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Posts Tagged ‘Hebrew University of Jerusalem’

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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2013 American Cancer Research Association Award for Outstanding Achievement in Chemistry in Cancer Research: Professor Alexander Levitzki

Posted in Interviews with Scientific Leaders, Scientist: Career considerations, tagged , , , , , , on April 12, 2013| 4 Comments »

2013 American Cancer Research Association Award for Outstanding Achievement in Chemistry in Cancer Research: Professor Alexander Levitzki

Reporter: Aviva Lev-Ari, PhD, RN

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Professor Alexander Levitzki Chosen for American Cancer Research Association Award

April 7, 2013

Jerusalem — The American Association for Cancer Research (AACR) has chosen Professor Alexander Levitzki of The Hebrew University of Jerusalem as the winner of its 2013 Award for Outstanding Achievement in Chemistry in Cancer Research.

The AACR is currently holding its annual meeting through Wednesday in Washington, D.C. Alexander Levitzki, professor of biological chemistry at Hebrew University’Professor Alexander Levitzkis Alexander Silberman Institute of Life Sciences, will deliver his award lecture there on Tuesday afternoon on “Eradicating Tumors by Targeting Nonviral Vectors Carrying PolyIC.”

The AACR said that Professor Levitzki was chosen for the honor in recognition of his contributions to signal transduction therapy and his work on the development of tyrosine kinase inhibitors as effective agents against cancer. 

Professor Levitzki’s concept of targeted cancer therapy using protein tyrosine kinase inhibitors is extensively used by the pharmaceutical industry worldwide to develop anticancer drugs. His studies formed the basis for the development of drugs like imatinib, crizotinib and lapatinib, used for the treatment of patients with chronic myeloid leukemia, lung cancer and breast cancer, respectively. Currently there are more than 200 such inhibitors at various stages of the U.S. Food and Drug Administration’s approval process.

His method of large-scale screening of synthetic compounds tested against a large spectrum of protein kinases for specificity, followed by systematic testing in cell lines and animal studies, became the standard procedure in most of the laboratories working in that field.

Professor Levitzki has received numerous awards throughout his career, including

  • Israel Prize in Biochemistry, the
  • Wolf Prize for Medicine, the
  • Hamilton-Fairley Award from the European Society of Medical Oncology, the
  • Rothschild Prize in Biology and
  • two Prostate Cancer Foundation Research Awards. Last year he received the
  • Nauta Award in Pharmacochemistry, which is the highest award from the European Federation for Medicinal Chemistry.

He is a

He served as

  • President and vice president of the Federation of Israeli Societies of Experimental Biology and received an
  • honorary Ph.D. from Ben-Gurion University in Beersheba.

Professor Levitzki was a member of the scientific advisory board of Teva Pharmaceutical Industries and has served on the editorial board of several journals, including

 http://www.afhu.org/professor-alexander-levitizki-chosen-american-cancer-research-association-award

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Building blocks of the universe: Top physicists teach about early galaxy formation at Jerusalem Winter School in Theoretical Physics

Posted in Bio Instrumentation in Experimental Life Sciences Research, tagged , , , , , on January 17, 2013| Leave a Comment »

Reporters: Aviva Lev-Ari, PhD, RN

Press Release  1/1/2013

Building blocks of the universe: Top physicists teach about early galaxy formation at Jerusalem Winter School in Theoretical PhysicsHeaded by Nobel Laureate, ten day School runs December 31 to January 10

Galaxies in formation
Galaxies in formation

The 30th Jerusalem Winter School in Theoretical Physics opens on December 31 at the Israel Institute for Advanced Studies at the Hebrew University of Jerusalem. The topic this year is Early Galaxy Formation in LCDM Cosmology. One hundred students from around the world will participate in lectures and workshops by world-renowned experts in the field.

The 2004 Nobel Laureate in Physics and Hebrew University alumnus Prof. David Gross will head the school for the sixth time. Prof. Gross earned his bachelor’s degree in physics and mathematics from the Hebrew University of Jerusalem. He received the Nobel Prize for the discovery of asymptotic freedom in the theory of the strong interaction, the force operating between quarks.

Prof. Avishai Dekel, the Andre Aisenstadt Chair of Theoretical Physics at the Hebrew University’s Racah Institute of Physics, will manage the school with Prof. Reinhard Genzel from the Max Planck Institute for Extraterrestrial Physics. According to Prof. Dekel, ”Galaxy formation is the hot topic in physical cosmology today. Galaxies are the building blocks of the universe, and understanding the evolution of galaxies is an important step in understanding the formation of planets and life in the universe.”

Prof. Dekel is one of the world’s leading theoretical cosmologists. He developed the modern theory of galaxy evolution by flow of cold material from the cosmic fabric. In recent years he has focused on the early universe, one to five billion years after the Big Bang.

”The lectures at the school will start with the basics and reach the most advanced issues in current research,” added Prof. Dekel. “My research, for example, deals with a model for galaxy formation by streams of cold gas. This model replaces the hitherto accepted model, whereby the most influential process on galaxy evolution was clashes between galaxies.”

Professor Reinhard Genzel from the Max Planck Institute for Extraterrestrial Physics is one of the leading researchers in the subject of galaxy formation. He discovered the black hole at the center of the Milky Way Galaxy and he is one of the most prominent researchers of galaxies in the early universe. During the School he will talk about the evolution of galaxies.

The Winter School in Theoretical Physics takes place from 31 December to 10 January. All lectures are in English at the Israel Institute of Advanced Studies, Feldman Building, Edmond J. Safra campus in Givat Ram. Registration is required by email to shani@ias.huji.ac.il.

 
SOURCE:

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Calcium Regulation Key Mechanism Discovered: New Potential for Neuro-degenerative Diseases Drug Development

Posted in Alzheimer's Disease, Cell Biology, Signaling & Cell Circuits, Cerebrovascular and Neurodegenerative Diseases, Etiology, Pharmacotherapy and Cell Activity, tagged , , , , , , on January 17, 2013| 2 Comments »

Reporter: Aviva Lev-Ari, PhD, RN

 

Press Release

13 January, 2013

Hebrew University study finds key mechanism in calcium regulation.  The finding is important element in road towards development of new drugs for neurodegenerative diseases

LAB
LAB

All living cells keep their cellular calcium concentration at a very low level. Since a small increase in calcium can affect many critical cellular functions (an elevated calcium concentration over an extended period can induce cell death), powerful cellular mechanisms ensure that calcium concentration quickly returns to its low level.

It is known that impairments of cellular calcium regulation underlie almost all neurodegenerative diseases. For example, age-related loss of calcium regulation was shown to promote cell vulnerability in Alzheimer’s disease.

In a study recently published in the Journal of Neuroscience, Hebrew University of Jerusalem researchers, along with others from Israel and the US, presented their findings of a previously undescribed cellular mechanism which is essential for keeping cellular calcium concentration low. 
This mechanism operates together with other already characterized mechanisms.

Dr. Shirley Weiss and Prof. Baruch Minke of the Hebrew University’s Institute of Medical Research Israel-Canada (IMRIC) and the Edmond and Lily Safra Center for Brain Sciences (ELSC) characterized this mechanism using photoreceptor cells of the fruit fly, which is a powerful model for studying basic biological processes. 

They found that a protein-designated calphotin (a calcium buffer) operates by sequestering elevated calcium concentration. Genetic elimination of calphotin led to a light-induced rise in cellular calcium for an abnormally extended time, leading to retinal photoreceptor degeneration in the fruit flies.

The researchers stress that this kind of research, leading to a better understanding of the fundamental mechanisms underlying cellular calcium regulation, is critical for the development of new drugs and treatments for neurodegenerative diseases. 

SOURCE:

http://www.huji.ac.il/cgi-bin/dovrut/dovrut_search_eng.pl?mesge135806850705872560

 

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