dr. Bakaeen walks us through the essential surgical steps — and their underlying rationale — in the narrated operative video below.

SOURCE

https://consultqd.clevelandclinic.org/tricuspid-valve-reconstruction-for-infective-endocarditis-operative-highlights-video/amp/?__twitter_impression=true

 

An article that appeared in NEJM compares early surgery versus conventional treatment for infective endocarditis.
Early Surgery versus Conventional Treatment for Infective Endocarditis
Duk-Hyun Kang, Yong-Jin Kim, Sung-Han Kim, Byung Joo Sun, et al.

N Engl J Med June 28, 2012; 366:2466-2473. http://doi.org/10.1056/NEJMoa1112843

Background and Purpose: While current guidelines advocate surgical management for complicated left-sided infective endocarditis and early surgery for patients with infective endocarditis and congestive heart failure, the indications for surgical intervention to prevent systemic embolism remain unclear. Surgery is favored by experience with complete excision of infected tissue and valve repair, and low operative mortality, but it does not remove concerns about residual active infection, which results in two sets of guidelines, the 2006 ACC-AHA for class IIa indication only for recurrent emboli and persistent vegetation, and the 2009 ESC guidelines for class IIb indication for very large, isolated vegetations. The Early Surgery versus Conventional Treatment in Infective Endocarditis (EASE) trial was conducted to determine whether early surgical intervention woulddecrease rate of death or embolic events.

Patient Enrollment: The study enrolled 76 consecutive patients, 18 years of age or older, with left-sided, native-valve infective endocarditis and a high risk of embolism. For all patients with suspected infective endocarditis, blood cultures were obtained and transthoracic echocardiography was performed within 24 hours after hospitalization. Patients were only eligible for enrollment if they had received a diagnosis of definite infective endocarditis and had severe mitral valve or aortic valve disease and vegetation with a diameter greater than 10 mm. Patients were excluded if they had moderate-to-severe congestive heart failure, infective endocarditis complicated by heart block, annular or aortic abscess, destructive penetrating lesions requiring urgent surgery, or fungal endocarditis, or were over 80 years age, or coexisting major embolic stroke with a risk of hemorrhagic transformation at the time of diagnosis, and a serious coexisting condition. Patients were also excluded if they had infective endocarditis involving a prosthetic valve, right-sided vegetations, or small vegetations (diameter, ≤10 mm) or had been referred from another hospital more than 7 days after the diagnosis of infective endocarditis.
The protocol specified that patients who were assigned to the early-surgery group should undergo surgery within 48 hours after randomization. Patients assigned to the conventional-treatment group were treated according to the AHA guidelines, and surgery was performed only if complications requiring urgent surgery developed during medical treatment or if symptoms persisted after the completion of antibiotic therapy. Details of the study procedures are provided in the Supplementary Appendix, available at NEJM.org.

Study End Points: The primary end point was a composite of in-hospital death or clinical embolic events that occurred within 6 weeks after randomization. An embolic event was defined as a systemic embolism fulfilling both prespecified criteria: the acute onset of clinical symptoms or signs of embolism and the occurrence of new lesions, as confirmed by follow-up imaging studies. Prespecified secondary end points, at 6 months of follow-up, included death from any cause, embolic events, recurrence of infective endocarditis, and repeat hospitalization due to the development of congestive heart failure.

Clinical and Echocardiographic Characteristics of the Patients at Baseline, According to Treatment Group:

The mean age of the patients was 47 years, and 67% were men. The mitral valve was involved in 45 patients, the aortic valve in 22, and both valves in 9. Severe mitral regurgitation was observed in 45 patients, severe aortic regurgitation in 23, severe aortic stenosis in 3, severe mitral regurgitation and stenosis in 1, and both severe mitral regurgitation and aortic regurgitation in 4. The median diameter of vegetation was 12 mm (interquartile range, 11 to 17). All patients met the Duke criteria for definite endocarditis; the most common pathogens in both groups were viridans streptococci (in 30% of all patients), other streptococci (in 30%), and Staphylococcus aureus (in 11%). Characteristics of Antibiotic Therapy, According to Treatment Group: There were no significant between-group differences in terms of control of the underlying infection, the antibiotic regimen used, or the duration of antibiotic therapy.

Surgical Procedures: All patients in the early-surgery group underwent valve surgery within 48 hours after randomization; the median time between randomization and surgery was 24 hours (interquartile range, 7 to 45). Of the 22 patients with involvement of the mitral valve, 8 patients underwent mitral-valve repair and 14 underwent mitral-valve replacement with a mechanical valve. Of the 15 patients with involvement of the aortic valve or both the mitral and aortic valves, 14 underwent mechanical-valve replacement and 1 underwent valve replacement with a biologic prosthesis. Concomitant coronary-artery bypass grafting at the time of valve surgery was performed in 2 patients (5%).

Conventional Therapy: Of the 39 patients assigned to the conventional-treatment group, 30 (77%) underwent surgery during the initial hospitalization (27 patients) or during follow-up (3). The surgical procedures included 11 mitral-valve repairs, 6 mitral-valve replacements (with 5 patients receiving a mechanical valve and 1 a biologic prosthesis), 11 aortic-valve replacements (with 9 patients receiving a mechanical valve and 2 a biologic prosthesis), and 2 combined aortic-valve replacements (with 1 patient receiving a mechanical valve and 1 a biologic prosthesis) and mitral-valve repairs. In 8 patients (21%), indications for urgent surgery developed during hospitalization (median time to surgery after randomization, 6.5 days [interquartile range, 6 to 10]). Elective surgery was performed in an additional 22 patients owing to symptoms or left ventricular dysfunction more than 2 weeks after randomization. Surgical results are shown in the Supplementary Appendix.

Primary End Point: The primary end point of in-hospital death or embolic events within the first 6 weeks after randomization occurred in one patient (3%) in the early-surgery group, as compared with nine (23%) in the conventional-treatment group (hazard ratio, 0.10; 95% confidence interval [CI], 0.01 to 0.82; P=0.03). In the early-surgery group, one patient died in the hospital and no patients had embolic events; in the conventional-treatment group, one patient died in the hospital and eight patients had embolic events (Table 3TABLE 3).
http://www.nejm.org/na101/home/literatum/publisher/mms/journals/content/nejm/2012/nejm_2012.366.issue-26/nejmoa1112843/production/images/small/nejmoa1112843_t3.gif

At 6 weeks after randomization, the rate of embolism was 0% in the early-surgery group, as compared with 21% in the conventional-treatment group (P=0.005). No patient in either group had an embolic event or was hospitalized for congestive heart failure during follow-up. Recurrence of infective endocarditis within 6 months after discharge was not observed in any patient in the early-surgery group but was reported in 1 patient in the conventional-treatment group. Among the 11 patients (28%) in the conventional-treatment group who were treated medically and discharged without undergoing surgery, 1 (3%) died suddenly, 7 (18%) had symptoms related to severe valve disease or recurrence of infective endocarditis (3 of whom underwent surgery during follow-up), and 3 (8%) had no symptoms or embolic events (Table S3 in the Supplementary Appendix).
There was no significant difference between the early-surgery and conventional-treatment groups in all-cause mortality at 6 months (3% and 5%, respectively; hazard ratio, 0.51; 95% CI, 0.05 to 5.66; P=0.59) (Figure 2AFIGURE 2).
http://www.nejm.org/na101/home/literatum/publisher/mms/journals/content/nejm/2012/nejm_2012.366.issue-26/nejmoa1112843/production/images/small/nejmoa1112843_f2.gif
Kaplan–Meier Curves for the Cumulative Probabilities of Death and of the Composite End Point at 6 Months, According to Treatment Group.

At 6 months, the rate of the composite of death from any cause, embolic events, recurrence of infective endocarditis, or repeat hospitalization due to the development of congestive heart failure was 3% in the early-surgery group, as compared with 28% in the conventional-treatment group (hazard ratio, 0.08; 95% CI, 0.01 to 0.65; P=0.02). The estimated actuarial rate of end points was significantly lower in the early-surgery group than in the conventional-treatment group (P=0.009 by the log-rank test) (Figure 2B).

Conclusion: Early surgery performed within 48 hours after diagnosis reduced the composite primary end point of death from any cause or embolic events by effectively reducing the risk of systemic embolism. Moreover, these improvements in clinical outcomes were achieved without an increase in operative mortality or recurrence of infective endocarditis.

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How Might Sleep Apnea Lead to Serious Health Concerns like Cardiac and Cancers?

Posted in Cancer Prevention: Research & Programs, Cell Biology, Signaling & Cell Circuits, Chemical Biology and its relations to Metabolic Disease, Health Economics and Outcomes Research, Medical and Population Genetics, Nutrition, Origins of Cardiovascular Disease, Population Health Management, Nutrition and Phytochemistry, Systemic Inflammatory Response Related Disorders, tagged , , , , , , , , , , , , , , , on March 20, 2013| 1 Comment »

How Might Sleep Apnea Lead to Serious Health Concerns like Cardiac and Cancer?

Author: Larry H Bernstein, MD, FCAP

3.3.16

3.3.16   How Might Sleep Apnea Lead to Serious Health Concerns like Cardiac and Cancer?, Volume 2 (Volume Two: Latest in Genomics Methodologies for Therapeutics: Gene Editing, NGS and BioInformatics, Simulations and the Genome Ontology), Part 2: CRISPR for Gene Editing and DNA Repair

UPDATED on 7/23/2019

Israel-led research team develops AI-based model to detect sleep apnea | The Times of Israel

https://www.timesofisrael.com/israel-led-research-team-develops-ai-based-model-to-detect-sleep-apnea/?utm_source=dlvr.it

What is the link between sleep apnea and cardiovascular disease and is the treatment of obstructive sleep apnea (OSA) by continuous positive airway pressure in patients (CPAP) with heart failure to improve left ventricular systolic function sufficient?  There are statistics incicating the benefit of CPAP and improvement of LVSF in those patients on CPAP with CHF.  But that observation does not get at why the patients benefit, or whether the OSA is sufficient.  Don’t expect a randomized clinical trial of any design to be brought to bear on the subject, considering the ethical issues involved.  We’ll return to that in a moment.
In a recent study researchers in Spain followed thousands of patients at sleep clinics and found that those with the most severe forms of sleep apnea had a 65 percent greater risk of developing cancer of any kind. The second study, of about 1,500 government workers in Wisconsin, showed that those with the most disordered sleep had five times the rate of dying from cancer as people without the sleep disorder (apnea not specified). Both research teams only looked at cancer diagnoses and outcomes in general.  If I lump the two studies, assuming that all patients with the most disordered sleep had OSA and were on CPAP, what does this tell us?  The heart and lung function together as a cardiopulmonary oxygenation unit!  A problem disrupting oxygenation, such as autonomically controlled sleep disruption or, oronasal obstruction (ASSOCIATED WITH SNORING), would be expected to have an effect on alertness during the day, predisposition to CHF from strain on the CP circulation as well as ventilatory impairment and peripheral oxygenation.  It appears that an association with ANY cancer, unspecified, is a long reach.
In both studies the researchers ruled out the possibility that the usual risk factors for cancer, like
  1. age
  2. smoking
  3. alcohol use
  4. physical activity
  5. weight
The association between cancer and disordered breathing at night remained
  • even after they adjusted for confounding variables.
This led to the conclusion that cancer might be linked to (intermittent) lack of oxygen supply interrupting aerobic cell activity over long periods of time.  The conclusion is drawn that from two associations
  • the research on positive outcome from CPAP in OSA and
  • a possible link between breathing and cardiac and cancer clearly
demonstrates the importance of regular breathing exercises (other wise known as ‘Pranayama’ in India) as part of our every day life.
This answers the first observation I posed. That is, the use of CPAP, while enormously important, is not sufficient.  Regular breathing exercises would seem to be helpful, although not a standard part of current treatment. This would be especially important if the movement of the abdominal muscles and diaphragm were synchronized with the expansion of the nthorax for maximum air flow.  This observation is familiar from working with a certified exercise physiologist.   The other part of this is an optimum time for walking and carrying out basic muscle and flexibility exercises several times a week, which has been shown repeatedly by studies on health benefits.
It is not my place to raise some questions about the way the studies were carried out.  The patients who have sleep apnea would be expected to have an increased body mass index (BMI), and while not sarcopenic, more likely to have excess body fat, abdominal distribution in males, and hip distribution in females, amd more importantly, unseen fat in the abdominal peritoneum.  This is related to type 2 diabetes with a metabolic syndrome, a separate indicator of CVD risk.   The metabolic syndrome involves TNF-alpha (once also known as cachexin), IL-1, IL-6, C-reactive protein, and in the case of fat signaling, adipokines, as well as insulin resistance and, as a result, some counter-regulatory secretion of glucocorticosteroids.  This metabolic picture would result in the following:
  1. impaired glucose utilization
  2. some excess and uncompensated gluconeogenesis
  3. the impaired lactate reentry at the end of glycolysis
  4. an effect on allosteric PFK
Features 1-4 look like what Warburg called a Pasteur Effect, not at the clellular level, but in the whole individual.   While obesity and type 2 diabetes are occuring in the young and adolescent population, the consequences might not be seen until years later.  The consequences could be in a middle aged person falling asleep at a meeting, or a series of automabile accidents related to falling asleep at the wheel.
At a time that clinical laboratory measurements are so accurate, and
  • the associations between type 2 diabetes,
  • measurement of wt/ht^2,
  • arm strength,
  • skin fold thickness,

are common measures of fitness, they don’t appear to have any place in these studies. If that is the case, then how is it possible to make sense of a relationship between SEVERITY of sleep disturbance and health outcome.

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Liver Endoplasmic Reticulum Stress and Hepatosteatosis

Posted in Biological Networks, Gene Regulation and Evolution, Biomarkers & Medical Diagnostics, Cell Biology, Signaling & Cell Circuits, Chemical Biology and its relations to Metabolic Disease, Computational Biology/Systems and Bioinformatics, Disease Biology, Small Molecules in Development of Therapeutic Drugs, Genome Biology, International Global Work in Pharmaceutical, Liver & Digestive Diseases Research, Metabolomics, Molecular Genetics & Pharmaceutical, Nutrigenomics, Nutrition, Nutritional Supplements: Atherogenesis, lipid metabolism, Personalized and Precision Medicine & Genomic Research, Pharmaceutical Industry Competitive Intelligence, Population Health Management, Genetics & Pharmaceutical, Population Health Management, Nutrition and Phytochemistry, Scientist: Career considerations, Systemic Inflammatory Response Related Disorders, Technology Transfer: Biotech and Pharmaceutical, tagged , , , , , , , , , , , , , , , , , , , , , , , , , , , , on March 10, 2013| 2 Comments »

Liver Endoplasmic Reticulum Stress and Hepatosteatosis

Larry H Bernstein, MD, FCAP

 

1. Absence of adipose triglyceride lipase protects from hepatic endoplasmic reticulum stress in mice.

Fuchs CD, Claudel T, Kumari P, Haemmerle G, et al.
LabExpMol Hepatology, Medical Univ of Graz, Austria.
Hepatology. 2012 Jul;56(1):270-80.   http://dx.doi.org/10.1002/hep.25601. Epub 2012 May 29.

Nonalcoholic fatty liver disease (NAFLD) is characterized by

  • triglyceride (TG) accumulation and
  • endoplasmic reticulum (ER) stress.

Fatty acids (FAs) may trigger ER stress, therefore,

  •  the absence of adipose triglyceride lipase (ATGL/PNPLA2)-
    • the main enzyme for intracellular lipolysis,
  • releasing FAs, and
  • closest homolog to adiponutrin (PNPLA3)

recently implicated in the pathogenesis of NAFLD-

  • could protect against hepatic ER stress.

Wild-type (WT) and ATGL knockout (KO) mice

  •  were challenged with tunicamycin (TM) to induce ER stress.

Markers of hepatic

  •  lipid metabolism,
  • ER stress, and
  • inflammation were explored
    • for gene expression by
    •  serum biochemistry,
    • hepatic TG and FA profiles,
    • liver histology,
    • cell-culture experiments were performed in Hepa1.6 cells
  • after the knockdown of ATGL before FA and TM treatment.

TM increased hepatic TG accumulation in ATGL KO, but not in WT mice. Lipogenesis and β-oxidation
were repressed at the gene-expression level (sterol regulatory element-binding transcription factor 1c,
fatty acid synthase, acetyl coenzyme A carboxylase 2, and carnitine palmitoyltransferase 1 alpha) in
both WT and ATGL KO mice. Genes for very-low-density lipoprotein (VLDL) synthesis (microsomal
triglyceride transfer protein and apolipoprotein B)

  •  were down-regulated by TM in WT
  • and even more in ATGL KO mice,
  • which displayed strongly reduced serum VLDL cholesterol levels.

ER stress markers were induced exclusively in TM-treated WT, but not ATGL KO, mice:

  •  glucose-regulated protein,
  • C/EBP homolog protein,
  • spliced X-box-binding protein,
  • endoplasmic-reticulum-localized DnaJ homolog 4, and
  • inflammatory markers Tnfα and iNos.

Total hepatic FA profiling revealed a higher palmitic acid/oleic acid (PA/OA) ratio in WT mice.
Phosphoinositide-3-kinase inhibitor-

  • known to be involved in FA-derived ER stress and
  • blocked by OA-
  • was increased in TM-treated WT mice only.

In line with this, in vitro OA protected hepatocytes from TM-induced ER stress. Lack of ATGL may protect from
hepatic ER stress through alterations in FA composition. ATGL could constitute a new therapeutic strategy
to target ER stress in NAFLD.
PMID: 22271167 Diabetes Obes Metab. 2010 Oct;12 Suppl 2:83-92.
http://dx.doi.org/10.1111/j.1463-1326.2010.01275.x.

2. Hepatic steatosis: a role for de novo lipogenesis and the transcription factor SREBP-1c.
Ferré P, Foufelle F. INSERM, and Université Pierre et Marie Curie-Paris, Paris, France.    PMID: 21029304

Excessive availability of plasma fatty acids and lipid synthesis from glucose (lipogenesis) are important determinants of steatosis.
Lipogenesis is an insulin- and glucose-dependent process that is under the control of specific transcription factors,

Insulin induces the maturation of SREBP-1c in the endoplasmic reticulum (ER).

  • SREBP-1c in turn activates glycolytic gene expression,
    • allowing glucose metabolism, and
    • lipogenic genes in conjunction with ChREBP.

Lipogenesis activation in the liver of obese markedly insulin-resistant steatotic rodents is then paradoxical.
It appears the activation of SREBP-1c and thus of lipogenesis is

  •  secondary in the steatotic liver to an ER stress.

The ER stress activates the

  •  cleavage of SREBP-1c independent of insulin,
  • explaining the paradoxical stimulation of lipogenesis
  • in an insulin-resistant liver.

Inhibition of the ER stress in obese rodents

  •  decreases SREBP-1c activation and lipogenesis and
  • improves markedly hepatic steatosis and insulin sensitivity.
  • ER is thus worth considering as a potential therapeutic target for steatosis and metabolic syndrome.

3. SREBP-1c transcription factor and lipid homeostasis: clinical perspective
Ferré P, Foufelle F
Inserm, Centre de Recherches Biomédicales des Cordeliers, Paris, France.
Horm Res. 2007;68(2):72-82. Epub 2007 Mar 5. PMID:17344645

Insulin has long-term effects on glucose and lipid metabolism through its control on the expression of specific genes.
In insulin sensitive tissues and particularly in the liver,

  •  the transcription factor sterol regulatory element binding protein-1c (SREBP-1c) transduces the insulin signal, which is
  • synthetized as a precursor in the membranes of the endoplasmic reticulum
  • which requires post-translational modification to yield its transcriptionally active nuclear form.

Insulin activates the transcription and the proteolytic maturation of SREBP-1c, which induces the

  •  expression of a family of genes
  • involved in glucose utilization and fatty acid synthesis and
  • can be considered as a thrifty gene.

Since a high lipid availability is

  •  deleterious for insulin sensitivity and secretion,
  • a role for SREBP-1c in dyslipidaemia and type 2 diabetes
  • has been considered in genetic studies.

SREBP-1c could also participate in

  •  hepatic steatosis observed in humans
  • related to alcohol consumption and
  • hyperhomocysteinemia
  • concomitant with a ER-stress and
  • insulin-independent SREBP-1c activation.

4. Hepatic steatosis: a role for de novo lipogenesis and the transcription factor SREBP-1c
Ferré P, Foufelle F
INSERM, Centre de Recherches des Cordeliers and Université Pierre et Marie Curie-Paris, Paris, France.
Diabetes Obes Metab. 2010 Oct;12 Suppl 2:83-92. PMID: 21029304
http://dx.doiorg/10.1111/j.1463-1326.2010.01275.x.

Lipogenesis in liver steatosis is

  •  an insulin- and glucose-dependent process
  • under the control of specific transcription factors,
  • sterol regulatory element binding protein 1c (SREBP-1c),
  • activated by insulin and carbohydrate response element binding protein (ChREBP)

Insulin induces the maturation of SREBP-1c in the endoplasmic reticulum (ER).
SREBP-1c in turn activates glycolytic gene expression, allowing –

  •  glucose metabolism in conjunction with ChREBP.

activation of SREBP-1c and lipogenesis is secondary in the steatotic liver to ER stress, which

  •  activates the cleavage of SREBP-1c independent of insulin,
  • explaining the stimulation of lipogenesis in an insulin-resistant liver.
  • Inhibition of the ER stress in obese rodents decreases SREBP-1c activation and improves
  • hepatic steatosis and insulin sensitivity.

ER is thus a new partner in steatosis and metabolic syndrome

5. Pharmacologic ER stress induces non-alcoholic steatohepatitis in an animal model
Jin-Sook Leea, Ze Zhenga, R Mendeza, Seung-Wook Hac, et al.
Wayne State University SOM, Detroit, MI
Toxicology Letters 20 May 2012; 211(1):29–38      http://dx.doi.org/10.1016/j.toxlet.2012.02.017

Endoplasmic reticulum (ER) stress refers to a condition of

  •  accumulation of unfolded or misfolded proteins in the ER lumen, which is known to
  • activate an intracellular stress signaling termed
  • Unfolded Protein Response (UPR).

A number of pharmacologic reagents or pathophysiologic stimuli

  •  can induce ER stress and activation of the UPR signaling,
  • leading to alteration of cell physiology that is
  • associated with the initiation and progression of a variety of diseases.

Non-alcoholic steatohepatitis (NASH), characterized by hepatic steatosis and inflammation, has been considered the
precursor or the hepatic manifestation of metabolic disease. In this study, we delineated the

  • toxic effect and molecular basis
  • by which pharmacologic ER stress,
  • induced by a bacterial nucleoside antibiotic tunicamycin (TM),
  • promotes NASH in an animal model.

Mice of C57BL/6J strain background were challenged with pharmacologic ER stress by intraperitoneal injection of TM. Upon TM injection,

  •  mice exhibited a quick NASH state characterized by
  • hepatic steatosis and inflammation.

TM-treated mice exhibited an increase in –

  •  hepatic triglycerides (TG) and a –
  • decrease in plasma lipids, including
  • plasma TG,
  • plasma cholesterol,
  • high-density lipoprotein (HDL), and
  • low-density lipoprotein (LDL),

In response to TM challenge,

  •  cleavage of sterol responsive binding protein (SREBP)-1a and SREBP-1c,
  •  the key trans-activators for lipid and sterol biosynthesis,
  • was dramatically increased in the liver.

Consistent with the hepatic steatosis phenotype, expression of

  •  some key regulators and enzymes in de novo lipogenesis and lipid droplet formation was up-regulated,
  • while expression of those involved in lipolysis and fatty acid oxidation was down-regulated
  • in the liver of mice challenged with TM.

TM treatment also increased phosphorylation of NF-κB inhibitors (IκB),

  •  leading to the activation of NF-κB-mediated inflammatory pathway in the liver.

Our study not only confirmed that pharmacologic ER stress is a strong “hit” that triggers NASH, but also demonstrated

  •  crucial molecular links between ER stress,
  • lipid metabolism, and
  • inflammation in the liver in vivo.

Highlights
► Pharmacologic ER stress induced by tunicamycin (TM) induces a quick NASH state in vivo.
► TM leads to dramatic increase in cleavage of sterol regulatory element-binding protein in the liver.
► TM up-regulates lipogenic genes, but down-regulates the genes in lipolysis and FA oxidation.
► TM activates NF-κB and expression of genes encoding pro-inflammatory cytokines in the liver.
Abbreviations
ER, endoplasmic reticulum; TM, tunicamycin; NASH, non-alcoholic steatohepatitis; NAFLD,
non-alcoholic fatty liver disease; TG, triglycerides; SREBP, sterol responsive binding protein;
NF-κB, activation of nuclear factor-kappa B; IκB, NF-κB inhibitor
Keywords: ER stress; Non-alcoholic steatohepatitis; Tunicamycin; Lipid metabolism; Hepatic inflammation
Figures and tables from this article:

Fig. 1. TM challenge alters lipid profiles and causes hepatic steatosis in mice. (A) Quantitative real-time RT-PCR analysis of liver mRNA isolated from mice challenged with TM or vehicle control. Total liver mRNA was isolated at 8 h or 30 h after injection with vehicle or TM (2 μg/g body weight) for real-time RT-PCR analysis. Expression values were normalized to β-actin mRNA levels. Fold changes of mRNA are shown by comparing to one of the control mice. Each bar denotes the mean ± SEM (n = 4 mice per group); **P < 0.01. Edem1, ER degradation enhancing, mannosidase alpha-like 1. (B) Oil-red O staining of lipid droplets in the livers of the mice challenged with TM or vehicle control (magnification: 200×). (C) Levels of TG in the liver tissues of the mice challenged with TM or vehicle control. (D) Levels of plasma lipids in the mice challenged with TM or vehicle control. TG, triglycerides; TC, total plasma cholesterol; HDL, high-density lipoproteins; VLDL/LDL, very low and low density lipoproteins. For C and D, each bar denotes mean ± SEM (n = 4 mice per group); *P < 0.05; **P < 0.01.

 Fhttp://ars.els-cdn.com/content/image/1-s2.0-S0378427412000732-gr1.jpgigure options

Fig. 2. TM challenge leads to a quick NASH state in mice. (A) Histological examination of liver tissue sections of the mice challenged with TM (2 μg/g body weight) or vehicle control. Upper panel, hematoxylin–eosin (H&E) staining of liver tissue sections; the lower panel, Sirius staining of collagen deposition of liver tissue sections (magnification: 200×). (B) Histological scoring for NASH activities in the livers of the mice treated with TM or vehicle control. The grade scores were calculated based on the scores of steatosis, hepatocyte ballooning, lobular and portal inflammation, and Mallory bodies. The stage scores were based on the liver fibrosis. Number of mice examined is given in parentheses. Mean ± SEM values are shown. P-values were calculated by Mann–Whitney U-test.

 http://ars.els-cdn.com/content/image/1-s2.0-S0378427412000732-gr2.jpg

Fig. 3. TM challenge significantly increases levels of cleaved/activated forms of SREBP1a and SREBP1c in the liver. Western blot analysis of protein levels of SREBP1a (A) and SREBP1c (B) in the liver tissues from the mice challenged with TM (2 μg/g body weight) or vehicle control. Levels of GAPDH were included as internal controls. For A and B, the values below the gels represent the ratios of mature/cleaved SREBP signal intensities to that of SREBP precursors. The graph beside the images showed the ratios of mature/cleaved SREBP to precursor SREBP in the liver of mice challenged with TM or vehicle. The protein signal intensities shown by Western blot analysis were quantified by NIH imageJ software. Each bar represents the mean ± SEM (n = 3 mice per group); **P < 0.01. SREBP-p, SREBP precursor; SREBP-m, mature/cleaved SREBP.

 http://ars.els-cdn.com/content/image/1-s2.0-S0378427412000732-gr3.jpg

Fig. 4. TM challenge up-regulates expression of genes involved in lipogenesis but down-regulates expression of genes involved in lipolysis and FA oxidation. Quantitative real-time RT-PCR analysis of liver mRNAs isolated from the mice challenged with TM (2 μg/g body weight) or vehicle control, which encode regulators or enzymes in: (A) de novo lipogenesis: PGC1α, PGC1β, DGAT1 and DGAT2; (B) lipid droplet production: ADRP, FIT2, and FSP27; (C) lipolysis: ApoC2, Acox1, and LSR; and (D) FA oxidation: PPARα. Expression values were normalized to β-actin mRNA levels. Fold changes of mRNA are shown by comparing to one of the control mice. Each bar denotes the mean ± SEM (n = 4 mice per group); **P < 0.01. (E and F) Isotope tracing analysis of hepatic de novo lipogenesis. Huh7 cells were incubated with [1-14C] acetic acid for 6 h (E) or 12 h (F) in the presence or absence of TM (20 μg/ml). The rates of de novo lipogenesis were quantified by determining the amounts of [1-14C]-labeled acetic acid incorporated into total cellular lipids after normalization to cell numbers.

 http://ars.els-cdn.com/content/image/1-s2.0-S0378427412000732-gr4.jpg

Fig. 5. TM activates the inflammatory pathway through NF-κB, but not JNK, in the liver. Western blot analysis of phosphorylated Iκ-B, total Iκ-B, phosphorylated JNK, and total JNK in the liver tissues from the mice challenged with TM (2 μg/g body weight) or vehicle control. Levels of GAPDH were included as internal controls. The values below the gels represent the ratios of phosphorylated protein signal intensities to that of total proteins.

 http://ars.els-cdn.com/content/image/1-s2.0-S0378427412000732-gr5.jpg

Fig. 6. TM induces expression of pro-inflammatory cytokines and acute-phase responsive proteins in the liver. Quantitative real-time RT-PCR analyses of liver mRNAs isolated from the mice challenged with TM (2 μg/g body weight) or vehicle control, which encode: (A) pro-inflammatory cytokine TNFα and IL6; and (B) acute-phase protein SAP and SAA3. Expression values were normalized to β-actin mRNA levels. Fold changes of mRNA are shown by comparing to one of the control mice. (C–E) ELISA analyses of serum levels of TNFα, IL6, and SAP in the mice challenged with TM or vehicle control for 8 h ELISA. Each bar denotes the mean ± SEM (n = 4 mice per group); *P < 0.05, **P < 0.01.

http://ars.els-cdn.com/content/image/1-s2.0-S0378427412000732-gr6.jpg

Corresponding author at: Center for Molecular Medicine and Genetics, Wayne State University School of Medicine, 540 E. Canfield Avenue, Detroit, MI 48201, USA. Tel.: +1 313 577 2669; fax: +1 313 577 5218.

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Genomics & Genetics of Cardiovascular Disease Diagnoses: A Literature Survey of AHA’s Circulation Cardiovascular Genetics, 3/2010 – 3/2013

Posted in Atherogenic Processes & Pathology, Biological Networks, Gene Regulation and Evolution, Biomarkers & Medical Diagnostics, Cardiovascular Pharmacogenomics, Chemical Genetics, Computational Biology/Systems and Bioinformatics, Disease Biology, Small Molecules in Development of Therapeutic Drugs, FDA Regulatory Affairs, Frontiers in Cardiology and Cardiovascular Disorders, Genome Biology, Genomic Testing: Methodology for Diagnosis, HTN, Liver & Digestive Diseases Research, Metabolomics, Molecular Genetics & Pharmaceutical, Origins of Cardiovascular Disease, Personalized and Precision Medicine & Genomic Research, Pharmaceutical Analytics, Pharmacogenomics, Population Health Management, Genetics & Pharmaceutical, Proteomics, Regulated Clinical Trials: Design, Methods, Components and IRB related issues, Statistical Methods for Research Evaluation, Systemic Inflammatory Response Related Disorders, Technology Transfer: Biotech and Pharmaceutical, tagged , , , , , , , , , , , on March 7, 2013| 25 Comments »

Genomics & Genetics of Cardiovascular Disease Diagnoses: A Literature Survey of AHA’s Circulation Cardiovascular Genetics, 3/2010 – 3/2013

 

Curators: Aviva Lev-Ari, PhD, RN and Larry H. Bernstein, MD, FCAP

 

348 articles that appeared in AHA’s Circulation Cardiovascular Genetics, 3/2010 – 3/2013 were classified by the curators of this article into the following TEN categories. The first 9, represent DIAGNOSES of cardiovascular diseases, the last, deals with Pharmacogenomics.

The Cardiovascular Diagnoses that were covered in the period of 3/2010 – 3/2013, include the following:

  • Preventative Cardiology
  • MicroRNA in Serum as Bimarker for Cardiovascular Pathologies: acute myocardial infarction, viral myocarditis, diastolic dysfunction, and acute heart failure
  • Genetic Determinants of Potassium Sensitivity and Hypertension
  • Heart and Aging Research in Genomic Epidemiology: 1700 MIs and 2300 coronary heart disease events among about 29 000 eligible patients
  • Genetics of CVD and Hyperlipidemia, Hyper Cholesterolemia, Metabolic Syndrome
  • Genomics and Valvular Disease
  • Pharmacogenomics

Introductions

Larry H. Bernstein, MD, FCAP

 

The curation of this large amount of material in 10 categories begins with a first chapter on preventative cardiology, which has had much public attention for the last decade.  Much of the concern with preventive cardiology has emphasized diet and exercise.  There is much to be said about this in articles not yet written.  However, there are several decades of research on the amino acid composition of foods, and the essential fatty acids, that indicates an essential balance between proinflammatory and antiinflammatory fatty acids in polyunsaturated fatty acids, and of the harmful effects of saturated fats.  There is also much to be said of essential amino acids, and in particular, those essential for methylation processes, and sulfur metabolism.

The next eight chapters are all concerned with genomics in cardiovascular disease.  This is in no small part a follow up on the completion of the genetic code in 2003, a seminal event.  Let us look at these in clusters.

[1]   microRNA in serum is now considered for a biomarker for cardiovascular disease.  It can be measured at very low levels, but we don’t yet know where it fits.   It might be more revealing once we understand the adaptive mechanism in development of congestive heart failure, renal hypertension, and post-genomic events.

[2]  It appears to me that potassium sensitivity and hypertension approached from the genomic side is more complicate.  Why is that?   The kidney excretes a sodium load and in metabolic acidosis, the serum potassium rises with a metabolic acidemia that can’t be compensated by the respiratory loss of CO2 through the carbonic anhydrase mechanism.

[3]  Heart and aging research is a rich area for work on the long term post-genomic changes, and it involves a large population base.

[4][5]  The genomics of cardiac dysrrhytmias and cardiomyopathies will open new doors into our understanding of the mechanisms of these diseases, and perhaps find therapeutic targets.  There has been a large volume of work on lipid synthesis, the role of the liver in generating apolipoproteins, and this has new answers on the way.  The most important feature, not readily accepted is the measurement of particles, which has now been done by a monoclonal antibody.  Metabolic syndrome brings together adipose tissue metabolism, endocrine and changes in CRP and IL-1.

[6]   Vascular pathologies and coagulation, hyperviscosity has had an enormous increase in intensity of research.  The concept of plaque rupture to account for all AMIs is being modified, and the high sensitivity cardio-specific troponins have become the most widely use test.

[7]  The genomics of valvular disease fits with the increased surgical procedures for valvular disease related to atheroschlerosis and advent of minimally invasive surgical procedures for the reapir and replacement of valves, procedure called TAVR vs. Openhealrt surgery for valve replacement.

[8]  Inherited cardiovascular disease is an older family of disorders, going back to Victor McKusik, and also the “Blue Baby” operation, both at Johns Hopkins.

[9] Pharmacogenomics is a vary active field of investigation and has uncovered inter-individual differences in handling Warfarin as a starter.

 

 

Preventative Cardiology

 

Methods in Genetics and Clinical Interpretation Randomized Trial of Personal Genomics for Preventive Cardiology Design and Challenges

Joshua W. Knowles, MD, PhD, Themistocles L. Assimes, MD, PhD, Michaela Kiernan, PhD, Aleksandra Pavlovic, BS, Benjamin A. Goldstein, PhD, Veronica Yank, MD, Michael V. McConnell, MD, Devin Absher, PhD, Carlos Bustamante, PhD, Euan A. Ashley, MD, DPhil and John P.A. Ioannidis, MD, DSc

Author Affiliations

From the Division of Cardiovascular Medicine (J.W.K., T.L.A., A.P., M.V.M., E.A.A.), Stanford Prevention Research Center (M.K., V.Y., J.P.A.I.), Division of General Medical Disciplines (V.Y.), Department of Genetics (C.B.), Department of Health Research and Policy (J.P.A.I.), Stanford University School of Medicine, Stanford, CA; Quantitative Sciences Unit, Stanford University School of Medicine, Palo Alto, CA (B.A.G.); HudsonAlpha Institute for Biotechnology, Huntsville, AL (D.A.); Department of Statistics, Stanford University School of Humanities and Sciences, Stanford, CA (J.P.A.I.).

Correspondence to Joshua W. Knowles, MD, PhD, Stanford University School of Medicine, Division of Cardiovascular Medicine, Falk CVRC, 300 Pasteur Dr, Stanford, CA 94305. E-mail knowlej@stanford.edu

Background

Genome-wide association studies (GWAS) have identified more than 1500 disease-associated single nucleotide polymorphisms (SNPs), including many related to atherosclerotic cardiovascular disease (CVD). Associations have been found for most traditional risk factors (TRFs), including lipids,1,2 blood pressure/hypertension,3,4 weight/body mass index,5,6 smoking behavior,7 and diabetes.8–13 GWAS have also identified susceptibility variants for coronary heart disease (CHD). The first and, so far, strongest of these signals was found in the 9p21.3 locus, where common variants in this region increase the relative risk of CVD by 15% to 30% per risk allele in most race/ethnic groups.13–20 Subsequent large-scale GWAS meta-analyses and replication studies in largely white/European populations have led to the reliable identification of an additional 26 loci conferring susceptibility to CHD,2,20–23 all with substantially lower effects sizes compared with the 9p21 locus. Many of these CVD susceptibility loci appear to be conferring risk independent of TRFs and thus cannot currently be assessed by surrogate clinical measures (Table 1). Among the 27 independent loci identified in the most recent large meta-analyses of CVD, 21 were reported not to be associated with any of the TRFs.20,21

 SOURCE

Circulation: Cardiovascular Genetics 2012; 5: 368-376

doi: 10.1161/ CIRCGENETICS.112.962746

 

 

MicroRNA in Serum as Bimarker for Cardiovascular Pathologies: acute myocardial infarction, viral myocarditis,  diastolic dysfunction, and acute heart failure

Increased MicroRNA-1 and MicroRNA-133a Levels in Serum of Patients With Cardiovascular Disease Indicate Myocardial Damage

 

Yasuhide Kuwabara, MD, Koh Ono, MD, PhD, Takahiro Horie, MD, PhD, Hitoo Nishi, MD, PhD, Kazuya Nagao, MD, PhD, Minako Kinoshita, MD, PhD, Shin Watanabe, MD, PhD, Osamu Baba, MD, Yoji Kojima, MD, PhD, Satoshi Shizuta, MD, Masao Imai, MD, Toshihiro Tamura, MD, Toru Kita, MD, PhD and Takeshi Kimura, MD, PhD

Author Affiliations

From the Department of Cardiovascular Medicine, Graduate School of Medicine, Kyoto University, Kyoto, Japan (Y. Kuwabara, K.O., T.H., H.N., K.N., M.K., S.W., O.B., Y. Kojima, S.S., M.I., T.T., T. Kimura); and Kobe City Medical Center General Hospital, Kobe, Japan (T. Kita).

Correspondence to Koh Ono, MD, PhD, Department of Cardiovascular Medicine, Graduate School of Medicine, Kyoto University, 54 Shogoin-kawahara-cho, Sakyo-ku, Kyoto, Japan 606-8507. E-mail kohono@kuhp.kyoto-u.ac.jp

 

Abstract

Background—Recently, elevation of circulating muscle-specific microRNA (miRNA) levels has been reported in patients with acute myocardial infarction. However, it is still unclear from which part of the myocardium or under what conditions miRNAs are released into circulating blood. The purpose of this study was to identify the source of elevated levels of circulating miRNAs and their function in cardiovascular diseases.

Conclusions—These results suggest that elevated levels of circulating miR-133a in patients with cardiovascular diseases originate mainly from the injured myocardium. Circulating miR-133a can be used as a marker for cardiomyocyte death, and it may have functions in cardiovascular diseases.

SOURCE:

Circulation: Cardiovascular Genetics. 2011; 4: 446-454

Published online before print June 2, 2011,

doi: 10.1161/ CIRCGENETICS.110.958975

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Circulating MicroRNA-208b and MicroRNA-499 Reflect Myocardial Damage in Cardiovascular Disease

Maarten F. Corsten, MD, Robert Dennert, MD, Sylvia Jochems, BSc, Tatiana Kuznetsova, MD, PhD, Yvan Devaux, PhD, Leon Hofstra, MD, PhD, Daniel R. Wagner, MD, PhD, Jan A. Staessen, MD, PhD, Stephane Heymans, MD, PhD and Blanche Schroen, PhD

Author Affiliations

From the Center for Heart Failure Research (M.F.C., R.D., S.J., S.H., B.S.), Cardiovascular Research Institute, Maastricht, The Netherlands; the Division of Hypertension and Cardiovascular Rehabilitation (T.K., J.A.S.), Department of Cardiovascular Diseases, University of Leuven, Leuven, Belgium and Department of Epidemiology, Maastricht University Medical Center, Maastricht, The Netherlands; Centre de Recherche Public–Santé, Luxembourg (Y.D., D.R.W.), Luxembourg; Maastricht University Medical Center (L.H.), Maastricht, The Netherlands; and Centre Hospitalier Luxembourg (D.R.W.), Luxembourg.

Correspondence to Blanche Schroen, PhD, Center for Heart Failure Research, Cardiovascular Research Institute Maastricht, Universiteitssingel 50, 6229 ER Maastricht, The Netherlands. E-mail b.schroen@cardio.unimaas.nl

Drs Heymans and Schroen contributed equally to this work.

Abstract

Background— Small RNA molecules, called microRNAs, freely circulate in human plasma and correlate with varying pathologies. In this study, we explored their diagnostic potential in a selection of prevalent cardiovascular disorders.

Methods and Results— MicroRNAs were isolated from plasmas from well-characterized patients with varying degrees of cardiac damage:

(1) acute myocardial infarction,

(2) viral myocarditis,

(3) diastolic dysfunction, and

(4) acute heart failure.

Plasma levels of selected microRNAs, including heart-associated (miR-1, -133a, -208b, and -499), fibrosis-associated (miR-21 and miR-29b), and leukocyte-associated (miR-146, -155, and -223) candidates, were subsequently assessed using real-time polymerase chain reaction. Strikingly, in plasma from acute myocardial infarction patients, cardiac myocyte–associated miR-208b and -499 were highly elevated, 1600-fold (P<0.005) and 100-fold (P<0.0005), respectively, as compared with control subjects. Receiver operating characteristic curve analysis revealed an area under the curve of 0.94 (P<1010) for miR-208b and 0.92 (P<109) for miR-499. Both microRNAs correlated with plasma troponin T, indicating release of microRNAs from injured cardiomyocytes. In viral myocarditis, we observed a milder but significant elevation of these microRNAs, 30-fold and 6-fold, respectively. Plasma levels of leukocyte-expressed microRNAs were not significantly increased in acute myocardial infarction or viral myocarditis patients, despite elevated white blood cell counts. In patients with acute heart failure, only miR-499 was significantly elevated (2-fold), whereas no significant changes in microRNAs studied could be observed in diastolic dysfunction. Remarkably, plasma microRNA levels were not affected by a wide range of clinical confounders, including age, sex, body mass index, kidney function, systolic blood pressure, and white blood cell count.

Conclusions— Cardiac damage initiates the detectable release of cardiomyocyte-specific microRNAs-208b and -499 into the circulation.

SOURCE:

Circulation: Cardiovascular Genetics. 2010; 3: 499-506

Published online before print October 4, 2010,

doi: 10.1161/ CIRCGENETICS.110.957415

 

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Genetic Determinants of Potassium Sensitivity and Hypertension

 

Integrated Computational and Experimental Analysis of the Neuroendocrine Transcriptome in Genetic Hypertension Identifies Novel Control Points for the Cardiometabolic Syndrome

Ryan S. Friese, PhD, Chun Ye, PhD, Caroline M. Nievergelt, PhD, Andrew J. Schork, BS, Nitish R. Mahapatra, PhD, Fangwen Rao, MD, Philip S. Napolitan, BS, Jill Waalen, MD, MPH, Georg B. Ehret, MD, Patricia B. Munroe, PhD, Geert W. Schmid-Schönbein, PhD, Eleazar Eskin, PhD and Daniel T. O’Connor, MD

Author Affiliations

From the Departments of Bioengineering (R.S.F., G.W.S.-S.), Medicine (R.S.F., A.J.S., F.R., P.S.N., D.T.O.), Pharmacology (D.T.O.), and Psychiatry (C.M.N.), the Bioinformatics Program (C.Y.), and the Institute for Genomic Medicine (D.T.O.), University of California at San Diego; the VA San Diego Healthcare System, San Diego, CA (D.T.O.); the Departments of Computer Science & Human Genetics, University of California at Los Angeles (E.E.); the Department of Biotechnology, Indian Institute of Technology Madras, Chennai, India (N.R.M.); Clinical Pharmacology and The Genome Centre, William Harvey Research Institute, Barts and The London School of Medicine and Dentistry, Queen Mary University of London, London, United Kingdom (P.B.M.); Center for Complex Disease Genomics, McKusick-Nathans Institute of Genetic Medicine, Johns Hopkins University School of Medicine, Baltimore, MD (G.B.E.); and Scripps Research Institute, La Jolla, CA (J.W.).

Correspondence to Daniel T. O’Connor, MD, Department of Medicine, University of California at San Diego School of Medicine, VASDHS (0838), Skaggs (SSPPS) Room 4256, 9500 Gilman Drive, La Jolla, CA 92093-0838. E-mail doconnor@ucsd.edu

Abstract

Background—Essential hypertension, a common complex disease, displays substantial genetic influence. Contemporary methods to dissect the genetic basis of complex diseases such as the genomewide association study are powerful, yet a large gap exists betweens the fraction of population trait variance explained by such associations and total disease heritability.

Methods and Results—We developed a novel, integrative method (combining animal models, transcriptomics, bioinformatics, molecular biology, and trait-extreme phenotypes) to identify candidate genes for essential hypertension and the metabolic syndrome. We first undertook transcriptome profiling on adrenal glands from blood pressure extreme mouse strains: the hypertensive BPH (blood pressure high) and hypotensive BPL (blood pressure low). Microarray data clustering revealed a striking pattern of global underexpression of intermediary metabolism transcripts in BPH. The MITRA algorithm identified a conserved motif in the transcriptional regulatory regions of the underexpressed metabolic genes, and we then hypothesized that regulation through this motif contributed to the global underexpression. Luciferase reporter assays demonstrated transcriptional activity of the motif through transcription factors HOXA3, SRY, and YY1. We finally hypothesized that genetic variation at HOXA3, SRY, and YY1 might predict blood pressure and other metabolic syndrome traits in humans. Tagging variants for each locus were associated with blood pressure in a human population blood pressure extreme sample with the most extensive associations for YY1 tagging single nucleotide polymorphism rs11625658 on systolic blood pressure, diastolic blood pressure, body mass index, and fasting glucose. Meta-analysis extended the YY1 results into 2 additional large population samples with significant effects preserved on diastolic blood pressure, body mass index, and fasting glucose.

Conclusions—The results outline an innovative, systematic approach to the genetic pathogenesis of complex cardiovascular disease traits and point to transcription factor YY1 as a potential candidate gene involved in essential hypertension and the cardiometabolic syndrome.

 SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 430-440

Published online before print June 5, 2012,

doi: 10.1161/ CIRCGENETICS.111.962415

Genome-Wide Linkage and Positional Candidate Gene Study of Blood Pressure Response to Dietary Potassium Intervention

The Genetic Epidemiology Network of Salt Sensitivity Study

Tanika N. Kelly, PhD, James E. Hixson, PhD, Dabeeru C. Rao, PhD, Hao Mei, MD, PhD, Treva K. Rice, PhD, Cashell E. Jaquish, PhD, Lawrence C. Shimmin, PhD, Karen Schwander, MS, Chung-Shuian Chen, MS, Depei Liu, PhD, Jichun Chen, MD, Concetta Bormans, PhD, Pramila Shukla, MS, Naveed Farhana, MS, Colin Stuart, BS, Paul K. Whelton, MD, MSc, Jiang He, MD, PhD and Dongfeng Gu, MD, PhD

Author Affiliations

From the Department of Epidemiology (T.N.K., H.M., C.-S.C., J.H.), Tulane University School of Public Health and Tropical Medicine, and Department of Medicine (J.H.), Tulane University School of Medicine, New Orleans, La; Department of Epidemiology (J.E.H., L.C.S., C.B., P.S., N.F., C.S.), University of Texas School of Public Health, Houston, Tex; Division of Biostatistics (D.C.R., T.K.R., K.S.), Washington University School of Medicine, St Louis, Mo; Division of Prevention and Population Sciences (C.E.J.), National Heart, Lung, Blood Institute, Bethesda, Md; National Laboratory of Medical Molecular Biology (D.L.), Institute of Basic Medical Sciences, Chinese Academy of Medical Sciences and Peking Union Medical College, Beijing, China; Cardiovascular Institute and Fuwai Hospital (J.C., D.G.), Chinese Academy of Medical Sciences and Peking Union Medical College and Chinese National Center for Cardiovascular Disease Control and Research, Beijing, China; and Office of the President (P.K.W.), Loyola University Health System and Medical Center, Maywood, Ill.

Correspondence to Dongfeng Gu, MD, PhD, Division of Population Genetics and Prevention, Cardiovascular Institute and Fuwai Hospital, 167 Beilishi Rd, Beijing 100037, China. E-mail gudongfeng@vip.sina.com

Abstract

Background— Genetic determinants of blood pressure (BP) response to potassium, or potassium sensitivity, are largely unknown. We conducted a genome-wide linkage scan and positional candidate gene analysis to identify genetic determinants of potassium sensitivity.

Conclusions— Genetic regions on chromosomes 3 and 11 may harbor important susceptibility loci for potassium sensitivity. Furthermore, the AGTR1 gene was a significant predictor of BP responses to potassium intake.

SOURCE:

Circulation: Cardiovascular Genetics. 2010; 3: 539-547

Published online before print September 22, 2010,

doi: 10.1161/ CIRCGENETICS.110.940635

 

Genome-Wide Association Study of Cardiac Structure and Systolic Function in African Americans

The Candidate Gene Association Resource (CARe) Study

Ervin R. Fox, MD*, Solomon K. Musani, PhD*, Maja Barbalic, PhD*, Honghuang Lin, PhD, Bing Yu, MS, Kofo O. Ogunyankin, MD, Nicholas L. Smith, PhD, Abdullah Kutlar, MD, Nicole L. Glazer, MD, Wendy S. Post, MD, MS, Dina N. Paltoo, PhD, MPH, Daniel L. Dries, MD, MPH, Deborah N. Farlow, PhD, Christine W. Duarte, PhD, Sharon L. Kardia, PhD, Kristin J. Meyers, PhD, Yan V. Sun, PhD, Donna K. Arnett, PhD, Amit A. Patki, MS, Jin Sha, MS, Xiangqui Cui, PhD, Tandaw E. Samdarshi, MD, MPH, Alan D. Penman, PhD, Kirsten Bibbins-Domingo, MD, PhD, Petra Bůžková, PhD, Emelia J. Benjamin, MD, David A. Bluemke, MD, PhD, Alanna C. Morrison, PhD, Gerardo Heiss, MD, J. Jeffrey Carr, MD, MSc, Russell P. Tracy, PhD, Thomas H. Mosley, PhD, Herman A. Taylor, MD, Bruce M. Psaty, MD, PhD, Susan R. Heckbert, MD, PhD, Thomas P. Cappola, MD, ScM and Ramachandran S. Vasan, MD

Author Affiliations

Guest Editor for this article was Barry London, MD, PhD.

Correspondence to Ervin Fox, MD MPH, FAHA, FACC, Professor of Medicine, Department of Medicine, University of Mississippi Medical Center, 2500 North State St, Jackson, MS 39216. E-mail efox@medicine.umsmed.edu

* These authors contributed equally as joint first authors.

Abstract

Background—Using data from 4 community-based cohorts of African Americans, we tested the association between genome-wide markers (single-nucleotide polymorphisms) and cardiac phenotypes in the Candidate-gene Association Resource study.

Methods and Results—Among 6765 African Americans, we related age, sex, height, and weight-adjusted residuals for 9 cardiac phenotypes (assessed by echocardiogram or magnetic resonance imaging) to 2.5 million single-nucleotide polymorphisms genotyped using Genome-wide Affymetrix Human SNP Array 6.0 (Affy6.0) and the remainder imputed. Within the cohort, genome-wide association analysis was conducted, followed by meta-analysis across cohorts using inverse variance weights (genome-wide significance threshold=4.0 ×107). Supplementary pathway analysis was performed. We attempted replication in 3 smaller cohorts of African ancestry and tested lookups in 1 consortium of European ancestry (EchoGEN). Across the 9 phenotypes, variants in 4 genetic loci reached genome-wide significance: rs4552931 in UBE2V2 (P=1.43×107) for left ventricular mass, rs7213314 in WIPI1 (P=1.68×107) for left ventricular internal diastolic diameter, rs1571099 in PPAPDC1A (P=2.57×108) for interventricular septal wall thickness, and rs9530176 in KLF5 (P=4.02×107) for ejection fraction. Associated variants were enriched in 3 signaling pathways involved in cardiac remodeling. None of the 4 loci replicated in cohorts of African ancestry was confirmed in lookups in EchoGEN.

Conclusions—In the largest genome-wide association study of cardiac structure and function to date in African Americans, we identified 4 genetic loci related to left ventricular mass, interventricular septal wall thickness, left ventricular internal diastolic diameter, and ejection fraction, which reached genome-wide significance. Replication results suggest that these loci may be unique to individuals of African ancestry. Additional large-scale studies are warranted for these complex phenotypes.

SOURCE:

Circulation: Cardiovascular Genetics. 2013; 6: 37-46

Published online before print December 28, 2012,

doi: 10.1161/ CIRCGENETICS.111.962365

 

Heart and Aging Research in Genomic Epidemiology: 1700 MIs and 2300 coronary heart disease events among about 29 000 eligible patients

 

Cohorts for Heart and Aging Research in Genomic Epidemiology (CHARGE) Consortium

Design of Prospective Meta-Analyses of Genome-Wide Association Studies From 5 Cohorts

Bruce M. Psaty, MD, PhD, Christopher J. O’Donnell, MD, MPH, Vilmundur Gudnason, MD, PhD, Kathryn L. Lunetta, PhD, Aaron R. Folsom, MD, Jerome I. Rotter, MD, André G. Uitterlinden, PhD, Tamara B. Harris, MD, Jacqueline C.M. Witteman, PhD, Eric Boerwinkle, PhD and on Behalf of the CHARGE Consortium

Author Affiliations

From the Cardiovascular Health Research Unit, Departments of Medicine, Epidemiology, and Health Services (B.M.P.), University of Wash; Center for Health Studies, Group Health (B.M.P.), Seattle, Wash; the National Heart, Lung and Blood Institute and the Framingham Heart Study (C.J.O.D.), Framingham, Mass; Icelandic Heart Association and the Department of Cardiovascular Genetics (Y.G.), University of Iceland, Reykjavik, Iceland; Department of Biostatistics (K.L.), Boston University School of Public Health, Mass; Division of Epidemiology and Community Health (A.R.F.), University of Minnesota, Minneapolis; Medical Genetics Institute (J.I.R.), Cedars-Sinai Medical Center, Los Angeles, Calif; Departments of Internal Medicine (A.G.U.) and Epidemiology (A.G.U., J.C.M.W.), Erasmus Medical Center, Rotterdam, The Netherlands; Laboratory of Epidemiology, Demography, and Biometry (T.B.H.), Intramural Research Program, National Institute on Aging, Bethesda, Md; and Human Genetics Center and Division of Epidemiology (E.B.), University of Texas, Houston.

Guest editor for this article was Elizabeth R. Hauser, PhD.

Abstract

Background— The primary aim of genome-wide association studies is to identify novel genetic loci associated with interindividual variation in the levels of risk factors, the degree of subclinical disease, or the risk of clinical disease. The requirement for large sample sizes and the importance of replication have served as powerful incentives for scientific collaboration.

Methods— The Cohorts for Heart and Aging Research in Genomic Epidemiology Consortium was formed to facilitate genome-wide association studies meta-analyses and replication opportunities among multiple large population-based cohort studies, which collect data in a standardized fashion and represent the preferred method for estimating disease incidence. The design of the Cohorts for Heart and Aging Research in Genomic Epidemiology Consortium includes 5 prospective cohort studies from the United States and Europe: the Age, Gene/Environment Susceptibility—Reykjavik Study, the Atherosclerosis Risk in Communities Study, the Cardiovascular Health Study, the Framingham Heart Study, and the Rotterdam Study. With genome-wide data on a total of about 38 000 individuals, these cohort studies have a large number of health-related phenotypes measured in similar ways. For each harmonized trait, within-cohort genome-wide association study analyses are combined by meta-analysis. A prospective meta-analysis of data from all 5 cohorts, with a properly selected level of genome-wide statistical significance, is a powerful approach to finding genuine phenotypic associations with novel genetic loci.

Conclusions— The Cohorts for Heart and Aging Research in Genomic Epidemiology Consortium and collaborating non-member studies or consortia provide an excellent framework for the identification of the genetic determinants of risk factors, subclinical-disease measures, and clinical events.

Example of Coronary Heart Disease

The cohort-study methods papers provide detail about many of the phenotypes listed in Table 2. For coronary heart disease, investigators knowledgeable about the phenotype in each study decided to focus on fatal and nonfatal myocardial infarction (MI) as the primary outcome because the MI criteria differed in only trivial ways among the studies. There were some minor differences in the definition of the composite outcome of MI, fatal coronary heart disease, and sudden death, which became the secondary outcome. Only subjects at risk for an incident event were included in the analysis. MI survivors whose DNA was drawn after the event were not eligible. The primary analysis was restricted to Europeans or European Americans. Patients entered the analysis at the time of the DNA blood draw, and were followed until an event, death, loss to follow up, or the last visit. The main recommendations of the Analysis Committee were adopted, and a threshold of 5×108 was selected for genome-wide statistical significance. Analyses in progress include about 1700 MIs and 2300 coronary heart disease events among about 29 000 eligible patients. Each cohort conducted its own analysis, and results were uploaded to a secure share site for the fixed-effects meta-analysis. Even with this number of events (Supplemental Figure 2), power is good for only for relatively high minor allele frequencies (>0.25) and large relative risks (>1.3).

The authors had full access to and take full responsibility for the integrity of the data. All authors have read and agree to the manuscript as written.

Discussion

In thousands of published papers, the 5 CHARGE cohort studies and many of the collaborating studies have already characterized the risk factors for and the incidence and prognosis of a variety of aging-related and cardiovascular conditions. The analysis of the incident MI, for instance, is free from the survival bias typically associated with cross-sectional or case-control studies. The methodologic advantages of the prospective population-based cohort design, the similarity of phenotypes across 5 studies, the availability of genome-wide genotyping data in each cohort, and the need for large sample sizes to provide reliable estimates of genotype-phenotype associations have served as the primary incentives for the formation of the CHARGE consortium, which includes GWAS data on about 38 000 individuals. The consortium effort relies on collaborative methods that are similar to those used by the individual contributing cohorts.

Phenotype experts who know the studies and the data well are responsible for phenotype-standardization across cohorts. The coordinated prospectively planned meta-analyses of CHARGE provide results that are virtually identical to a cohort-adjusted pooled analysis of individual level data. This approach–the within-study analysis followed by a between-study meta-analysis–avoids the human subjects issues associated with individual-level data sharing.

Editors, reviewers, and readers expect replication as the standard in science.6 The finding of a genetic association in one population with evidence for replication in multiple independent populations provides moderate assurance against false-positive reports and helps to establish the validity of the original finding. In a single experiment, the discovery-replication structure is traditionally embodied in a 2-stage design. The CHARGE consortium includes up to 5 independent replicate samples as well as additional collaborating studies for some phenotype working groups, so that it would have been possible to set up analysis plans within CHARGE to mimic the traditional 2-stage design for replication. For instance, the 2 largest cohorts could have served as the discovery set and the others as the replication set. However, attaining the extremely small probability values expected in GWAS requires large sample sizes. For any phenotype, a prospective meta-analysis of all participating cohorts, with a properly selected level of genome-wide statistical significance to minimize the chance of false-positives, is the most powerful approach to finding new genuine associations for genetic loci.25 When findings narrowly miss the prespecified significance threshold, genotyping individuals in other independent populations provides additional evidence about the association. For findings that substantially exceed pre-established significance thresholds, the results of a CHARGE meta-analysis effectively provide evidence of a multistudy replication.

The effort to assemble and manage the CHARGE consortium has provided some interesting and unanticipated challenges. Participating cohorts often had relationships with outside study groups that predated the formation of CHARGE. Timelines for genotyping and imputation have shifted. Purchases of new computer systems for the volume of work were sometimes necessary. Each cohort came to the consortium with their own traditions for methods of analysis, organization, and authorship policies that, while appropriate for their own work, were not always optimal for collaboration with multiple external groups. Within each cohort, the investigators had often formed working groups that divided up the large number of available phenotypes in ways that made sense locally but did not necessarily match the configuration that had been adopted by other cohorts. The Research Steering Committee has attempted to create a set of CHARGE working groups that accommodate the needs and the conventions of the various cohorts. Transparency, disclosure, and professional collaborative behavior by all participating investigators have been essential to the process.

Resource limitations are another challenge. Grant applications that funded the original single-study genome-wide genotyping effort typically imagined a much simpler design. The CHS whole-genome study had as its primary aim, for instance, the analysis of data on 3 endpoints, coronary disease, stroke and heart failure. With a score of active phenotype working groups, the CHARGE collaboration broadened the scope of the short-term work well beyond initial expectations for all the participating cohorts.

One of the premier challenges has been communications among scores of investigators at a dozen sites. CHS and ARIC are themselves multi-site studies. To be successful, the CHARGE collaboration has required effective communications: (1) within each cohort; (2) between cohorts; (3) within the CHARGE working groups; and (4) among the major CHARGE committees. In addition to the traditional methods of conference calls and email, the CHARGE “wiki,” set up by Dr J. Bis (Seattle, Wash), has provided a crucial and highly functional user-driven website for calendars, minutes, guidelines, working group analysis plans, manuscript proposals, and other documents. In the end, there is no substitute for face-to-face meetings, especially at the beginning of the collaboration, and this complex meta-organization has benefited from several CHARGE-wide meetings.

The major emerging opportunity is the collaboration with other studies and consortia. Many working groups have already incorporated nonmember studies into their efforts. Several working groups have coordinated submissions of initial manuscripts with the parallel submission of manuscripts from other studies or consortia. Several working groups have embarked on plans for joint meta-analyses between CHARGE and other consortia. CHARGE has tried to acknowledge and reward the efforts of champions, who assume leadership responsibility for moving these large complex projects forward and who are often hard-working young investigators, the key to the future success of population science.

The CHARGE Consortium represents an innovative model of collaborative research conducted by research teams that know well the strengths, the limitations, and the data from 5 prospective population-based cohort studies. By leveraging the dense genotyping, deep phenotyping and the diverse expertise, prospective meta-analyses are underway to identify and replicate the major common genetic determinants of risk factors, measures of subclinical disease, and clinical events for cardiovascular disease and aging.

SOURCE:

Circulation: Cardiovascular Genetics.2009; 2: 73-80

doi: 10.1161/ CIRCGENETICS.108.829747

 

 

Genomics of Ventricular arrhythmias, A-Fib, Right Ventricular Dysplasia, Cardiomyopathy

 

Comprehensive Desmosome Mutation Analysis in North Americans With Arrhythmogenic Right Ventricular Dysplasia/Cardiomyopathy

A. Dénise den Haan, MD, Boon Yew Tan, MBChB, Michelle N. Zikusoka, MD, Laura Ibañez Lladó, MS, Rahul Jain, MD, Amy Daly, MS, Crystal Tichnell, MGC, Cynthia James, PhD, Nuria Amat-Alarcon, MS, Theodore Abraham, MD, Stuart D. Russell, MD, David A. Bluemke, MD, PhD, Hugh Calkins, MD, Darshan Dalal, MD, PhD and Daniel P. Judge, MD

Author Affiliations

From the Department of Medicine/Cardiology (A.D.d.H., B.Y.T., M.N.Z., L.I.L., R.J., A.D., C.T., C.J., N.A.-A., T.A., S.D.R., H.C., D.D., D.P.J.), Johns Hopkins University School of Medicine, Baltimore, Md; Department of Cardiology, Division of Heart and Lungs (A.D.d.H.), University Medical Center Utrecht, Utrecht, The Netherlands; and National Institutes of Health, Radiology and Imaging Sciences (D.A.B.), Bethesda, Md.

Correspondence to Daniel P. Judge, MD, Johns Hopkins University, Division of Cardiology, Ross 1049; 720 Rutland Avenue, Baltimore, MD 21205. E-mail djudge@jhmi.edu

Abstract

Background— Arrhythmogenic right ventricular dysplasia/cardiomyopathy (ARVD/C) is an inherited disorder typically caused by mutations in components of the cardiac desmosome. The prevalence and significance of desmosome mutations among patients with ARVD/C in North America have not been described previously. We report comprehensive desmosome genetic analysis for 100 North Americans with clinically confirmed or suspected ARVD/C.

Methods and Results— In 82 individuals with ARVD/C and 18 people with suspected ARVD/C, DNA sequence analysis was performed on PKP2, DSG2, DSP, DSC2, and JUP. In those with ARVD/C, 52% harbored a desmosome mutation. A majority of these mutations occurred in PKP2. Notably, 3 of the individuals studied have a mutation in more than 1 gene. Patients with a desmosome mutation were more likely to have experienced ventricular tachycardia (73% versus 44%), and they presented at a younger age (33 versus 41 years) compared with those without a desmosome mutation. Men with ARVD/C were more likely than women to carry a desmosome mutation (63% versus 38%). A mutation was identified in 5 of 18 patients (28%) with suspected ARVD. In this smaller subgroup, there were no significant phenotypic differences identified between individuals with a desmosome mutation compared with those without a mutation.

Conclusions— Our study shows that in 52% of North Americans with ARVD/C a mutation in one of the cardiac desmosome genes can be identified. Compared with those without a desmosome gene mutation, individuals with a desmosome gene mutation had earlier-onset ARVD/C and were more likely to have ventricular tachycardia.

SOURCE:

Circulation: Cardiovascular Genetics.2009; 2: 428-435

Published online before print June 3, 2009,

doi: 10.1161/ CIRCGENETICS.109.858217

 

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Large-Scale Candidate Gene Analysis in Whites and African Americans Identifies IL6R Polymorphism in Relation to Atrial Fibrillation

The National Heart, Lung, and Blood Institute’s Candidate Gene Association Resource (CARe) Project

Renate B. Schnabel, MD, MSc*, Kathleen F. Kerr, PhD*, Steven A. Lubitz, MD*, Ermeg L. Alkylbekova, MD*, Gregory M. Marcus, MD, MAS, Moritz F. Sinner, MD, Jared W. Magnani, MD, Philip A. Wolf, MD, Rajat Deo, MD, Donald M. Lloyd-Jones, MD, ScM, Kathryn L. Lunetta, PhD, Reena Mehra, MD, MS, Daniel Levy, MD, Ervin R. Fox, MD, MPH, Dan E. Arking, PhD, Thomas H. Mosley, PhD, Martina Müller-Nurasyid, MSc, PhD, Taylor R. Young, MA, H.-Erich Wichmann, MD, PhD, Sudha Seshadri, MD, Deborah N. Farlow, PhD, Jerome I. Rotter, MD, Elsayed Z. Soliman, MD, MSc, MS, Nicole L. Glazer, PhD, James G. Wilson, MD, Monique M.B. Breteler, MD, Nona Sotoodehnia, MD, MPH, Christopher Newton-Cheh, MD, MPH, Stefan Kääb, MD, PhD, Patrick T. Ellinor, MD, PhD*, Alvaro Alonso, MD*, Emelia J. Benjamin, MD, ScM*, Susan R. Heckbert, MD, PhD* and for the Candidate Gene Association Resource (CARe) Atrial Fibrillation/Electrocardiography Working Group

Correspondence to Susan R. Heckbert, MD, PhD, Cardiovascular Health Research Unit, University of Washington, 1730 Minor Ave, Suite 1360, Seattle, WA 98101. E-mail heckbert@u.washington.edu; Emelia J. Benjamin, MD, ScM, Medicine and Epidemiology, Boston University Schools of Medicine and Public Health, The Framingham Heart Study, 73 Mount Wayte Ave, Framingham, MA 01702–5827. E-mail emelia@bu.edu; Renate B. Schnabel, MD, MSc, Department of Medicine 2, Cardiology, Johannes Gutenberg University, Langenbeckstr 1, 55131 Mainz, Germany. E-mail schnabelr@gmx.de

* These authors contributed equally to the manuscript.

Abstract

Background—The genetic background of atrial fibrillation (AF) in whites and African Americans is largely unknown. Genes in cardiovascular pathways have not been systematically investigated.

Methods and Results—We examined a panel of approximately 50 000 common single-nucleotide polymorphisms (SNPs) in 2095 cardiovascular candidate genes and AF in 3 cohorts with participants of European (n=18 524; 2260 cases) or African American descent (n=3662; 263 cases) in the National Heart, Lung, and Blood Institute’s Candidate Gene Association Resource. Results in whites were followed up in the German Competence Network for AF (n=906, 468 cases). The top result was assessed in relation to incident ischemic stroke in the Cohorts for Heart and Aging Research in Genomic Epidemiology Stroke Consortium (n=19 602 whites, 1544 incident strokes). SNP rs4845625 in the IL6R gene was associated with AF (relative risk [RR] C allele, 0.90; 95% confidence interval [CI], 0.85–0.95; P=0.0005) in whites but did not reach statistical significance in African Americans (RR, 0.86; 95% CI, 0.72–1.03; P=0.09). The results were comparable in the German AF Network replication, (RR, 0.71; 95% CI, 0.57–0.89; P=0.003). No association between rs4845625 and stroke was observed in whites. The known chromosome 4 locus near PITX2 in whites also was associated with AF in African Americans (rs4611994; hazard ratio, 1.40; 95% CI, 1.16–1.69; P=0.0005).

Conclusions—In a community-based cohort meta-analysis, we identified genetic association in IL6R with AF in whites. Additionally, we demonstrated that the chromosome 4 locus known from recent genome-wide association studies in whites is associated with AF in African Americans.

 SOURCE:

Circulation: Cardiovascular Genetics.2011; 4: 557-564

Published online before print August 16, 2011,

doi: 10.1161/ CIRCGENETICS.110.959197

PITX2c Is Expressed in the Adult Left Atrium, and Reducing Pitx2c Expression Promotes Atrial Fibrillation Inducibility and Complex Changes in Gene Expression

Paulus Kirchhof, MD*, Peter C. Kahr*, Sven Kaese, Ilaria Piccini, PhD, Ismail Vokshi, BSc, Hans-Heinrich Scheld, MD, Heinrich Rotering, MD, Lisa Fortmueller, MD (vet), Sandra Laakmann, MD (vet), Sander Verheule, PhD, Ulrich Schotten, MD, PhD, Larissa Fabritz, MD and Nigel A. Brown, PhD

Author Affiliations

From the Department of Cardiology and Angiology (P.K., P.C.K., S.K., I.P., L.F., S.L., L.F.) and the Department of Thoracic and Cardiovascular Surgery (H.-H.S., H.R.), University Hospital Muenster, Germany; Division of Biomedical Sciences (P.C.K., I.V., N.A.B.), St. George’s, University of London, United Kingdom; and the Department of Physiology (S.V., U.S.), Maastricht University, The Netherlands.

Correspondence to Nigel A. Brown, PhD, Division of Biomedical Sciences, St George’s, University of London, Cranmer Terrace, London, SW17 0RE, UK. E-mail nbrown@sgul.ac.uk

* Drs Kirchhof and Kahr contributed equally to this work.

Abstract

Background— Intergenic variations on chromosome 4q25, close to the PITX2 transcription factor gene, are associated with atrial fibrillation (AF). We therefore tested whether adult hearts express PITX2 and whether variation in expression affects cardiac function.

Methods and Results— mRNA for PITX2 isoform c was expressed in left atria of human and mouse, with levels in right atrium and left and right ventricles being 100-fold lower. In mice heterozygous for Pitx2c (Pitx2c+/), left atrial Pitx2c expression was 60% of wild-type and cardiac morphology and function were not altered, except for slightly elevated pulmonary flow velocity. Isolated Pitx2c+/ hearts were susceptible to AF during programmed stimulation. At short paced cycle lengths, atrial action potential durations were shorter in Pitx2c+/ than in wild-type. Perfusion with the β-receptor agonist orciprenaline abolished inducibility of AF and reduced the effect on action potential duration. Spontaneous heart rates, atrial conduction velocities, and activation patterns were not affected in Pitx2c+/ hearts, suggesting that action potential duration shortening caused wave length reduction and inducibility of AF. Expression array analyses comparing Pitx2c+/ with wild-type, for left atrial and right atrial tissue separately, identified genes related to calcium ion binding, gap and tight junctions, ion channels, and melanogenesis as being affected by the reduced expression of Pitx2c.

Conclusions— These findings demonstrate a physiological role for PITX2 in the adult heart and support the hypothesis that dysregulation of PITX2 expression can be responsible for susceptibility to AF.

 SOURCE:

Circulation: Cardiovascular Genetics.2011; 4: 123-133

Published online before print January 31, 2011,

doi: 10.1161/ CIRCGENETICS.110.958058

 

Genetics of CVD and Hyperlipidemia, Hyper Cholesterolemia, Metabolic Syndrome

 

Genetic Loci Associated With Plasma Concentration of Low-Density Lipoprotein Cholesterol, High-Density Lipoprotein Cholesterol, Triglycerides, Apolipoprotein A1, and Apolipoprotein B Among 6382 White Women in Genome-Wide Analysis With Replication

Daniel I. Chasman, PhD*, Guillaume Paré, MD, MS*, Robert Y.L. Zee, PhD, MPH, Alex N. Parker, PhD, Nancy R. Cook, ScD, Julie E. Buring, ScD, David J. Kwiatkowski, MD, PhD, Lynda M. Rose, MS, Joshua D. Smith, BS, Paul T. Williams, PhD, Mark J. Rieder, PhD, Jerome I. Rotter, MD, Deborah A. Nickerson, PhD, Ronald M. Krauss, MD, Joseph P. Miletich, MD and Paul M Ridker, MD, MPH

Author Affiliations

From the Center for Cardiovascular Disease Prevention (D.I.C., G.P., R.Y.L.Z., N.R.C., J.E.B., L.M.R., P.M.R.) and Donald W. Reynolds Center for Cardiovascular Research (D.I.C., G.P., R.Y.L.Z., N.R.C., D.J.K., P.M.R.), Brigham and Women’s Hospital, Harvard Medical School, Boston, Mass; Amgen, Inc, Cambridge, Mass (A.N.P., J.M.P.); Department of Genome Sciences, University of Washington, Seattle, Wash (J.D.S., M.J.R., D.A.N.); Life Science Division, Lawrence Berkeley National Laboratory, Berkeley, Calif (P.T.W., R.M.K.); Medical Genetics Institute, Cedars-Sinai Medical Center, Los Angeles, Calif (J.I.R.); and Children’s Hospital Oakland Research Institute, Oakland, Calif (R.M.K.).

Correspondence to Daniel I. Chasman, Center for Cardiovascular Disease Prevention, Brigham and Women’s Hospital, 900 Commonwealth Ave E, Boston, MA 02215. E-mail dchasman@rics.bwh.harvard.edu

Abstract

Background— Genome-wide genetic association analysis represents an opportunity for a comprehensive survey of the genes governing lipid metabolism, potentially revealing new insights or even therapeutic strategies for cardiovascular disease and related metabolic disorders.

Methods and Results— We have performed large-scale, genome-wide genetic analysis among 6382 white women with replication in 2 cohorts of 970 additional white men and women for associations between common single-nucleotide polymorphisms and low-density lipoprotein cholesterol, high-density lipoprotein cholesterol, triglycerides, apolipoprotein (Apo) A1, and ApoB. Genome-wide associations (P<5×108) were found at the PCSK9 gene, the APOB gene, the LPL gene, the APOA1-APOA5 locus, the LIPC gene, the CETP gene, the LDLR gene, and the APOE locus. In addition, genome-wide associations with triglycerides at the GCKR gene confirm and extend emerging links between glucose and lipid metabolism. Still other genome-wide associations at the 1p13.3 locus are consistent with emerging biological properties for a region of the genome, possibly related to the SORT1 gene. Below genome-wide significance, our study provides confirmatory evidence for associations at 5 novel loci with low-density lipoprotein cholesterol, high-density lipoprotein cholesterol, or triglycerides reported recently in separate genome-wide association studies. The total proportion of variance explained by common variation at the genome-wide candidate loci ranges from 4.3% for triglycerides to 12.6% for ApoB.

Conclusion— Genome-wide associations at the GCKR gene and near the SORT1 gene, as well as confirmatory associations at 5 additional novel loci, suggest emerging biological pathways for lipid metabolism among white women.

 SOURCE:

Circulation: Cardiovascular Genetics.2008; 1: 21-30

doi: 10.1161/ CIRCGENETICS.108.773168

 

 

Integrated Computational and Experimental Analysis of the Neuroendocrine Transcriptome in Genetic Hypertension Identifies Novel Control Points for the Cardiometabolic Syndrome

Ryan S. Friese, PhD, Chun Ye, PhD, Caroline M. Nievergelt, PhD, Andrew J. Schork, BS, Nitish R. Mahapatra, PhD, Fangwen Rao, MD, Philip S. Napolitan, BS, Jill Waalen, MD, MPH, Georg B. Ehret, MD, Patricia B. Munroe, PhD, Geert W. Schmid-Schönbein, PhD, Eleazar Eskin, PhD and Daniel T. O’Connor, MD

Author Affiliations

From the Departments of Bioengineering (R.S.F., G.W.S.-S.), Medicine (R.S.F., A.J.S., F.R., P.S.N., D.T.O.), Pharmacology (D.T.O.), and Psychiatry (C.M.N.), the Bioinformatics Program (C.Y.), and the Institute for Genomic Medicine (D.T.O.), University of California at San Diego; the VA San Diego Healthcare System, San Diego, CA (D.T.O.); the Departments of Computer Science & Human Genetics, University of California at Los Angeles (E.E.); the Department of Biotechnology, Indian Institute of Technology Madras, Chennai, India (N.R.M.); Clinical Pharmacology and The Genome Centre, William Harvey Research Institute, Barts and The London School of Medicine and Dentistry, Queen Mary University of London, London, United Kingdom (P.B.M.); Center for Complex Disease Genomics, McKusick-Nathans Institute of Genetic Medicine, Johns Hopkins University School of Medicine, Baltimore, MD (G.B.E.); and Scripps Research Institute, La Jolla, CA (J.W.).

Correspondence to Daniel T. O’Connor, MD, Department of Medicine, University of California at San Diego School of Medicine, VASDHS (0838), Skaggs (SSPPS) Room 4256, 9500 Gilman Drive, La Jolla, CA 92093-0838. E-mail doconnor@ucsd.edu

Abstract

Background—Essential hypertension, a common complex disease, displays substantial genetic influence. Contemporary methods to dissect the genetic basis of complex diseases such as the genomewide association study are powerful, yet a large gap exists betweens the fraction of population trait variance explained by such associations and total disease heritability.

Methods and Results—We developed a novel, integrative method (combining animal models, transcriptomics, bioinformatics, molecular biology, and trait-extreme phenotypes) to identify candidate genes for essential hypertension and the metabolic syndrome. We first undertook transcriptome profiling on adrenal glands from blood pressure extreme mouse strains: the hypertensive BPH (blood pressure high) and hypotensive BPL (blood pressure low). Microarray data clustering revealed a striking pattern of global underexpression of intermediary metabolism transcripts in BPH. The MITRA algorithm identified a conserved motif in the transcriptional regulatory regions of the underexpressed metabolic genes, and we then hypothesized that regulation through this motif contributed to the global underexpression. Luciferase reporter assays demonstrated transcriptional activity of the motif through transcription factors HOXA3, SRY, and YY1. We finally hypothesized that genetic variation at HOXA3, SRY, and YY1 might predict blood pressure and other metabolic syndrome traits in humans. Tagging variants for each locus were associated with blood pressure in a human population blood pressure extreme sample with the most extensive associations for YY1 tagging single nucleotide polymorphism rs11625658 on systolic blood pressure, diastolic blood pressure, body mass index, and fasting glucose. Meta-analysis extended the YY1 results into 2 additional large population samples with significant effects preserved on diastolic blood pressure, body mass index, and fasting glucose.

Conclusions—The results outline an innovative, systematic approach to the genetic pathogenesis of complex cardiovascular disease traits and point to transcription factor YY1 as a potential candidate gene involved in essential hypertension and the cardiometabolic syndrome.

 SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 430-440

Published online before print June 5, 2012,

doi: 10.1161/ CIRCGENETICS.111.962415

 

Associations Between Incident Ischemic Stroke Events and Stroke and Cardiovascular Disease-Related Genome-Wide Association Studies Single Nucleotide Polymorphisms in the Population Architecture Using Genomics and Epidemiology Study

Cara L. Carty, PhD, Petra Bůžková, PhD, Myriam Fornage, PhD, Nora Franceschini, MD, Shelley Cole, PhD, Gerardo Heiss, MD, PhD, Lucia A. Hindorff, PhD, MPH, Barbara V. Howard, PhD, Sue Mann, MPH, Lisa W. Martin, MD, Ying Zhang, PhD, Tara C. Matise, PhD, Ross Prentice, PhD, Alexander P. Reiner, MD, MS and Charles Kooperberg, PhD

Author Affiliations

From the Public Health Sciences, Fred Hutchinson Cancer Research Center (C.L.C., S.M., R.P., C.K.); Department of Biostatistics, University of Washington, Seattle, WA (P.B.); Institute of Molecular Medicine, University of Texas Health Sciences Center at Houston, Houston, TX (M.F.); Division of Epidemiology, School of Public Health, University of Texas Health Sciences Center, Houston, TX (M.F.); Department of Epidemiology, University of North Carolina, Chapel Hill, NC (N.F., G.H.); Department of Genetics, Texas Biomedical Research Institute, San Antonio, TX (S.C.); Office of Population Genomics, National Human Genome Research Institute, Bethesda, MD (L.A.H.); Medstar Health Research Institute, Washington, DC (B.V.H.); George Washington University School of Medicine, Washington, DC (B.V.H., L.W.M.); University of Oklahoma Health Sciences Center, Oklahoma City, OK (Y.Z.); Department of Genetics, Rutgers University, Piscataway, NJ (T.C.M.); Department of Epidemiology, University of Washington, Seattle, WA (A.P.R.).

Correspondence to Dr Cara L. Carty, Fred Hutchinson Cancer Research Center, 1100 Fairview Ave N./M3-A410, Seattle, WA 98109. E-mail ccarty@fhcrc.org

Abstract

Background—Genome-wide association studies (GWAS) have identified loci associated with ischemic stroke (IS) and cardiovascular disease (CVD) in European-descent individuals, but their replication in different populations has been largely unexplored.

Methods and Results—Nine single nucleotide polymorphisms (SNPs) selected from GWAS and meta-analyses of stroke, and 86 SNPs previously associated with myocardial infarction and CVD risk factors, including blood lipids (high density lipoprotein [HDL], low density lipoprotein [LDL], and triglycerides), type 2 diabetes, and body mass index (BMI), were investigated for associations with incident IS in European Americans (EA) N=26 276, African-Americans (AA) N=8970, and American Indians (AI) N=3570 from the Population Architecture using Genomics and Epidemiology Study. Ancestry-specific fixed effects meta-analysis with inverse variance weighting was used to combine study-specific log hazard ratios from Cox proportional hazards models. Two of 9 stroke SNPs (rs783396 and rs1804689) were associated with increased IS hazard in AA; none were significant in this large EA cohort. Of 73 CVD risk factor SNPs tested in EA, 2 (HDL and triglycerides SNPs) were associated with IS. In AA, SNPs associated with LDL, HDL, and BMI were significantly associated with IS (3 of 86 SNPs tested). Out of 58 SNPs tested in AI, 1 LDL SNP was significantly associated with IS.

Conclusions—Our analyses showing lack of replication in spite of reasonable power for many stroke SNPs and differing results by ancestry highlight the need to follow up on GWAS findings and conduct genetic association studies in diverse populations. We found modest IS associations with BMI and lipids SNPs, though these findings require confirmation.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 210-216

Published online before print March 8, 2012,

doi: 10.1161/ CIRCGENETICS.111.962191

 

Common Variation in Fatty Acid Genes and Resuscitation From Sudden Cardiac Arrest

Catherine O. Johnson, PhD, MPH, Rozenn N. Lemaitre, PhD, MPH, Carol E. Fahrenbruch, MSPH, Stephanie Hesselson, PhD, Nona Sotoodehnia, MD, MPH, Barbara McKnight, PhD, Kenneth M. Rice, PhD, Pui-Yan Kwok, MD, PhD, David S. Siscovick, MD, MPH and Thomas D. Rea, MD, MPH

Author Affiliations

From the Departments of Medicine (C.O.J., R.N.L., N.S., D.S.S., T.D.R.), Biostatistics (B.M., K.M.R.), and Epidemiology (D.S.S), University of Washington, Seattle; King County Emergency Medical Services, Seattle, WA (C.E.F.); and Institute of Human Genetics, University of California San Francisco (S.H., P.-Y.K.).

Correspondence to Catherine O. Johnson, PhD, MPH, Department of Medicine, University of Washington, CHRU 1730 Minor Ave, Suite 1360, Seattle, WA 98101. E-mail johnsoco@uw.edu

Abstract

Background—Fatty acids provide energy and structural substrates for the heart and brain and may influence resuscitation from sudden cardiac arrest (SCA). We investigated whether genetic variation in fatty acid metabolism pathways was associated with SCA survival.

Methods and Results—Subjects (mean age, 67 years; 80% male, white) were out-of-hospital SCA patients found in ventricular fibrillation in King County, WA. We compared subjects who survived to hospital admission (n=664) with those who did not (n=689), and subjects who survived to hospital discharge (n=334) with those who did not (n=1019). Associations between survival and genetic variants were assessed using logistic regression adjusting for age, sex, location, time to arrival of paramedics, whether the event was witnessed, and receipt of bystander cardiopulmonary resuscitation. Within-gene permutation tests were used to correct for multiple comparisons. Variants in 5 genes were significantly associated with SCA survival. After correction for multiple comparisons, single-nucleotide polymorphisms in ACSL1 and ACSL3 were significantly associated with survival to hospital admission. Single-nucleotide polymorphisms in ACSL3, AGPAT3, MLYCD, and SLC27A6 were significantly associated with survival to hospital discharge.

Conclusions—Our findings indicate that variants in genes important in fatty acid metabolism are associated with SCA survival in this population.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 422-429

Published online before print June 1, 2012,

doi: 10.1161/ CIRCGENETICS.111.961912

 

Genome-Wide Association Study Pinpoints a New Functional Apolipoprotein B Variant Influencing Oxidized Low-Density Lipoprotein Levels But Not Cardiovascular Events

AtheroRemo Consortium

Kari-Matti Mäkelä, BM, BSc, Ilkka Seppälä, MSc, Jussi A. Hernesniemi, MD, PhD, Leo-Pekka Lyytikäinen, MD, Niku Oksala, MD, PhD, DSc, Marcus E. Kleber, PhD, Hubert Scharnagl, PhD, Tanja B. Grammer, MD, Jens Baumert, PhD, Barbara Thorand, PhD, Antti Jula, MD, PhD, Nina Hutri-Kähönen, MD, PhD, Markus Juonala, MD, PhD, Tomi Laitinen, MD, PhD, Reijo Laaksonen, MD, PhD, Pekka J. Karhunen, MD, PhD, Kjell C. Nikus, MD, PhD, Tuomo Nieminen, MD, PhD, MSc, Jari Laurikka, MD, PhD, Pekka Kuukasjärvi, MD, PhD, Matti Tarkka, MD, PhD, Jari Viik, PhD, Norman Klopp, PhD, Thomas Illig, PhD, Johannes Kettunen, PhD, Markku Ahotupa, PhD, Jorma S.A. Viikari, MD, PhD, Mika Kähönen, MD, PhD, Olli T. Raitakari, MD, PhD, Mahir Karakas, MD, Wolfgang Koenig, MD, PhD, Bernhard O. Boehm, MD, Bernhard R. Winkelmann, MD, Winfried März, MD and Terho Lehtimäki, MD, PhD

Correspondence to Kari-Matti Mäkelä, Department of Clinical Chemistry, Finn-Medi 2, PO Box 2000, FI-33521 Tampere, Finland. E-mail kari-matti.makela@uta.fi

Abstract

Background—Oxidized low-density lipoprotein may be a key factor in the development of atherosclerosis. We performed a genome-wide association study on oxidized low-density lipoprotein and tested the impact of associated single-nucleotide polymorphisms (SNPs) on the risk factors of atherosclerosis and cardiovascular events.

Methods and Results—A discovery genome-wide association study was performed on a population of young healthy white individuals (N=2080), and the SNPs associated with a P<5×10–8 were replicated in 2 independent samples (A: N=2912; B: N=1326). Associations with cardiovascular endpoints were also assessed with 2 additional clinical cohorts (C: N=1118; and D: N=808). We found 328 SNPs associated with oxidized low-density lipoprotein. The genetic variant rs676210 (Pro2739Leu) in apolipoprotein B was the proxy SNP behind all associations (P=4.3×10–136, effect size=13.2 U/L per allele). This association was replicated in the 2 independent samples (A and B, P=2.5×10–47 and 1.1×10–11, effect sizes=10.3 U/L and 7.8 U/L, respectively). In the meta-analyses of cohorts A, C, and D (excluding cohort B without angiographic data), the top SNP did not associate significantly with the age of onset of angiographically verified coronary artery disease (hazard ratio=1.00 [0.94–1.06] per allele), 3-vessel coronary artery disease (hazard ratio=1.03 [0.94–1.13]), or myocardial infarction (hazard ratio=1.04 [0.96–1.12]).

Conclusions—This novel genetic marker is an important factor regulating oxidized low-density lipoprotein levels but not a major genetic factor for the studied cardiovascular endpoints.

 SOURCE:

Circulation: Cardiovascular Genetics.2013; 6: 73-81

Published online before print December 17, 2012,

doi: 10.1161/ CIRCGENETICS.112.964965

Genome-Wide Screen for Metabolic Syndrome Susceptibility Loci Reveals Strong Lipid Gene Contribution But No Evidence for Common Genetic Basis for Clustering of Metabolic Syndrome Traits

Kati Kristiansson, PhD, Markus Perola, MD, PhD, Emmi Tikkanen, MSc, Johannes Kettunen, PhD, Ida Surakka, MSc, Aki S. Havulinna, DSc (Tech.), Alena Stančáková, MD, PhD, Chris Barnes, PhD, Elisabeth Widen, MD, PhD, Eero Kajantie, MD, PhD, Johan G. Eriksson, MD, DMSc, Jorma Viikari, MD, PhD, Mika Kähönen, MD, PhD, Terho Lehtimäki, MD, PhD, Olli T. Raitakari, MD, PhD, Anna-Liisa Hartikainen, MD, PhD, Aimo Ruokonen, MD, PhD, Anneli Pouta, MD, PhD, Antti Jula, MD, PhD, Antti J. Kangas, MSc, Pasi Soininen, PhD, Mika Ala-Korpela, PhD, Satu Männistö, PhD, Pekka Jousilahti, MD, PhD, Lori L. Bonnycastle, PhD, Marjo-Riitta Järvelin, MD, PhD, Johanna Kuusisto, MD, PhD, Francis S. Collins, MD, PhD, Markku Laakso, MD, PhD, Matthew E. Hurles, PhD, Aarno Palotie, MD, PhD, Leena Peltonen, MD, PhD*, Samuli Ripatti, PhD and Veikko Salomaa, MD, PhD

Correspondence to Dr Kati Kristiansson, National Institute for Health and Welfare, University of Helsinki, Biomedicum, PL 104, FI-00251 Helsinki, Finland. E-mail kati.kristiansson@thl.fi

Abstract

Background—Genome-wide association (GWA) studies have identified several susceptibility loci for metabolic syndrome (MetS) component traits, but have had variable success in identifying susceptibility loci to the syndrome as an entity. We conducted a GWA study on MetS and its component traits in 4 Finnish cohorts consisting of 2637 MetS cases and 7927 controls, both free of diabetes, and followed the top loci in an independent sample with transcriptome and nuclear magnetic resonance-based metabonomics data. Furthermore, we tested for loci associated with multiple MetS component traits using factor analysis, and built a genetic risk score for MetS.

Methods and Results—A previously known lipid locus, APOA1/C3/A4/A5 gene cluster region (SNP rs964184), was associated with MetS in all 4 study samples (P=7.23×109 in meta-analysis). The association was further supported by serum metabolite analysis, where rs964184 was associated with various very low density lipoprotein, triglyceride, and high-density lipoprotein metabolites (P=0.024–1.88×105). Twenty-two previously identified susceptibility loci for individual MetS component traits were replicated in our GWA and factor analysis. Most of these were associated with lipid phenotypes, and none with 2 or more uncorrelated MetS components. A genetic risk score, calculated as the number of risk alleles in loci associated with individual MetS traits, was strongly associated with MetS status.

Conclusions—Our findings suggest that genes from lipid metabolism pathways have the key role in the genetic background of MetS. We found little evidence for pleiotropy linking dyslipidemia and obesity to the other MetS component traits, such as hypertension and glucose intolerance.

 SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 242-249

Published online before print March 7, 2012,

doi: 10.1161/ CIRCGENETICS.111.961482

 

Genetics and Vascular Pathologies and Platelet Aggregation, Cardiac Troponin T in Serum

 

 

TGFβRIIb Mutations Trigger Aortic Aneurysm Pathogenesis by Altering Transforming Growth Factor β2 Signal Transduction

Katharine J. Bee, PhD, David C. Wilkes, PhD, Richard B. Devereux, MD, Craig T. Basson, MD, PhD and Cathy J. Hatcher, PhD

Author Affiliations

From the Center for Molecular Cardiology, Greenberg Division of Cardiology, Weill Cornell Medical College, New York, NY.

Correspondence to Cathy J. Hatcher, PhD, Greenberg Division of Cardiology, Weill Cornell Medical College, 525 E. 68th St, New York, NY 10065. E-mail cjhatche@med.cornell.edu

Abstract

Background—Thoracic aortic aneurysm (TAA) is a common progressive disorder involving gradual dilation of the ascending and/or descending thoracic aorta that eventually leads to dissection or rupture. Nonsydromic TAA can occur as a genetically triggered, familial disorder that is usually transmitted in a monogenic autosomal dominant fashion and is known as familial TAA. Genetic analyses of families affected with TAA have identified several chromosomal loci, and further mapping of familial TAA genes has highlighted disease-causing mutations in at least 4 genes: myosin heavy chain 11 (MYH11), α-smooth muscle actin (ACTA2), and transforming growth factor β receptors I and II (TGFβRI and TGFβRII).

Methods and Results—We evaluated 100 probands to determine the mutation frequency in MYH11, ACTA2, TGFβRI, and TGFβRII in an unbiased population of individuals with genetically mediated TAA. In this study, 9% of patients had a mutation in one of the genes analyzed, 3% of patients had mutations in ACTA2, 3% in MYH11, 1% in TGFβRII, and no mutations were found in TGFβRI. Additionally, we identified mutations in a 75 base pair alternatively spliced TGFβRII exon, exon 1a that produces the TGFβRIIb isoform and accounted for 2% of patients with mutations. Our in vitro analyses indicate that the TGFβRIIb activating mutations alter receptor function on TGFβ2 signaling.

Conclusions—We propose that TGFβRIIb expression is a regulatory mechanism for TGFβ2 signal transduction. Dysregulation of the TGFβ2 signaling pathway, as a consequence of TGFβRIIb mutations, results in aortic aneurysm pathogenesis.

SOURCE: 

Circulation: Cardiovascular Genetics.2012; 5: 621-629

Published online before print October 24, 2012,doi: 10.1161/​CIRCGENETICS.112.964064

Matrix Metalloproteinase-9 Genotype as a Potential Genetic Marker for Abdominal Aortic Aneurysm

Tyler Duellman, BS, Christopher L. Warren, PhD, Peggy Peissig, PhD, Martha Wynn, MD and Jay Yang, MD, PhD

Author Affiliations

From the Molecular and Cellular Pharmacology Graduate Program (T.D., J.Y.) and Department of Anesthesiology (M.W., J.Y.), University of Wisconsin School of Medicine and Public Health, Madison; Illumavista Biosciences LLC, Madison, WI (C.L.W.); and Biomedical Informatics Research Center, Marshfield Clinics Research Foundation, Marshfield, WI (P.P.).

Correspondence to Jay Yang, MD, PhD, Department of Anesthesiology, University of Wisconsin SMPH, SMI 301, 1300 University Ave, Madison, WI 53706. E-mail Jyang75@wisc.edu

Abstract

Background—Degradation of extracellular matrix support in the large abdominal arteries contribute to abnormal dilation of aorta, leading to abdominal aortic aneurysms, and matrix metalloproteinase-9 (MMP-9) is the predominant enzyme targeting elastin and collagen present in the walls of the abdominal aorta. Previous studies have suggested a potential association between MMP-9 genotype and abdominal aortic aneurysm, but these studies have been limited only to the p-1562 and (CA) dinucleotide repeat microsatellite polymorphisms in the promoter region of the MMP-9 gene. We determined the functional alterations caused by 15 MMP-9 single-nucleotide polymorphisms (SNPs) reported to be relatively abundant in the human genome through Western blots, gelatinase, and promoter–reporter assays and incorporated this information to perform a logistic-regression analysis of MMP-9 SNPs in 336 human abdominal aortic aneurysm cases and controls.

Methods and Results—Significant functional alterations were observed for 6 exon SNPs and 4 promoter SNPs. Genotype analysis of frequency-matched (age, sex, history of hypertension, hypercholesterolemia, and smoking) cases and controls revealed significant genetic heterogeneity exceeding 20% observed for 6 SNPs in our population of mostly white subjects from Northern Wisconsin. A step-wise logistic-regression analysis with 6 functional SNPs, where weakly contributing confounds were eliminated using Akaike information criteria, gave a final 2 SNP (D165N and p-2502) model with an overall odds ratio of 2.45 (95% confidence interval, 1.06–5.70).

Conclusions—The combined approach of direct experimental confirmation of the functional alterations of MMP-9 SNPs and logistic-regression analysis revealed significant association between MMP-9 genotype and abdominal aortic aneurysm.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 529-537

Published online before print August 31, 2012,

doi: 10.1161/ CIRCGENETICS.112.963082

Common Genetic Variation in the 3BCL11B Gene Desert Is Associated With Carotid-Femoral Pulse Wave Velocity and Excess Cardiovascular Disease Risk

The AortaGen Consortium

Gary F. Mitchell, MD*, Germaine C. Verwoert, MSc*, Kirill V. Tarasov, MD, PhD*, Aaron Isaacs, PhD, Albert V. Smith, PhD, Yasmin, BSc, MA, PhD, Ernst R. Rietzschel, MD, PhD, Toshiko Tanaka, PhD, Yongmei Liu, MD, PhD, Afshin Parsa, MD, MPH, Samer S. Najjar, MD, Kevin M. O’Shaughnessy, MA, BM, DPhil, FRCP, Sigurdur Sigurdsson, MSc, Marc L. De Buyzere, MSc, Martin G. Larson, ScD, Mark P.S. Sie, MD, PhD, Jeanette S. Andrews, MS, Wendy S. Post, MD, MS, Francesco U.S. Mattace-Raso, MD, PhD, Carmel M. McEniery, BSc, PhD, Gudny Eiriksdottir, MSc, Patrick Segers, PhD, Ramachandran S. Vasan, MD, Marie Josee E. van Rijn, MD, PhD, Timothy D. Howard, PhD, Patrick F. McArdle, PhD, Abbas Dehghan, MD, PhD, Elizabeth S. Jewell, MS, Stephen J. Newhouse, MSc, PhD, Sofie Bekaert, PhD, Naomi M. Hamburg, MD, Anne B. Newman, MD, MPH, Albert Hofman, MD, PhD, Angelo Scuteri, MD, PhD, Dirk De Bacquer, PhD, Mohammad Arfan Ikram, MD, PhD†, Bruce M. Psaty, MD, PhD†, Christian Fuchsberger, PhD‡, Matthias Olden, PhD‡, Louise V. Wain, PhD§, Paul Elliott, MB, PhD§, Nicholas L. Smith, PhD‖, Janine F. Felix, MD, PhD‖, Jeanette Erdmann, PhD¶, Joseph A. Vita, MD, Kim Sutton-Tyrrell, PhD, Eric J.G. Sijbrands, MD, PhD, Serena Sanna, PhD, Lenore J. Launer, MS, PhD, Tim De Meyer, PhD, Andrew D. Johnson, MD, Anna F.C. Schut, MD, PhD, David M. Herrington, MD, MHS, Fernando Rivadeneira, MD, PhD, Manuela Uda, PhD, Ian B. Wilkinson, MA, BM, FRCP, Thor Aspelund, PhD, Thierry C. Gillebert, MD, PhD, Luc Van Bortel, MD, PhD, Emelia J. Benjamin, MD, MSc, Ben A. Oostra, PhD, Jingzhong Ding, MD, PhD, Quince Gibson, MBA, André G. Uitterlinden, PhD, Gonçalo R. Abecasis, PhD, John R. Cockcroft, BSc, MB, ChB, FRCP, Vilmundur Gudnason, MD, PhD, Guy G. De Backer, MD, PhD, Luigi Ferrucci, MD, Tamara B. Harris, MD, MS, Alan R. Shuldiner, MD, Cornelia M. van Duijn, PhD, Daniel Levy, MD*, Edward G. Lakatta, MD* and Jacqueline C.M. Witteman, PhD*

Correspondence to Gary F. Mitchell, MD, Cardiovascular Engineering, Inc, 1 Edgewater Dr, Suite 201A, Norwood, MA 02062. E-mail GaryFMitchell@mindspring.com

* These authors contributed equally.

Abstract

Background—Carotid-femoral pulse wave velocity (CFPWV) is a heritable measure of aortic stiffness that is strongly associated with increased risk for major cardiovascular disease events.

Methods and Results—We conducted a meta-analysis of genome-wide association data in 9 community-based European ancestry cohorts consisting of 20 634 participants. Results were replicated in 2 additional European ancestry cohorts involving 5306 participants. Based on a preliminary analysis of 6 cohorts, we identified a locus on chromosome 14 in the 3′-BCL11B gene desert that is associated with CFPWV (rs7152623, minor allele frequency=0.42, β=−0.075±0.012 SD/allele, P=2.8×1010; replication β=−0.086±0.020 SD/allele, P=1.4×106). Combined results for rs7152623 from 11 cohorts gave β=−0.076±0.010 SD/allele, P=3.1×1015. The association persisted when adjusted for mean arterial pressure (β=−0.060±0.009 SD/allele, P=1.0×1011). Results were consistent in younger (<55 years, 6 cohorts, n=13 914, β=−0.081±0.014 SD/allele, P=2.3×109) and older (9 cohorts, n=12 026, β=−0.061±0.014 SD/allele, P=9.4×106) participants. In separate meta-analyses, the locus was associated with increased risk for coronary artery disease (hazard ratio=1.05; confidence interval=1.02–1.08; P=0.0013) and heart failure (hazard ratio=1.10, CI=1.03–1.16, P=0.004).

Conclusions—Common genetic variation in a locus in the BCL11B gene desert that is thought to harbor 1 or more gene enhancers is associated with higher CFPWV and increased risk for cardiovascular disease. Elucidation of the role this novel locus plays in aortic stiffness may facilitate development of therapeutic interventions that limit aortic stiffening and related cardiovascular disease events.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 81-90

Published online before print November 8, 2011,

doi: 10.1161/ CIRCGENETICS.111.959817

Genetic Variation in PEAR1 is Associated with Platelet Aggregation and Cardiovascular Outcomes

Joshua P. Lewis1, Kathleen Ryan1, Jeffrey R. O’Connell1, Richard B. Horenstein1, Coleen M. Damcott1, Quince Gibson1, Toni I. Pollin1, Braxton D. Mitchell1, Amber L. Beitelshees1, Ruth Pakzy1, Keith Tanner1, Afshin Parsa1, Udaya S. Tantry2, Kevin P. Bliden2, Wendy S. Post3, Nauder Faraday3, William Herzog4, Yan Gong5, Carl J. Pepine6, Julie A. Johnson5, Paul A. Gurbel2 and Alan R. Shuldiner7*

Author Affiliations

1University of Maryland School of Medicine, Baltimore, MD

2Sinai Hospital of Baltimore, Baltimore, MD

3Johns Hopkins University School of Medicine, Baltimore, MD

4Sinai Hospital of Baltimore & Johns Hopkins University School of Medicine, Baltimore, MD

5University of Florida College of Pharmacy, Gainesville, FL

6University of Florida College of Medicine, Gainesville, FL

7University of Maryland School of Medicine & Veterans Administration Medical Center, Baltimore, MD

* University of Maryland School of Medicine & Veterans Administration Medical Center, Baltimore, MD ashuldin@medicine.umaryland.edu

Abstract

Background-Aspirin or dual antiplatelet therapy (DAPT) with aspirin and clopidogrel is standard therapy for patients at increased risk for cardiovascular events. However, the genetic determinants of variable response to aspirin (alone and in combination with clopidogrel) are not known.

Methods and Results-We measured ex-vivo platelet aggregation before and after DAPT in individuals (n=565) from the Pharmacogenomics of Antiplatelet Intervention (PAPI) Study and conducted a genome-wide association study (GWAS) of drug response. Significant findings were extended by examining genotype and cardiovascular outcomes in two independent aspirin-treated cohorts: 227 percutaneous coronary intervention (PCI) patients, and 1,000 patients of the International VErapamil SR/trandolapril Study (INVEST) GENEtic Substudy (INVEST-GENES). GWAS revealed a strong association between single nucleotide polymorphisms on chromosome 1q23 and post-DAPT platelet aggregation. Further genotyping revealed rs12041331 in the platelet endothelial aggregation receptor-1 (PEAR1) gene to be most strongly associated with DAPT response (P=7.66×10-9). In Caucasian and African American patients undergoing PCI, A-allele carriers of rs12041331 were more likely to experience a cardiovascular event or death compared to GG homozygotes (hazard ratio = 2.62, 95%CI 0.96-7.10, P=0.059 and hazard ratio = 3.97, 95%CI 1.10-14.31, P=0.035 respectively). In aspirin-treated INVEST-GENES patients, rs12041331 A-allele carriers had significantly increased risk of myocardial infarction compared to GG homozygotes (OR=2.03, 95%CI 1.01-4.09, P=0.048).

Conclusions-Common genetic variation in PEAR1 may be a determinant of platelet response and cardiovascular events in patients on aspirin, alone and in combination with clopidogrel.

Clinical Trial Registration Information-clinicaltrials.gov; Identifiers: NCT00799396 and NCT00370045

SOURCE:

CIRCGENETICS.112.964627

Published online before print February 7, 2013,

doi: 10.1161/ CIRCGENETICS.111.964627

Association of Genome-Wide Variation With Highly Sensitive Cardiac Troponin-T Levels in European Americans and Blacks

A Meta-Analysis From Atherosclerosis Risk in Communities and Cardiovascular Health Studies

Bing Yu, MD, MSc, Maja Barbalic, PhD, Ariel Brautbar, MD, Vijay Nambi, MD, Ron C. Hoogeveen, PhD, Weihong Tang, PhD, Thomas H. Mosley, PhD, Jerome I. Rotter, MD, Christopher R. deFilippi, MD, Christopher J. O’Donnell, MD, Sekar Kathiresan, MD, Ken Rice, PhD, Susan R. Heckbert, MD, PhD, Christie M. Ballantyne, MD, Bruce M. Psaty, MD, PhD and Eric Boerwinkle, PhD on behalf of the CARDIoGRAM Consortium

Author Affiliations

From the Human Genetic Center, University of Texas Health Science Center at Houston, Houston, TX (B.Y., M.B., E.B.); Deptartment of Medicine (A.B., V.N., R.C.H., C.M.B.), and Human Genome Sequencing Center (E.B.), Baylor College of Medicine, Houston, TX; Department of Epidemiology, University of Minnesota, Minneapolis, MN (W.T.); Division of Geriatrics, University of Mississippi Medical Center, Jackson, MS (T.H.M.); Medical Genetics Institute, Cedars-Sinai Medical Center, Los Angeles, CA (J.I.R.); School of Medicine, University of Maryland, Baltimore, MD (C.R.D.); National Heart, Lung, and Blood Institute and Framingham Heart Study, National Institutes of Health, Bethesda, MD (C.J.O.D.); Center for Human Genetic Research & Cardiovascular Research Center, Massachusetts General Hospital and Department of Medicine, Harvard Medical School, Boston, MA (S.K.); Department of Biostatistics (K.R.), and Cardiovascular Health Research Unit & Department of Epidemiology (S.R.H.), University of Washington, Seattle, WA; and Cardiovascular Health Research Unit, Departments of Medicine, Epidemiology, and Health Services, University of Washington & Group Health Research Institute, Group Health Cooperative, Seattle, WA (B.M.P.).

Correspondence to Eric Boerwinkle, PhD, Human Genetic Center, University of Texas School of Public Health, 1200 Herman Pressler E-447, Houston, TX 77030. E-mail Eric.Boerwinkle@uth.tmc.edu

Abstract

Background—High levels of cardiac troponin T, measured by a highly sensitive assay (hs-cTnT), are strongly associated with incident coronary heart disease and heart failure. To date, no large-scale genome-wide association study of hs-cTnT has been reported. We sought to identify novel genetic variants that are associated with hs-cTnT levels.

Methods and Results—We performed a genome-wide association in 9491 European Americans and 2053 blacks free of coronary heart disease and heart failure from 2 prospective cohorts: the Atherosclerosis Risk in Communities Study and the Cardiovascular Health Study. Genome-wide association studies were conducted in each study and race stratum. Fixed-effect meta-analyses combined the results of linear regression from 2 cohorts within each race stratum and then across race strata to produce overall estimates and probability values. The meta-analysis identified a significant association at chromosome 8q13 (rs10091374; P=9.06×109) near the nuclear receptor coactivator 2 (NCOA2) gene. Overexpression of NCOA2 can be detected in myoblasts. An additional analysis using logistic regression and the clinically motivated 99th percentile cut point detected a significant association at 1q32 (rs12564445; P=4.73×108) in the gene TNNT2, which encodes the cardiac troponin T protein itself. The hs-cTnT-associated single-nucleotide polymorphisms were not associated with coronary heart disease in a large case-control study, but rs12564445 was significantly associated with incident heart failure in Atherosclerosis Risk in Communities Study European Americans (hazard ratio=1.16; P=0.004).

Conclusions—We identified 2 loci, near NCOA2 and in the TNNT2 gene, at which variation was significantly associated with hs-cTnT levels. Further use of the new assay should enable replication of these results.

 SOURCE:

Circulation: Cardiovascular Genetics.2013; 6: 82-88

Published online before print December 16, 2012,

doi: 10.1161/ CIRCGENETICS.112.963058

 

Genomics and Valvular Disease

 

Supravalvular Aortic Stenosis Elastin Arteriopathy

 

Giuseppe Merla, PhD, Nicola Brunetti-Pierri, MD, Pasquale Piccolo, PhD, Lucia Micale, PhD and Maria Nicla Loviglio, PhD, MSc

Author Affiliations

From the Medical Genetics Unit, IRCCS Casa Sollievo Della Sofferenza Hospital, San Giovanni Rotondo, Italy (G.M., L.M., M.N.L.); Telethon Institute of Genetics and Medicine, Napoli, Italy (N.B-P., P.P.); Department of Pediatrics, Federico II University of Naples, Naples, Italy (N.B-P.); and CIG Center for Integrative Genomics, University of Lausanne, Lausanne, Switzerland (M.N.L.).

Correspondence to Giuseppe Merla, PhD, Medical Genetics Unit, IRCCS Casa Sollievo della Sofferenza, viale Cappuccini, 71013 San Giovanni Rotondo, Italy. E-mail g.merla@operapadrepio.it

Abstract

Supravalvular aortic stenosis is a systemic elastin (ELN) arteriopathy that disproportionately affects the supravalvular aorta. ELN arteriopathy may be present in a nonsyndromic condition or in syndromic conditions such as Williams–Beuren syndrome. The anatomic findings include congenital narrowing of the lumen of the aorta and other arteries, such as branches of pulmonary or coronary arteries. Given the systemic nature of the disease, accurate evaluation is recommended to establish the degree and extent of vascular involvement and to plan appropriate interventions, which are indicated whenever hemodynamically significant stenoses occur. ELN arteriopathy is genetically heterogeneous and occurs as a consequence of haploinsufficiency of the ELN gene on chromosome 7q11.23, owing to either microdeletion of the entire chromosomal region or ELN point mutations. Interestingly, there is a prevalence of premature termination mutations resulting in null alleles among ELN point mutations. The identification of the genetic defect in patients with supravalvular aortic stenosis is essential for a definitive diagnosis, prognosis, and genetic counseling.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 692-696

doi: 10.1161/ CIRCGENETICS.112.962860

Genetic Loci for Coronary Calcification and Serum Lipids Relate to Aortic and Carotid Calcification

Daniel Bos, MD, M. Arfan Ikram, MD, PhD, Aaron Isaacs, PhD, Benjamin F.J. Verhaaren, MD, Albert Hofman, MD, PhD, Cornelia M. van Duijn, PhD, Jacqueline C.M. Witteman, PhD, Aad van der Lugt, MD, PhD and Meike W. Vernooij, MD, PhD

Author Affiliations

From the Departments of Radiology (D.B., M.A.I., B.F.J.V., A.v.d.L., M.W.V), Epidemiology (D.B., M.A.I., A.I., B.F.J.V., A.H., C.M.v.D., J.C.M.W., M.W.V.), and Genetic Epidemiology Unit (A.I., C.M.v.D.), Erasmus MC, Rotterdam, the Netherlands.

Correspondence to Meike W. Vernooij, MD, PhD, Department of Radiology, Erasmus MC, Gravendijkwal 230, PO Box 2040, 3000CA Rotterdam, the Netherlands. E-mail m.vernooij@erasmusmc.nl

Abstract

Background—Atherosclerosis in different vessel beds shares lifestyle and environmental risk factors. It is unclear whether this holds for genetic risk factors. Hence, for the current study genetic loci for coronary artery calcification and serum lipid levels, one of the strongest risk factors for atherosclerosis, were used to assess their relation with atherosclerosis in different vessel beds.

Methods and Results—From 1987 persons of the population-based Rotterdam Study, 3 single-nucleotide polymorphisms (SNPs) for coronary artery calcification and 132 SNPs for total cholesterol, low-density lipoprotein cholesterol, high-density lipoprotein cholesterol or triglycerides were used. To quantify atherosclerotic calcification as a marker of atherosclerosis, all participants underwent nonenhanced computed tomography of the aortic arch and carotid arteries. Associations between genetic risk scores of the joint effect of the SNPs and of all calcification were investigated. The joint effect of coronary artery calcification–SNPs was associated with larger calcification volumes in all vessel beds (difference in calcification volume per SD increase in genetic risk score: 0.15 [95% confidence interval, 0.11–0.20] in aorta, 0.14 [95% confidence interval, 0.10–0.18] in extracranial carotids, and 0.11 [95% confidence interval, 0.07–0.16] in intracranial carotids). The joint effect of total cholesterol SNPs, low-density lipoprotein SNPs, and of all lipid SNPs together was associated with larger calcification volumes in both the aortic arch and the carotid arteries but attenuated after adjusting for the lipid fraction and lipid-lowering medication.

Conclusions—The genetic basis for aortic arch and carotid artery calcification overlaps with the most important loci of coronary artery calcification. Furthermore, serum lipids share a genetic predisposition with both calcification in the aortic arch and the carotid arteries, providing novel insights into the cause of atherosclerosis.

 SOURCE:

Circulation: Cardiovascular Genetics.2013; 6: 47-53

Published online before print December 16, 2012,

doi: 10.1161/ CIRCGENETICS.112.963934

 

Joint Associations of 61 Genetic Variants in the Nicotinic Acetylcholine Receptor Genes with Subclinical Atherosclerosis in American Indians

A Gene-Family Analysis

Jingyun Yang, PhD*, Yun Zhu, MS*, Elisa T. Lee, PhD, Ying Zhang, PhD, Shelley A. Cole, PhD, Karin Haack, PhD, Lyle G. Best, BS MD, Richard B. Devereux, MD, Mary J. Roman, MD, Barbara V. Howard, PhD and Jinying Zhao, MD, PhD

Author Affiliations

From the Tulane University School of Public Health and Tropical Medicine, New Orleans, LA (J.Y., Y. Zhu, J.Z.); Center for American Indian Health Research, University of Oklahoma Health Sciences Center, Oklahoma City, OK (E.T.L., Y. Zhang); Texas Biomedical Research Institute, San Antonio, TX (S.A.C., K.H.); Missouri Breaks Industries Research Inc, Timber Lake, SD (L.G.B.); The New York Hospital-Cornell Medical Center, New York, NY (R.B.D., M.J.R.); MedStar Health Research Institute, Hyattsville, MD (B.V.H.); and Georgetown and Howard Universities Centers for Translational Sciences, Washington, DC (B.V.H.).

Correspondence to Jinying Zhao, MD, PhD, Department of Epidemiology, School of Public Health and Tropical Medicine, Tulane University, 1440 Canal St, SL18, New Orleans, LA 70112. E-mail jzhao5@tulane.edu

* These authors contributed equally to this work.

Abstract

Background—Atherosclerosis is the underlying cause of cardiovascular disease, the leading cause of morbidity and mortality in all American populations, including American Indians. Genetic factors play an important role in the pathogenesis of atherosclerosis. Although a single-nucleotide polymorphism (SNP) may explain only a small portion of variability in disease, the joint effect of multiple variants in a pathway on disease susceptibility could be large.

Methods and Results—Using a gene-family analysis, we investigated the joint associations of 61 tag SNPs in 7 nicotinic acetylcholine receptor genes with subclinical atherosclerosis, as measured by carotid intima-media thickness and plaque score, in 3665 American Indians from 94 families recruited by the Strong Heart Family Study (SHFS). Although multiple SNPs showed marginal association with intima-media thickness and plaque score individually, only a few survived adjustments for multiple testing. However, simultaneously modeling of the joint effect of all 61 SNPs in 7 nicotinic acetylcholine receptor genes revealed significant association of the nicotinic acetylcholine receptor gene family with both intima-media thickness and plaque score independent of known coronary risk factors.

Conclusions—Genetic variants in the nicotinic acetylcholine receptor gene family jointly contribute to subclinical atherosclerosis in American Indians who participated in the SHFS. These variants may influence the susceptibility of atherosclerosis through pathways other than cigarette smoking per se.

SOURCE:

Circulation: Cardiovascular Genetics.2013; 6: 89-96

Published online before print December 22, 2012,

doi: 10.1161/ CIRCGENETICS.112.963967

 

 

Heredity of Cardiovascular Disorders Inheritance

 

A Clinical Approach to Common Cardiovascular Disorders When There Is a Family History

The Implications of Inheritance for Clinical Management

Srijita Sen-Chowdhry, MBBS, MD, FESC, Daniel Jacoby, MD and William J. McKenna, MD, DSc, FESC

Author Affiliations

From the Institute of Cardiovascular Science, University College London, London, United Kingdom (S.S-C., W.J.M.); Department of Epidemiology, Imperial College, London, London, United Kingdom (S.S-C.); Division of Cardiology, Yale School of Medicine, New Haven, CT (D.J., W.J.M.).

Correspondence to Professor William J. McKenna, MD, DSc, FESC, Institute of Cardiovascular Science, University College London, The Heart Hospital, 16-18 Westmoreland Street, London, E-mail william.mckenna@uclh.nhs.uk

Introduction

Since the advent of genotyping, recognition of heritable disease has been perceived as an opportunity for genetic diagnosis or new gene identification studies to advance understanding of pathogenesis. Until recently, however, clinical application of DNA-based testing was confined largely to Mendelian disorders. Even within this remit, predictive testing of relatives is cost-effective only in diseases in which the majority of families harbor mutations in known causal genes, such as adult polycystic kidney disease and hypertrophic cardiomyopathy, but not dilated cardiomyopathy. Confirmatory genetic testing of index cases with borderline clinical features may be economic in the still smaller subset of diseases with limited locus heterogeneity, such as Marfan syndrome. Furthermore, Mendelian diseases account for ≈5% of total disease burden.1 Genome-wide association studies have made headway in elucidating the genetic contribution to the more common, complex diseases, and high throughput techniques promise to facilitate integration of genetic analysis into clinical practice. Nevertheless, many genes remain to be identified and implementation of genomic profiling as a population screening tool would not be cost-effective at present. The implications of heredity, however, extend beyond serving as a platform for genetic analysis, influencing diagnosis, prognostication, and treatment of both index cases and relatives, and enabling rational targeting of genotyping resources. This review covers acquisition of a family history, evaluation of heritability and inheritance patterns, and the impact of inheritance on subsequent components of the clinical pathway.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 467-476

doi: 10.1161/ CIRCGENETICS.110.959361

Clinical Considerations of Heritable Factors in Common Heart Failure

Thomas P. Cappola, MD, ScM and Gerald W. Dorn II, MD

Author Affiliations

From the Department of Medicine, University of Pennsylvania, Philadelphia, PA (T.P.C.), and Center for Pharmacogenomics, Washington University School of Medicine, St Louis, MO (G.W.D.II.).

Correspondence to Gerald W. Dorn II, MD, Center for Pharmacogenomics, Washington University, 660 S Euclid Ave, Campus Box 8220, St Louis, MO 63110. E-mail gdorn@dom.wustl.edu

 

Introduction

Heart failure is a common condition responsible for at least 290 000 deaths each year in the United States alone.1 A small minority of heart failure cases are attributed to Mendelian or familial cardiomyopathies. The majority of systolic heart failure cases are not familial but represent the end result of 1 or many conditions that primarily injure the myocardium sufficiently to diminish cardiac output in the absence of compensatory mechanisms. Paradoxically, because they also injure the myocardium, it is the chronic actions of the compensatory mechanisms that in many instances contribute to the progression from simple cardiac injury to dilated cardiomyopathy and overt heart failure. Thus, the epidemiology of common heart failure appears to be just as sporadic as its major antecedent conditions (atherosclerosis, diabetes, hypertension, and viral myocarditis).

Familial trends in preclinical cardiac remodeling2 and risk of developing heart failure3 reveal an important role for genetic modifiers in addition to clinical and environmental factors. Candidate gene studies performed over the past 10 years have identified a few polymorphic gene variants that modify risk or progression of common heart failure.4 Whole-genome sequencing will lead to the discovery of other genetic modifiers that were not candidates.5 The imminent availability of individual whole-genome sequences at a cost competitive with available genetic tests for familial cardiomyopathy will no doubt further expand the list of putative genetic heart failure modifiers. Heart failure risk alleles along with traditional clinical factors will need to be considered by clinical cardiologists in their design of optimal disease surveillance and prevention programs and in individually tailoring heart failure management.

The use of individual genetic make-up is likely to have the earliest and greatest impact on managing patients with heart failure by tailoring available pharmacotherapeutics to optimize patient response and minimize adverse effects (ie, the area of pharmacogenetics). Modern heart failure management has been derived and directed by the results of large, randomized, multicenter clinical trials. When standard therapies are applied according to the selection criteria used in these trials, they prolong average survival across affected populations or decrease the incidence of heart failure in populations at risk.6 For this reason, standardized treatment guidelines prescribe heart failure therapies according to trial designs, aiming for the same target doses and general treatment approaches,7 and largely ignore individual characteristics. In this article, we review established and emerging knowledge of genetic influence on common heart failure and try to anticipate how these genetic factors may be best used to eschew the cookie-cutter approach to heart failure management and move toward implementing a personalized medicine approach for the treatment and prevention of this important and prevalent disease.

The Concept of Genotype-Directed Personal Medical Management in Heart Failure

Variation in clinical heart failure progression and therapeutic response (either benefits or side effects) supports the need for a more individualized approach to disease management. On the basis of clinical stratification (eg, by etiology of heart failure as ischemic versus nonischemic, functional status, comorbid disease), physicians try to match each patient’s specific heart failure syndrome with a therapeutic regime devised to provide the most benefit. Standard heart failure pharmacotherapy currently comprises a minimum of 3 medications (angiotensin-converting enzyme [ACE] inhibitors, β-blockers, and aldosterone antagonists), with consideration of additional medications (hydralazine/isosorbide, angiotensin receptor blockers) and diuretics. The recommended target dosages for these agents, derived from their respective clinical trials, is rarely achieved,8 partly because of untoward clinical side effects such as low blood pressure or renal dysfunction. Accordingly, the published guidelines most often are applied in each individual patient using ad hoc approaches derived from personal experience and the “art of medicine.”

Technological advances in human genomics promise a different approach and are bringing cardiology into an era of clinically applied pharmacogenetics9 (whether we want to or not). As sequencing costs decline, it is not hard to envision that patients will present having had their entire genome already sequenced. The imperative to apply genome information in clinical settings will increase, as demonstrated by recent proof-of-concept studies.10 Our field seems poorly prepared for this type of evolution in care; Roden et al9 identified 3 major barriers: First is the absence of rapidly available genotype information in the clinical workflow. This barrier is being overcome with whole-genome sequencing, which (with proper analysis) promises a permanent and largely immutable genetic roadmap for individual disease risk and drug response at a cost comparable to many other clinical tests.11 Second, we must have the knowledge to properly apply information on genetic variants for the diseases we are managing and the drugs we are using. As we describe, this knowledge is accumulating for heart failure and for other cardiac conditions, and the rate at which we are gaining additional information and developing further expertise appears to be accelerating.

The third and perhaps most formidable barrier is the lack of clinical evidence showing how real-time application of genetic information can best benefit patients. As has been broadly communicated to the medical community and lay public, common functional gene variants in CYP2C19 can impair the transformation of clopidogrel into its active metabolite, leading to increased risk of stent thrombosis after percutaneous coronary intervention.12 The relevant question thus becomes the following: If physicians have this information at the time of clinical care and reacted by adjusting clopidogrel dose or substituting prasugrel, which is unaffected by CYP2C19 genotype,13 would there be any improvement in clinical outcome? It is also important to consider whether any observed benefits justify the additional costs of genetic testing and for the alternate drug. Studies are currently examining these questions, and similar clinical trials will prospectively examine whether a genotype-guided strategy of warfarin dosing will be superior to the standard genotype-blinded approach in reaching target anticoagulation goals. At this time, there are no similar prospective, randomized, blinded trials of genotype-guided care for common heart failure.

Emerging Variants

The variants described here are established, but new ones are emerging. Although findings in heart failure genome-wide association studies have been limited, we can expect additional common heart failure variants to emerge as sample sizes increase.65 The CHARGE (Cohorts for Heart and Aging Research in Genomic Epidemiology) consortium published a genome-wide association study of incident heart failure that tested for associations between >2.4 million HapMap-imputed polymorphisms in >20 000 subjects.7 They identified 2 loci associated with heart failure, rs10519210 (15q22, containing USP3 encoding a ubiquitin-specific protease) in subjects of European ancestry and rs11172782 (12q14, containing LRIG3 encoding a leucine-rich, immunoglobulin-like domain-containing protein of uncertain function) in subjects of African ancestry.66 In a companion study using the same population and genotyping results, mortality analysis of the subgroup of individuals who developed heart failure implicated an intronic SNP in CMTM7 (CKLF-like MARVEL transmembrane domain-containing 7).67 These genetic associations require independent replication and further study to identify the underlying biological mechanisms.

A recently published genome-wide association study by a European consortium on dilated cardiomyopathy identified common variants in BAG3 (BCL2-associated athanogene 3) associated with heart failure57 and identified rare BAG3 missense and truncation mutations that segregate with familial cardiomyopathy. These findings were consistent with an earlier exome-sequencing study that identified BAG3 as a familial dilated cardiomyopathy gene and showed recapitulation of cardiomyopathy with BAG3 morpholino knockdown in zebra fish.68 Together, these studies convincingly support variation in BAG3 as a genetic risk factor of cardiomyopathy and heart failure. It is noteworthy that both common and rare functional variations were identified at this locus. A unifying hypothesis for these findings, which needs to be formally tested, is that common variants in BAG3 serve as proxies for rare functional BAG3 mutations with large effects. In this situation, the underlying genetic lesion is a rare variant with a large functional effect. This has recently been described for common variants in MYH6 that correlated with rare functional MYH6 variants to cause sick sinus syndrome.69 It is premature to speculate on the clinical applications of these newer findings.

Moving Knowledge to Practice

A small number of genomic variants have been identified that modify heart failure by affecting well-understood physiological systems. The principal barrier preventing their adoption in practice may be lack of evidence showing how application of this information can best be used for clinical benefit. Trials testing genotype targeting of antiplatelet therapy and anticoagulation will be completed in the coming years. The findings from these studies will likely determine the level of enthusiasm for conducting genotype-guided trials of β-blockers and RAAS antagonists in heart failure. Given that the lifetime risk of heart failure in the United States is estimated at 1 in 5, even a small favorable effect on heart failure prevention or outcome through use of genome-guided therapy has the potential for a large public health impact. We therefore believe that a near-term goal should be to conduct pharmacogenomic trials in heart failure based on our current understanding of heart failure variants.

Looking ahead, unbiased approaches will continue to reveal a large number heart failure-modifying variants (both common and rare). Based on experience in other complex phenotypes, such has height70 and plasma lipid levels,71 the underlying genetic mechanisms for many new heart failure variants will be completely unknown, and their sheer number will preclude detailed experimentation using murine models to figure them out. Leveraging these variants for clinical application is a challenge that we will be forced to confront.

As our ability to identify rare, disease-causing variants improves through personal genome sequencing, we will be faced with the additional problem of how best to estimate the disease risk conferred by a sequence variant for which there has been no biological validation. In probabilistic terms, because there are 3 billion nucleotides in the human genome and over twice that many humans on the planet, it is likely that a nucleotide substitution for every position is represented in someone. Obviously, it will be impossible to recombinantly express and functionally characterize every DNA variant that is going to be implicated in heart failure. Bioinformatics filters have been used to try and separate functionally significant from insignificant variants based on the likelihood of changing transcript expression or protein function. These tools are limited but will improve if we tailor their results to the known characteristics of each gene product. For example, current approaches to categorize amino acid substitutions as conservative or nonconservative based only on charge or side chains can be improved by molecular modeling that incorporates protein-specific structure-function information. This approach has been used to estimate the pathogenicity of myosin heavy chain (MHC) mutations in an effort to determine which mutations are likely to cause familial cardiomyopathy when linkage analysis is not feasible.72 In concept, this approach can be applied to any protein for which structure-function activities have been finely mapped to distinct domains.

A promising extension of this approach may be to use evolutionary genetics to infer disease causality. Again, using the MHC genes as examples, human genome data show a greater prevalence of nonsynonymous gene variants in MYH6, which encodes the minor cardiac α-MHC isoform, compared with the adjacent MYH7, which encodes the major β-MHC isoform. This disparity suggests a greater tolerance for protein changes in the α-MHC isoform and negative selection against these in β-MHC. We can infer, therefore, that amino acid changes are more likely to have adverse impacts in MYH7-encoded β-MHC. If this paradigm survives prospective testing, then the forthcoming explosion of individual genetic data not only will present a massive problem in interpretation, but also will provide the genetic information by which analyses of rare sequence variants across large unaffected populations can help to differentiate the tolerable variants from those that are more likely to alter disease risk.

Each Reference above is found in:

http://circgenetics.ahajournals.org/content/4/6/701.full

SOURCE: 

Circulation: Cardiovascular Genetics.2011; 4: 701-709

doi: 10.1161/ CIRCGENETICS.110.959379

 

Pharmacogenomics

 

Hypertension Susceptibility Loci and Blood Pressure Response to Antihypertensives

Results From the Pharmacogenomic Evaluation of Antihypertensive Responses Study

Yan Gong, PhD, Caitrin W. McDonough, PhD, Zhiying Wang, MS, Wei Hou, PhD, Rhonda M. Cooper-DeHoff, PharmD, MS, Taimour Y. Langaee, PhD, Amber L. Beitelshees, PharmD, MPH, Arlene B. Chapman, MD, John G. Gums, PharmD, Kent R. Bailey, PhD, Eric Boerwinkle, PhD, Stephen T. Turner, MD and Julie A. Johnson, PharmD

Author Affiliations

From the Department of Pharmacotherapy and Translational Research (Y.G., C.W.M., R.M.C.-D., T.Y.L., J.G.G., J.A.J.), Department of Biostatistics, College of Medicine (W.H.), Division of Cardiovascular Medicine, College of Medicine (R.M.C.-D., J.A.J.), and Department of Community Health and Family Medicine (J.G.G.), University of Florida, Gainesville, FL; Division of Epidemiology, University of Texas at Houston, Houston, TX (Z.W., E.B.); Division of Endocrinology, Diabetes and Nutrition, University of Maryland, Baltimore, MD (A.L.B.); Renal Division, Emory University, Atlanta, GA (A.B.C.); and Division of Nephrology and Hypertension, Mayo Clinic, Rochester, MN (S.T.T.).

Correspondence to Yan Gong, PhD, Department of Pharmacotherapy and Translational Research, University of Florida, PO Box 100486, 1600 SW Archer Rd, Gainesville, FL 32610. E-mail gong@cop.ufl.edu.

Abstract

Background—To date, 39 single nucleotide polymorphisms (SNPs) have been associated with blood pressure (BP) or hypertension in genome-wide association studies in whites. Our hypothesis is that the loci/SNPs associated with BP/hypertension are also associated with BP response to antihypertensive drugs.

Methods and Results—We assessed the association of these loci with BP response to atenolol or hydrochlorothiazide monotherapy in 768 hypertensive participants in the Pharmacogenomics Responses of Antihypertensive Responses study. Linear regression analysis was performed on whites for each SNP in an additive model adjusting for baseline BP, age, sex, and principal components for ancestry. Genetic scores were constructed to include SNPs with nominal associations, and empirical P values were determined by permutation test. Genotypes of 37 loci were obtained from Illumina 50K cardiovascular or Omni1M genome-wide association study chips. In whites, no SNPs reached Bonferroni-corrected α of 0.0014, 6 reached nominal significance (P<0.05), and 3 were associated with atenolol BP response at P<0.01. The genetic score of the atenolol BP-lowering alleles was associated with response to atenolol (P=3.3×10–6 for systolic BP; P=1.6×10–6 for diastolic BP). The genetic score of the hydrochlorothiazide BP-lowering alleles was associated with response to hydrochlorothiazide (P=0.0006 for systolic BP; P=0.0003 for diastolic BP). Both risk score P values were <0.01 based on the empirical distribution from the permutation test.

Conclusions—These findings suggest that selected signals from hypertension genome-wide association studies may predict BP response to atenolol and hydrochlorothiazide when assessed through risk scoring.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 686-691

Published online before print October 19, 2012,

doi: 10.1161/ CIRCGENETICS.112.964080

 

Genetic Determinants of Statin-Induced Low-Density Lipoprotein Cholesterol Reduction

The Justification for the Use of Statins in Prevention: An Intervention Trial Evaluating Rosuvastatin (JUPITER) Trial

Daniel I. Chasman, PhD, Franco Giulianini, PhD, Jean MacFadyen, BA, Bryan J. Barratt, PhD, Fredrik Nyberg, MD, PhD, MPH and Paul M Ridker, MD, MPH

Author Affiliations

From the Center for Cardiovascular Disease Prevention (D.I.C., F.G., J.M., P.M.R.), JUPITER Trial Coordinating Center (D.I.C., F.G., J.M., P.M.R.), Brigham and Women’s Hospital and Harvard Medical School (D.I.C., P.M.R.), Boston, MA; Personalised Healthcare and Biomarkers, AstraZeneca Research and Development, Alderley Park, United Kingdom (B.J.B.); AstraZeneca Research and Development, Mölndal, Sweden (F.N.); and Unit of Occupational and Environmental Medicine, Department of Public Health and Community Medicine, Sahlgrenska Academy, University of Gothenburg, Gothenburg, Sweden (F.N.).

Correspondence to Daniel I. Chasman, PhD, Center for Cardiovascular Disease Prevention, Brigham and Women’s Hospital, 900 Commonwealth Ave E, Boston, MA 02215. E-mail dchasman@rics.bwh.harvard.edu

Abstract

Background—In statin trials, each 20 mg/dL reduction in cholesterol results in a 10–15% reduction of annual incidence rates for vascular events. However, interindividual variation in low-density lipoprotein cholesterol (LDL-C) response to statins is wide and may partially be determined on a genetic basis.

Methods and Results—A genome-wide association study of LDL-C response was performed among a total of 6989 men and women of European ancestry who were randomly allocated to either rosuvastatin 20 mg daily or placebo. Single nucleotide polymorphisms (SNPs) for genome-wide association (P<5×108) with LDL-C reduction on rosuvastatin were identified at ABCG2, LPA, and APOE, and a further association at PCSK9 was genome-wide significant for baseline LDL-C and locus-wide significant for LDL-C reduction. Median LDL-C reductions on rosuvastatin were 40, 48, 51, 55, 60, and 64 mg/dL, respectively, among those inheriting increasing numbers of LDL-lowering alleles for SNPs at these 4 loci (P trend=6.2×1020), such that each allele approximately doubled the odds of percent LDL-C reduction greater than the trial median (odds ratio, 1.9; 95% confidence interval, 1.8–2.1; P=5.0×1041). An intriguing additional association with sub–genome-wide significance (P<1×10-6) was identified for statin related LDL-C reduction at IDOL, which mediates posttranscriptional regulation of the LDL receptor in response to intracellular cholesterol levels. In candidate analysis, SNPs in SLCO1B1 and LDLR were confirmed as associated with LDL-C lowering, and a significant interaction was observed between SNPs in PCSK9 and LDLR.

Conclusions—Inherited polymorphisms that predominantly relate to statin pharmacokinetics and endocytosis of LDL particles by the LDL receptor are common in the general population and influence individual patient response to statin therapy.

SOURCE:

Circulation: Cardiovascular Genetics.2012; 5: 257-264

Published online before print February 13, 2012,

doi: 10.1161/ CIRCGENETICS.111.961144

Genetic Variation in the β2 Subunit of the Voltage-Gated Calcium Channel and Pharmacogenetic Association With Adverse Cardiovascular Outcomes in the INternational VErapamil SR-Trandolapril STudy GENEtic Substudy (INVEST-GENES)

Yuxin Niu, PhD*, Yan Gong, PhD*, Taimour Y. Langaee, PhD, Heather M. Davis, PharmD, Hazem Elewa, PhD, Amber L. Beitelshees, PharmD, MPH, James I. Moss, PhD, Rhonda M. Cooper-DeHoff, PharmD, Carl J. Pepine, MD and Julie A. Johnson, PharmD

Author Affiliations

From the Department of Pharmacotherapy and Translational Research and Center for Pharmacogenomics (Y.N., Y.G., T.Y.L., H.M.D., H.E., J.I.M., R.M.C.-D., J.A.J.), College of Pharmacy, University of Florida, Gainesville, Fla; Division of Endocrinology, Diabetes and Nutrition (A.L.B.), University of Maryland School of Medicine, Baltimore, Md; and Division of Cardiovascular Medicine (R.M.C.-D., C.J.P., J.A.J.), University of Florida College of Medicine, Gainesville, Fla.

Correspondence to Julie A. Johnson, PharmD, Department of Pharmacotherapy and Translational Research, College of Pharmacy, University of Florida, PO Box 100486, Gainesville, FL 32610. E-mail Johnson@cop.ufl.edu

* Drs Niu and Gong contributed equally to this work.

Abstract

Background— Single-nucleotide polymorphisms (SNPs) within the regulatory β2 subunit of the voltage-gated calcium channel (CACNB2) may contribute to variable treatment response to antihypertensive drugs and adverse cardiovascular outcomes.

Methods and Results— SNPs in CACNB2 from 60 ethnically diverse individuals were identified and characterized. Three common SNPs (rs2357928, rs7069292, and rs61839258) and a genome-wide association study-identified intronic SNP (rs11014166) were genotyped for a clinical association study in 5598 hypertensive patients with coronary artery disease randomized to a β-blocker (BB) or a calcium channel blocker (CCB) treatment strategy in the INternational VErapamil SR-Trandolapril STudy GENEtic Substudy (INVEST-GENES). Reporter gene assays were conducted on the promoter SNP, showing association with clinical outcomes. Twenty-one novel SNPs were identified. A promoter A>G SNP (rs2357928) was found to have significant interaction with treatment strategy for adverse cardiovascular outcomes (P for interaction, 0.002). In whites, rs2357928 GG patients randomized to CCB were more likely to experience an adverse outcome than those randomized to BB treatment strategy, with adjusted hazard ratio (HR) (CCB versus BB) of 2.35 (95% CI, 1.19 to 4.66; P=0.014). There was no evidence for such treatment difference in AG (HR, 1.16; 95% CI, 0.75 to 1.79; P=0.69) and AA (HR, 0.63; 95% CI, 0.36 to 1.11; P=0.11) patients. This finding was consistent in Hispanics and blacks. CACNB2 rs11014166 showed similar pharmacogenetic effect in Hispanics, but not in whites or blacks. Reporter assay analysis of rs2357928 showed a significant increase in promoter activity for the G allele compared to the A allele.

Conclusions— These data suggest that genetic variation within CACNB2 may influence treatment-related outcomes in high-risk patients with hypertension.

Clinical Trial Registration— URL: http://www.clinicaltrials.gov. Unique identifier: NCT00133692.

SOURCE:

Circulation: Cardiovascular Genetics.2010; 3: 548-555

doi: 10.1161/ CIRCGENETICS.110.957654

 

Hepatic Metabolism and Transporter Gene Variants Enhance Response to Rosuvastatin in Patients With Acute Myocardial Infarction

The GEOSTAT-1 Study

Kristian M. Bailey, MBChB, Simon P.R. Romaine, BSc, Beryl M. Jackson, RGN, Amanda J. Farrin, MSc, Maria Efthymiou, MSc, Julian H. Barth, MD, Joanne Copeland, BSc, Terry McCormack, MBBS, Andrew Whitehead, MSc, Marcus D. Flather, MBBS, Nilesh J. Samani, MD, FMedSci, Jane Nixon, PhD, Alistair S. Hall, MD, PhD, Anthony J. Balmforth, PhD and on behalf of the SPACE ROCKET Trial Group

Author Affiliations

From the Division of Cardiovascular and Diabetes Research (K.M.B., S.P.R.R., B.M.J., A.J.B.), and Division of Cardiovascular and Neuronal Remodelling (A.S.H.), Multidisciplinary Cardiovascular Research Centre, Leeds Institute of Genetics, Health and Therapeutics, University of Leeds, Leeds, United Kingdom; Clinical Trials Research Unit (A.J.F., M.E., J.C., J.N.), University of Leeds, Leeds, United Kingdom; Clinical Biochemistry (J.H.B.), Leeds General Infirmary, Leeds, United Kingdom; Whitby Group Practice (T.M.), Spring Vale Medical Centre, Whitby, North Yorkshire, United Kingdom; Pharmacy Department (A.W.), Leeds General Infirmary, Leeds, United Kingdom; Clinical Trials and Evaluation Unit (M.D.F.), Royal Brompton and Harefield NHS Trust and Imperial College, London, United Kingdom; and Department of Cardiovascular Sciences (N.J.S.), University of Leicester, Leicester, United Kingdom.

Correspondence to Alistair S. Hall, Clinical Cardiology, Multidisciplinary Cardiovascular Research Centre (MCRC), G Floor, Jubilee Building, Leeds General Infirmary, Leeds, LS1 3EX, United Kingdom. E-mail A.S.Hall@leeds.ac.uk

* Dr Bailey, Mr Romaine, Dr Hall, and Dr Balmforth contributed equally to this study.

Abstract

Background— Pharmacogenetics aims to maximize benefits and minimize risks of drug treatment. Our objectives were to examine the influence of common variants of hepatic metabolism and transporter genes on the lipid-lowering response to statin therapy.

Methods and Results— The Genetic Effects On STATins (GEOSTAT-1) Study was a genetic substudy of Secondary Prevention of Acute Coronary Events—Reduction of Cholesterol to Key European Targets (SPACE ROCKET) (a randomized, controlled trial comparing 40 mg of simvastatin and 10 mg of rosuvastatin) that recruited 601 patients after myocardial infarction. We genotyped the following functional single nucleotide polymorphisms in the genes coding for the cytochrome P450 (CYP) metabolic enzymes, CYP2C9*2 (430C>T), CYP2C9*3 (1075A>C), CYP2C19*2 (681G>A), CYP3A5*1 (6986A>G), and hepatic influx and efflux transporters SLCO1B1 (521T>C) and breast cancer resistance protein (BCRP; 421C>A). We assessed 3-month LDL cholesterol levels and the proportion of patients reaching the current LDL cholesterol target of <70 mg/dL (<1.81 mmol/L). An enhanced response to rosuvastatin was seen for patients with variant genotypes of either CYP3A5 (P=0.006) or BCRP (P=0.010). Furthermore, multivariate logistic-regression analysis revealed that patients with at least 1 variant CYP3A5 and/or BCRP allele (n=186) were more likely to achieve the LDL cholesterol target (odds ratio: 2.289; 95% CI: 1.157, 4.527; P=0.017; rosuvastatin 54.0% to target vs simvastatin 33.7%). There were no differences for patients with variants of CYP2C9, CYP2C19, or SLCO1B1 in comparison with their respective wild types, nor were differential effects on statin response seen for patients with the most common genotypes for CYP3A5 and BCRP (n=415; odds ratio: 1.207; 95% CI: 0.768, 1.899; P=0.415).

Conclusion— The LDL cholesterol target was achieved more frequently for the 1 in 3 patients with CYP3A5 and/or BCRP variant genotypes when prescribed rosuvastatin 10 mg, compared with simvastatin 40 mg.

Clinical Trial Registration— URL: http://isrctn.org. Unique identifier: ISRCTN 89508434.

SOURCE:

Circulation: Cardiovascular Genetics.2010; 3: 276-285

Published online before print March 5, 2010,

doi: 10.1161/ CIRCGENETICS.109.898502

 

Comprehensive Whole-Genome and Candidate Gene Analysis for Response to Statin Therapy in the Treating to New Targets (TNT) Cohort

John F. Thompson, PhD, Craig L. Hyde, PhD, Linda S. Wood, MS, Sara A. Paciga, MA, David A. Hinds, PhD, David R. Cox, MD, PhD, G. Kees Hovingh, MD, PhD and John J.P. Kastelein, MD, PhD

Author Affiliations

From the Helicos BioSciences (J.F.T.), Cambridge, Mass; Molecular Medicine (J.F.T., L.S.W., S.A.P.) and Statistical Applications (C.L.H.), Pfizer Global Research and Development, Groton, Conn; Perlegen Sciences (D.A.H., D.R.C.), Mountain View, Calif; and Department of Vascular Medicine (G.K.H., J.J.P.K.), Academic Medical Center, Amsterdam, The Netherlands.

Correspondence to John J.P. Kastelein, MD, PhD, Department of Vascular Medicine, Academic Medical Center, Meibergdreef 9, Room F4-159.2, 1105 AZ Amsterdam, The Netherlands. E-mail j.j.kastelein@amc.uva.nl or j.s.jansen@amc.uva.nl

Abstract

Background— Statins are effective at lowering low-density lipoprotein cholesterol and reducing risk of cardiovascular disease, but variability in response is not well understood. To address this, 5745 individuals from the Treating to New Targets (TNT) trial were genotyped in a combination of a whole-genome and candidate gene approach to identify associations with response to atorvastatin treatment.

Methods and Results— A total of 291 988 single-nucleotide polymorphisms (SNPs) from 1984 individuals were analyzed for association with statin response, followed by genotyping top hits in 3761 additional individuals. None was significant at the whole-genome level in either the initial or follow-up test sets for association with low-density lipoprotein cholesterol, high-density lipoprotein cholesterol, or triglyceride response. In addition to the whole-genome platform, 23 candidate genes previously associated with statin response were analyzed in these 5745 individuals. Three SNPs in apoE were most highly associated with low-density lipoprotein cholesterol response, followed by 1 in PCSK9 with a similar effect size. At the candidate gene level, SNPs in HMGCR were also significant though the effect was less than with those in apoE and PCSK9. rs7412/apoE had the most significant association (P=6×1030), and its high significance in the whole-genome study (P=4×109) confirmed the suitability of this population for detecting effects. Age and gender were found to influence low-density lipoprotein cholesterol response to a similar extent as the most pronounced genetic effects.

Conclusions— Among SNPs tested with an allele frequency of at least 5%, only SNPs in apoE are found to influence statin response significantly. Less frequent variants in PCSK9 and smaller effect sizes in SNPs in HMGCR were also revealed.

SOURCE:

Circulation: Cardiovascular Genetics.2009; 2: 173-181

Published online before print February 12, 2009,

doi: 10.1161/ CIRCGENETICS.108.818062

Summary

Larry H. Bernstein, MD, FCAP

This review has examined a compendium of well regarded documents drawn from 248 articles in Circulation Cardiovascular Genetics from March 2010 to March 2013. The large amount of evidence obtained from large population studies identifying Genome Wide Analysis Studies (GWAS) examines a host of cardiac and vascular diseases in which there is association between specific single nucleotide peptides (SNPs), and gene loci, that may play or have no significant role in developing heart disease. It certainly is evidence of the role that the American Heart Association has is in supporting the leading research today for tomorrow’s patients.   It is too early to sort them out, but it speaks to a large volume of discovery in this area.

It raises another issue that we have been confronted with mostly since the second half of the 20th century.  What is that issue?  The issue, it appears to me, is the vast improvements in analytical technology so that “imprecision” is far less likely to be a confounder in biological measurements and this lends access to far better accuracy?  But from that question arises another! Accuracy only refers to what is measured, but does it give us better ability to explain a complex and dynamic process?  In other words, what is what we are looking at representative of in manageable events?   I think that this is the most important idea that should come out of the recent criticism of the trajectory that molecular genetics been on in the last 5 years.

It was still in an era that “BIG’ science was not the normal.  One could spend an enormous effort at stepwise purification of a protein or enzyme, or other biomolecule starting with a slurry made from 100 lbs of “chicken heart”, for example.  These separations were based on negative charges on the molecules and positive charges on the column, and the molecules of no interest were eluted by gradient elution.  Much was learned about large scale preparation from small scale trials.  But this work was not undertaken without the intent to carry out a number of investigations to understand the “functionality” of a link in a metabolic pathway.  The studies that followed the purification required kinetic investigation with a coenzyme, or with a synthetically modified coenzyme, amino acid sequencing, NMR studies, etc.  You could not put together a “mechanism” without having the minimum amount of necessary information for a reliable account.  It is probably this requirement that led to today’s “BIG” science, that is founded upon multiple methods, now large data bases, and teams of investigators across institutions and continents.  The acquisition of knowledge has been astounding, but the integration of knowledge has not caught up.

However, let’s see if we can sort out the most meaningful signals from what I too am beginning to call the “noisy channel”.  As often happens, important areas of research are opened up that are followed by significant discovery and, in the long run, many other dead end publications that have no lasting significance.  In order to do justice to the work, I’ll pick through documents I find interesting, keeping in mind there is a hidden layer of complexity of which only sufficient information leads to a better understanding.  As much literature calls attention to, much of what ails us has nothing to do with classical Mendelian genetics, and has a postgenomic component.

The most fascinating aspect of this is the withering “dark matter” of the genome. While that component may be silent or expressed, the understanding comes at a higher observed order.  The dark became light! The expression became subtle, like weak bond interactions. The underlying organization is a component of the adaptive ability of an organism or individual in an environment with plants and animals in a changing climate, at particular altitudes, with given water supplies, with disease vectors, and with endogenous sources of essential nutrients.  This brings into focus the regulatory role of the genome as just as important a factor as transmission of the genetic code, especially in somatic cell populations.

The remainder of this discussion deals specifically with my observations on cardiovascular genomics. The following conclusion is appropriate, if incomplete, at this time on circulating miRNAs, particularly miR-133a:

  • elevated levels of circulating miR-133a in patients with cardiovascular diseases originate mainly from the injured myocardium.
  • Circulating miR-133a can be used as a marker for cardiomyocyte death, and

A number of articles that cite this article suggest that it may be useful for following disease progression:
Plasma microRNAs serve as biomarkers of therapeutic efficacy and disease progression in hypertension-induced heart failure  Eur J Heart Fail  2013

MicroRNAs Within the Continuum of Postgenomics Biomarker Discovery Arterio. Thromb. Vasc. Bio. 2013;33:206-214

“Need for Rigor in Design, Reporting, and Interpretation of Transcriptomic Biomarker Studies”  J. Clin. Microbiol.. 2012;50:4192-4193

Circulating microRNAs as diagnostic biomarkers for cardiovascular diseases. Am. J. Physiol. Heart Circ. Physiol.. 2012;303:H1085-H1095,

Circulating MicroRNAs: Novel Biomarkers and Extracellular Communicators in Cardiovascular Disease? Circ. Res.. 2012;110:483-495

Circulating MicroRNAs: Biomarkers or Mediators of Cardiovascular Diseases?  Arterioscler. Thromb. Vasc. Bio. 2011;31:2383-2390,

Circulating MicroRNA-208b and MicroRNA-499 Reflect Myocardial Damage in Cardiovascular Disease MF Corsten, R Dennert, S Jochem, T Kuznetsova,  et al.

The finding refers to an association that is related to the appearance of a miRNA in the circulation of patients with acute cardiac ischemia, and particular released into the circulation of patients from injured myocardium.  This finding has to be distinguished from a finding of another miRNA released with acute injury.  In the case of miR499 (and miR208b), there is a comparison with plasma cTnT, and an ROC curve is produced.

The List of this follows:

Circulation: Cardiovascular Genetics 2010; 3: 499-506

Strikingly, in plasma from

  • acute myocardial infarction patients, cardiac myocyte–associated miR-208b and -499 were highly elevated, 1600-fold (P<0.005) and 100-fold (P<0.0005), respectively, as compared with control subjects. Receiver operating characteristic curve analysis revealed an area under the curve of 0.94 (P<10−10) for miR-208b and 0.92 (P<10−9) for miR-499. Both microRNAs correlated with plasma troponin T, indicating release of microRNAs from injured cardiomyocytes.
  • In patients with acute heart failure, only miR-499 was significantly elevated (2-fold), whereas
  • no significant changes in microRNAs studied could be observed in diastolic dysfunction.

Remarkably, plasma microRNA levels were not affected by a wide range of clinical confounders, including

  • age,
  • sex,
  • body mass index,
  • kidney function,
  • systolic blood pressure, and
  • white blood cell count.

This is miRNA with a different twist.  It appears that there are 3 types found in AMI (133a, 208b, 409).  But type 499 alone is increased with acute heart failure (no mention of chronic cardiomyopathy and no effect of estimated GFR, or of age).

If the problem was just of AMI, then we have to know what this brings to the table.  As it is the hs-troponins have yet to be shown to effectively not only increase the high sensitivity of the tests, but to decrease the confusion generated by the elevation.  The enormous improvement of a test that may be superior to the hs-ctn’s is for the patient with very indeterminiate shortness of breath, a nondefinitive ECG, and in a prodromal phase of AMI.  This happened in the past, and it may happen now, and it may account for many cases of silent MI that were found at autopsy.

Cited by
Plasma microRNAs serve as biomarkers of therapeutic efficacy and disease progression in hypertension-induced heart failure Eur J Heart Fail. 2013;0:hft018v1-hft018,
Circulating microRNAs as diagnostic biomarkers for cardiovascular diseases Am. J. Physiol. Heart Circ. Physiol.. 2012;303:H1085-H1095,

Circulation Editors’ Picks: Most Read Articles in Cardiovascular Genetics Circulation. 2012;126:e163-e169,
MicroRNAs in Patients on Chronic Hemodialysis (MINOS Study) CJASN. 2012;7:619-623,

Novel techniques and targets in cardiovascular microRNA research Cardiovasc Res. 2012;93:545-554,

Microparticles: major transport vehicles for distinct microRNAs in circulation Cardiovasc Res. 2012;93:633-644,

Profiling of circulating microRNAs: from single biomarkers to re-wired networks Cardiovasc Res. 2012;93:555-562,

Small but smart–microRNAs in the centre of inflammatory processes during cardiovascular diseases, the metabolic syndrome, and ageing   Cardiovasc Res. 2012;93:605-613,

Circulation: Heart Failure Editors’ Picks: Most Important Papers in Pathophysiology and Genetics Circ Heart Fail. 2012;5:e32-e49

Use of Circulating MicroRNAs to Diagnose Acute Myocardial Infarction   Clin. Chem. 2012;58:559-567,

Circulating microRNAs to identify human heart failure   Eur J Heart Fail. 2012;14:118-119,

Next Steps in Cardiovascular Disease Genomic Research–Sequencing, Epigenetics, and Transcriptomics  Clin. Chem. 2012;58:113-126,

Most Read in Cardiovascular Genetics on Biomarkers, Inherited Cardiomyopathies and Arrhythmias, Metabolomics, and Genomics Circ Cardiovasc Genet. 2011;4:e24-e30,

MicroRNA-126 modulates endothelial SDF-1 expression and mobilization of Sca-1+/Lin- progenitor cells in ischaemia  Cardiovasc Res. 2011;92:449-455,

The use of genomics for treatment is another matter, and has several factors, e.g., age, residual function after AMI, comorbidities

This is a lot of interesting work that opens as many questions as it answers. The observations are real, and they lead to questions relating to the heart and the circulation.  Maybe it will generate answers to very tough issues concerning hypertension, renal disease and the heart.  It is far too early to tell.  It appears that we are about to hear a cacophony of miR’s in a symphony on cardiac and circulatory diseases not be be pieced together soon. But we have many more tools at our disposal than we did when Karmen discovered and made a distinction between

  • Aspartate and Alanine aminotransferases in the late 1950s, followed in the 1960s by
  • Creatine phosphokinase, the
  • MB-isoenzyme of CK by Sobel, Shell and Kjeckshus,
  • isoenzyme-1 of lactate dehydrogenase, and later the
  • Troponins,

leading to the programs to “reduce the extent of infarct damage”.  Then came the

  • a- and b-type natriuretic peptides,

which are still not fully understood in their role in congestive heart failure and in renal disease.

One item strikes the imagination as a fruitful area of further study.   Genetic Determinants of Potassium Sensitivity and Hypertension.    Integrated Computational and Experimental Analysis of the Neuroendocrine Transcriptome in Genetic Hypertension Identifies Novel Control Points for the Cardiometabolic Syndrome

Essential hypertension, a common complex disease, displays substantial genetic influence. Contemporary methods to dissect the genetic basis of complex diseases such as the genomewide association study are powerful, yet a large gap exists betweens the fraction of population trait variance explained by such associations and total disease heritability.

The researchers

  • developed a novel, integrative method (combining animal models, transcriptomics, bioinformatics, molecular biology, and trait-extreme phenotypes)
  • to identify candidate genes for essential hypertension and the metabolic syndrome.

Method  …  transcriptome profiling on adrenal glands from blood pressure extreme mouse strains:

  1. the hypertensive BPH (blood pressure high) and
  2. hypotensive BPL (blood pressure low).

Results….   Microarray data clustering revealed

  • underexpression of intermediary metabolism transcripts in HIGH BLOOD PRESSURE.
  • The MITRA algorithm identified a conserved motif in the transcriptional regulatory regions of the underexpressed metabolic genes,
  • They decide that regulation through this motif contributed to the global underexpression.
  • Luciferase reporter assays demonstrated transcriptional activity of the motif through transcription factors
    • HOXA3,
    • SRY, and
    •  YY1.

They finally hypothesized that genetic variation at HOXA3, SRY, and YY1 might predict blood pressure and other metabolic syndrome traits in humans. Tagging variants for each locus were associated with

  • blood pressure in a human population blood pressure extreme sample with
  • the most extensive associations for YY1 tagging single nucleotide polymorphism rs11625658 on
  1. systolic blood pressure,
  2. diastolic blood pressure,
  3. body mass index, and
  4. fasting glucose.

Meta-analysis extended the YY1 results into 2 additional large population samples with significant effects preserved on diastolic blood pressure, body mass index, and fasting glucose.

It will take much more of this beautiful integrative work to open up our imagination as to what physiological processes are occurring.

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