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Lesson 9 Cell Signaling:  Curations and Articles of reference as supplemental information for lecture section on WNTs: #TUBiol3373

Stephen J. Wiilliams, Ph.D: Curator

UPDATED 4/23/2019

This has an updated lesson on WNT signaling.  Please click on the following and look at the slides labeled under lesson 10

cell motility 9b lesson_2018_sjw

Remember our lessons on the importance of signal termination.  The CANONICAL WNT signaling (that is the β-catenin dependent signaling)

is terminated by the APC-driven degradation complex.  This leads to the signal messenger  β-catenin being degraded by the proteosome.  Other examples of growth factor signaling that is terminated by a proteosome-directed include the Hedgehog signaling system, which is involved in growth and differentiation as well as WNTs and is implicated in various cancers.

A good article on the Hedgehog signaling pathway is found here:

The Voice of a Pathologist, Cancer Expert: Scientific Interpretation of Images: Cancer Signaling Pathways and Tumor Progression

All images in use for this article are under copyrights with Shutterstock.com

Cancer is expressed through a series of transformations equally involving metabolic enzymes and glucose, fat, and protein metabolism, and gene transcription, as a result of altered gene regulatory and transcription pathways, and also as a result of changes in cell-cell interactions.  These are embodied in the following series of graphics.

Figure 1: Sonic_hedgehog_pathwaySonic_hedgehog_pathway

The Voice of Dr. Larry

The figure shows a modification of nuclear translocation by Sonic hedgehog pathway. The hedgehog proteins have since been implicated in the development of internal organs, midline neurological structures, and the hematopoietic system in humans. The Hh signaling pathway consists of three main components: the receptor patched 1 (PTCH1), the seven transmembrane G-protein coupled receptor smoothened (SMO), and the intracellular glioma-associated oncogene homolog (GLI) family of transcription factors.5The GLI family is composed of three members, including GLI1 (gene activating), GLI2 (gene activating and repressive), and GLI3 (gene repressive).6 In the absence of an activating signal from either Shh, Ihh or Dhh, PTCH1 exerts an inhibitory effect on the signal transducer SMO, preventing any downstream signaling from occurring.7 When Hh ligands bind and activate PTCH1, the inhibition on SMO is released, allowing the translocation of SMO into the cytoplasm and its subsequent activation of the GLI family of transcription factors.

 

And from the review of  Elaine Y. C. HsiaYirui Gui, and Xiaoyan Zheng   Regulation of Hedgehog Signaling by Ubiquitination  Front Biol (Beijing). 2015 Jun; 10(3): 203–220.

the authors state:

Finally, termination of Hh signaling is also important for controlling the duration of pathway activity. Hh induced ubiquitination and degradation of Ci/Gli is the most well-established mechanism for limiting signal duration, and inhibiting this process can lead to cell patterning disruption and excessive cell proliferation (). In addition to Ci/Gli, a growing body of evidence suggests that ubiquitination also plays critical roles in regulating other Hh signaling components including Ptc, Smo, and Sufu. Thus, ubiquitination serves as a general mechanism in the dynamic regulation of the Hh pathway.

Overview of Hedgehog signaling showing the signal termination by ubiquitnation and subsequent degradation of the Gli transcriptional factors. obtained from Oncotarget 5(10):2881-911 · May 2014. GSK-3B as a Therapeutic Intervention in Cancer

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Note that in absence of Hedgehog ligands Ptch inhibits Smo accumulation and activation but upon binding of Hedgehog ligands (by an autocrine or paracrine fashion) Ptch is now unable to inhibit Smo (evidence exists that Ptch is now targeted for degradation) and Smo can now inhibit Sufu-dependent and GSK-3B dependent induced degradation of Gli factors Gli1 and Gli2.  Also note the Gli1 and Gli2 are transcriptional activators while Gli3 is a transcriptional repressor.

UPDATED 4/16/2019

Please click on the following links for the Powerpoint presentation for lesson 9.  In addition click on the mp4 links to download the movies so you can view them in Powerpoint slide 22:

cell motility 9 lesson_SJW 2019

movie file 1:

Tumorigenic but noninvasive MCF-7 cells motility on an extracellular matrix derived from normal (3DCntrol) or tumor associated (TA) fibroblasts.  Note that TA ECM is “soft” and not organized and tumor cells appear to move randomly if  much at all.

Movie 2:

 

Note that these tumorigenic and invasive MDA-MB-231 breast cancer cells move in organized patterns on organized ECM derived from Tumor Associated (TA) fibroblasts than from the ‘soft’ or unorganized ECM derived from normal  (3DCntrl) fibroblasts

 

The following contain curations of scientific articles from the site https://pharmaceuticalintelligence.com  intended as additional reference material  to supplement material presented in the lecture.

Wnts are a family of lipid-modified secreted glycoproteins which are involved in:

Normal physiological processes including

A. Development:

– Osteogenesis and adipogenesis (Loss of wnt/β‐catenin signaling causes cell fate shift of preosteoblasts from osteoblasts to adipocytes)

  – embryogenesis including body axis patterning, cell fate specification, cell proliferation and cell migration

B. tissue regeneration in adult tissue

read: Wnt signaling in the intestinal epithelium: from endoderm to cancer

And in pathologic processes such as oncogenesis (refer to Wnt/β-catenin Signaling [7.10]) and to your Powerpoint presentation

 

The curation Wnt/β-catenin Signaling is a comprehensive review of canonical and noncanonical Wnt signaling pathways

 

To review:

 

 

 

 

 

 

 

 

 

 

 

Activating the canonical Wnt pathway frees B-catenin from the degradation complex, resulting in B-catenin translocating to the nucleus and resultant transcription of B-catenin/TCF/LEF target genes.

Fig. 1 Canonical Wnt/FZD signaling pathway. (A) In the absence of Wnt signaling, soluble β-catenin is phosphorylated by a degradation complex consisting of the kinases GSK3β and CK1α and the scaffolding proteins APC and Axin1. Phosphorylated β-catenin is targeted for proteasomal degradation after ubiquitination by the SCF protein complex. In the nucleus and in the absence of β-catenin, TCF/LEF transcription factor activity is repressed by TLE-1; (B) activation of the canonical Wnt/FZD signaling leads to phosphorylation of Dvl/Dsh, which in turn recruits Axin1 and GSK3β adjacent to the plasma membrane, thus preventing the formation of the degradation complex. As a result, β-catenin accumulates in the cytoplasm and translocates into the nucleus, where it promotes the expression of target genes via interaction with TCF/LEF transcription factors and other proteins such as CBP, Bcl9, and Pygo.

NOTE: In the canonical signaling, the Wnt signal is transmitted via the Frizzled/LRP5/6 activated receptor to INACTIVATE the degradation complex thus allowing free B-catenin to act as the ultimate transducer of the signal.

Remember, as we discussed, the most frequent cancer-related mutations of WNT pathway constituents is in APC.

This shows how important the degradation complex is in controlling canonical WNT signaling.

Other cell signaling systems are controlled by protein degradation:

A.  The Forkhead family of transcription factors

Read: Regulation of FoxO protein stability via ubiquitination and proteasome degradation

B. Tumor necrosis factor α/NF κB signaling

Read: NF-κB, the first quarter-century: remarkable progress and outstanding questions

1.            Question: In cell involving G-proteins, the signal can be terminated by desensitization mechanisms.  How is both the canonical and noncanonical Wnt signal eventually terminated/desensitized?

We also discussed the noncanonical Wnt signaling pathway (independent of B-catenin induced transcriptional activity).  Note that the canonical and noncanonical involve different transducers of the signal.

Noncanonical WNT Signaling

Note: In noncanonical signaling the transducer is a G-protein and second messenger system is IP3/DAG/Ca++ and/or kinases such as MAPK, JNK.

Depending on the different combinations of WNT ligands and the receptors, WNT signaling activates several different intracellular pathways  (i.e. canonical versus noncanonical)

 

In addition different Wnt ligands are expressed at different times (temporally) and different cell types in development and in the process of oncogenesis. 

The following paper on Wnt signaling in ovarian oncogenesis shows how certain Wnt ligands are expressed in normal epithelial cells but the Wnt expression pattern changes upon transformation and ovarian oncogenesis. In addition, differential expression of canonical versus noncanonical WNT ligands occur during the process of oncogenesis (for example below the authors describe the noncanonical WNT5a is expressed in normal ovarian  epithelia yet WNT5a expression in ovarian cancer is lower than the underlying normal epithelium. However the canonical WNT10a, overexpressed in ovarian cancer cells, serves as an oncogene, promoting oncogenesis and tumor growth.

Wnt5a Suppresses Epithelial Ovarian Cancer by Promoting Cellular Senescence

Benjamin G. Bitler,1 Jasmine P. Nicodemus,1 Hua Li,1 Qi Cai,2 Hong Wu,3 Xiang Hua,4 Tianyu Li,5 Michael J. Birrer,6Andrew K. Godwin,7 Paul Cairns,8 and Rugang Zhang1,*

A.           Abstract

Epithelial ovarian cancer (EOC) remains the most lethal gynecological malignancy in the US. Thus, there is an urgent need to develop novel therapeutics for this disease. Cellular senescence is an important tumor suppression mechanism that has recently been suggested as a novel mechanism to target for developing cancer therapeutics. Wnt5a is a non-canonical Wnt ligand that plays a context-dependent role in human cancers. Here, we investigate the role of Wnt5a in regulating senescence of EOC cells. We demonstrate that Wnt5a is expressed at significantly lower levels in human EOC cell lines and in primary human EOCs (n = 130) compared with either normal ovarian surface epithelium (n = 31; p = 0.039) or fallopian tube epithelium (n = 28; p < 0.001). Notably, a lower level of Wnt5a expression correlates with tumor stage (p = 0.003) and predicts shorter overall survival in EOC patients (p = 0.003). Significantly, restoration of Wnt5a expression inhibits the proliferation of human EOC cells both in vitro and in vivo in an orthotopic EOC mouse model. Mechanistically, Wnt5a antagonizes canonical Wnt/β-catenin signaling and induces cellular senescence by activating the histone repressor A (HIRA)/promyelocytic leukemia (PML) senescence pathway. In summary, we show that loss of Wnt5a predicts poor outcome in EOC patients and Wnt5a suppresses the growth of EOC cells by triggering cellular senescence. We suggest that strategies to drive senescence in EOC cells by reconstituting Wnt5a signaling may offer an effective new strategy for EOC therapy.

Oncol Lett. 2017 Dec;14(6):6611-6617. doi: 10.3892/ol.2017.7062. Epub 2017 Sep 26.

Clinical significance and biological role of Wnt10a in ovarian cancer. 

Li P1Liu W1Xu Q1Wang C1.

Ovarian cancer is one of the five most malignant types of cancer in females, and the only currently effective therapy is surgical resection combined with chemotherapy. Wnt family member 10A (Wnt10a) has previously been identified to serve an oncogenic function in several tumor types, and was revealed to have clinical significance in renal cell carcinoma; however, there is still only limited information regarding the function of Wnt10a in the carcinogenesis of ovarian cancer. The present study identified increased expression levels of Wnt10a in two cell lines, SKOV3 and A2780, using reverse transcription-polymerase chain reaction. Functional analysis indicated that the viability rate and migratory ability of SKOV3 cells was significantly inhibited following Wnt10a knockdown using short interfering RNA (siRNA) technology. The viability rate of SKOV3 cells decreased by ~60% compared with the control and the migratory ability was only ~30% of that in the control. Furthermore, the expression levels of β-catenin, transcription factor 4, lymphoid enhancer binding factor 1 and cyclin D1 were significantly downregulated in SKOV3 cells treated with Wnt10a-siRNA3 or LGK-974, a specific inhibitor of the canonical Wnt signaling pathway. However, there were no synergistic effects observed between Wnt10a siRNA3 and LGK-974, which indicated that Wnt10a activated the Wnt/β-catenin signaling pathway in SKOV3 cells. In addition, using quantitative PCR, Wnt10a was overexpressed in the tumor tissue samples obtained from 86 patients with ovarian cancer when compared with matching paratumoral tissues. Clinicopathological association analysis revealed that Wnt10a was significantly associated with high-grade (grade III, P=0.031) and late-stage (T4, P=0.008) ovarian cancer. Furthermore, the estimated 5-year survival rate was 18.4% for patients with low Wnt10a expression levels (n=38), whereas for patients with high Wnt10a expression (n=48) the rate was 6.3%. The results of the present study suggested that Wnt10a serves an oncogenic role during the carcinogenesis and progression of ovarian cancer via the Wnt/β-catenin signaling pathway.

Targeting the Wnt Pathway includes curations of articles related to the clinical development of Wnt signaling inhibitors as a therapeutic target in various cancers including hepatocellular carcinoma, colon, breast and potentially ovarian cancer.

 

2.         Question: Given that different Wnt ligands and receptors activate different signaling pathways, AND  WNT ligands  can be deferentially and temporally expressed  in various tumor types and the process of oncogenesis, how would you approach a personalized therapy targeting the WNT signaling pathway?

3.         Question: What are the potential mechanisms of either intrinsic or acquired resistance to Wnt ligand antagonists being developed?

 

Other related articles published in this Open Access Online Scientific Journal include the following:

Targeting the Wnt Pathway [7.11]

Wnt/β-catenin Signaling [7.10]

Cancer Signaling Pathways and Tumor Progression: Images of Biological Processes in the Voice of a Pathologist Cancer Expert

e-Scientific Publishing: The Competitive Advantage of a Powerhouse for Curation of Scientific Findings and Methodology Development for e-Scientific Publishing – LPBI Group, A Case in Point 

Electronic Scientific AGORA: Comment Exchanges by Global Scientists on Articles published in the Open Access Journal @pharmaceuticalintelligence.com – Four Case Studies

 

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Colon Cancer

Author/Editor: Tilda Barliya PhD

 

Colorectal cancer is the third most common type of cancer diagnosed in the United States and is the third most common cause of cancer-related death. The majority of cases are sporadic, with hereditary colon cancer contributing up to 15% of all colon cancer diagnoses. Treatment consists of surgery for early-stage disease and the combination of surgery and adjuvant chemotherapy for advanced-stage disease. Management of metastatic disease has evolved from primary chemotherapeutic treatment to include resection of single liver and lung metastases in addition to resection of the primary disease and chemotherapy (1-4).

Courtesy WebMD site

In the United States, colorectal cancer (CRC) is the third most common type of cancer diagnosed and the third most common cause of cancer-related death in men and women. In 2010, an estimated 102,900 new cases of colon cancer were diagnosed (49,470 male, 53,430 female) and 51,370 patients (26,580 male, 24,790 female) died from CRC. The death rate from colon cancer decreased over the preceding decade, from 30.77 per 100,000 people to 20.5 per 100,000 people. The lifetime risk of developing colon cancer in industrialized nations is 5% and is stable or decreasing. In contrast, the incidence in developing countries continues to rise, hypothesized to be due to increased exposure to risk factors. It has been estimated that 1.5 million people in the United States will be living with CRC by 2020.The financial burden of caring for this population is significant: $4.5 to $9.6 billion per year.

Colon Cancer is divided into 5 types:

  1. Sporadic: 60-85%
  2. Familial: 10-30%
  3. Hereditary non-Polyposis Colon Cancer (HNPCC): 5%
  4. Familial Adenomatous Polyposis (FAP): 1%
  5. Autosomal Dominant Inheritance

The molecular defects are of two types:

  • alterations that lead to novel or increased function of oncogenes
  • alterations that lead to loss of function of tumor-suppressor genes (TSGs)

Multiple genes are associated with the initiation and progression of the different syndromes of colon cancer and are summarized by Fearon ER in Table 1 (6):

Table 1  Genetics of inherited colorectal tumor syndromesa
Syndrome Common features Gene defect(s)
FAP Multiple adenomatous polyps (>100) and carcinomas of the colon and rectum; duodenal polyps and carcinomas; fundic gland polyps in the stomach; congenital hypertrophy of retinal pigment epithelium APC (>90%)
Gardner syndrome Same as FAP; also, desmoid tumors and mandibular osteomas APC
Turcot’s syndrome Polyposis and colorectal cancer with brain tumors (medulloblastomas); colorectal cancer and brain tumors (glioblastoma) APC
MLH1PMS2
Attenuated adenomatous polyposis coli Fewer than 100 polyps, although marked variation in polyp number (from 5 to >1,000 polyps) observed in mutation carriers within a single family APC(predominantly 5′ mutations)
Hereditary nonpolyposis colorectal cancer Colorectal cancer without extensive polyposis; other cancers include endometrial, ovarian and stomach cancer, and occasionally urothelial, hepatobiliary, and brain tumors MSH2
MLH1
PMS2
GTBPMSH6
Peutz-Jeghers syndrome Hamartomatous polyps throughout the GI tract; mucocutaneous pigmentation; increased risk of GI and non-GI cancers LKB1STK11(30–70%)
Cowden disease Multiple hamartomas involving breast, thyroid, skin, central nervous system, and GI tract; increased risk of breast, uterus, and thyroid cancers; risk of GI cancer unclear PTEN (85%)
Juvenile polyposis syndrome Multiple hamartomatous/juvenile polyps with predominance in colon and stomach; variable increase in colorectal and stomach cancer risk; facial changes DPC4 (15%)
BMPR1a(25%)
PTEN (5%)
MYH-associated polyposis Multiple adenomatous GI polyps, autosomal recessive basis; colon polyps often have somatic KRAS mutations MYH

aAbbreviations: FAP, familial adenomatous polyposis; GI, gastrointestinal.

Essentially all of the genes discussed above are conclusively implicated in subsets of CRC due to specific somatic defects that either activate or inactivate gene and protein function. It is hypothesized that essentially any gene with dysregulated expression in CRC—either increased or decreased expression—may have a functionally significant role as an oncogene or a TSG, respectively. The aggregate data on the mutations and function of any given gene must be carefully evaluated to establish whether the gene truly contributes to CRC pathogenesis and whether it should be designated as an oncogene or a TSG (5,6).

The first proposed genetic model of CRC assumed that most CRCs arise from preexisting adenomatous lesions and that the accumulation of multiple gene defects is required for CRCs.

Benign GI tumors are a varied group, but localized lesions that project above the surrounding mucosa are commonly termed polyps. In humans, most colorectal polyps, particularly small polyps less than 5 mm in size, are hyperplastic (6). Most data indicate that hyperplastic polyps are not a major precursor to CRC; rather, the adenomatous polyp, or adenoma, is probably the important precursor lesion (7).

” Adenomas arise from glandular epithelium and are characterized by dysplastic morphology and altered differentiation of the epithelial cells in the lesion. The prevalence of adenomas in the United States is approximately 25% by age 50 and approximately 50% by age 70 (8)”. Only a fraction of adenomas progress to cancer, and progression probably occurs over years to decades. Individuals affected by syndromes that strongly predispose to adenomas, such as FAP, invariably develop CRCs by the third to fifth decade of life if their colons are not removed”.

A more recent and modified version of the genetic model postulate that each gene defect described in the model occurs at high frequency only at particular stages of tumor development. This observation is the basis for assigning a relative order to the defects in a multistep pathway.

Colon Cancer and clinical Trails:

Mutations in the KRAS proto-oncogene are found in 40-45% of patients with CRC and occur mainly in exon 2 (codon 12 and 13) and to a lesser extent in exon 3 (codon 61) and exon 4 (codon 146). A number of studies have evaluated a potential prognostic role of KRAS  in clinical practice for the treatment of colorectal cancer. However, clinical study design, reproducibility, interpretation and reporting of the clinical data remain important challenges.

Laurent-Puig’s group was the first to show the negative predictive value of KRAS mutations for response to the EGFR monoclonal antibody (mAb) cetuximab (11, 12, 13). Ever since then, a number of large phase II-III randomized studies have confirmed the negative predictive value of KRAS mutations for response to cetuximab and panitumumab treatment.

The role of KRAS mutations in predicting response to other therapies remains unclear. A subset analysis of patients treated in the phase III study of bevacizumab plus IFL (irinotecan, bolus 5-FU, and folinic acid) versus IFL showed that the clinical benefit of bevacizumab is independent of KRAS mutational status (11, 14).

The KRAS biomarker story is unique in several ways. It represents the first biomarker integrated into clinical practice in CRC“.

The high prevalence of KRAS mutations in CRC and its strong negative predictive value for EGFR mAb therapies, has led to its rapid acceptance as a valuable biomarker. The EMEA, FDA and ASCO47 now recommend that all patients with metastatic CRC who are candidates for anti-EGFR mAb therapy should be tested for KRAS mutations and, if a KRAS mutation in codon 12 or 13 is detected, then patients should not receive anti-EGFR antibody therapy.

More so, Data from the PETACC-3 trial, presented at ASCO 2010, have shown that KRAS and BRAF mutant CRC tumors induce different gene-expression profiles, further reiterating that these tumors have a distinct underlying biology. Despite intensive progress in the field of genomic research, none of these genomic markers are used routinely in clinical trials.  Only, nowadays, trials are starting to use specific gene-pathway” target in CRC clinical trials.

Samuel Constant et al. Colon Cancer: Current Treatments and Preclinical Models for the Discovery and Development of New Therapies

Summary:

Early studies are underway to understand the role of DNA methylation, chromatin modification, changes in the patterns of mRNA and noncoding RNA expression, and changes in protein expression and posttranslational modification. However,  we do not yet have an indepth and comprehensive understanding of the pathogenesis of the biologically and clinically distinct subsets of CRC. Careful design of clinical trials end points and validation of the genes as potential prognostic markers will allow a better outcome for these patients.

Ref:

1. Sarah Popek, MD, and Vassiliki Liana Tsikitis, MD. Colorectal Cancer: A Review. OncLive  November 10, 2011. http://www.onclive.com/publications/contemporary-oncology/2011/fall-2011/Colorectal-Cancer-A-Review

x. Martin Hefti.,  H.Maximilian Mehdorn., Ina Albert and Lutz Dörner. Fluorescence-Guided Surgery for Malignant Glioma: A Review on Aminolevulinic Acid Induced Protoporphyrin IX Photodynamic Diagnostic in Brain Tumors.  Current Medical Imaging Reviews, 2010, 6, 1-5. http://www.hirslanden.ch/content/global/en/startseite/gesundheit_medizin/mediathek_bibliothek/fachartikel/verschiedenes/fluorescence_guidedsurgeryformalignantglioma/_jcr_content/download/file.res/FluorescenceGuidedSurgeryforMalignantGlioma.pdf

2. Oguz Akin, Sandra B. Brennan., D. David Dershaw., Michelle S. Ginsberg., Marc J. Gollub., Heiko Sch€oder., David M. Panicek, and Hedvig Hricak. Advances in Oncologic Imaging: Update on 5 Common Cancers. CA CANCER J CLIN 2012;62:364–393. http://onlinelibrary.wiley.com/doi/10.3322/caac.21156/pdf

3. O’Donnell, Kevin et al. Nanoparticulate systems for oral drug delivery to the colon. International Journal of Nanotechnology, 2010, 8, 1/2, 4-20. “Colonic Navigation: Nanotechnology Helps Deliver Drugs to Intestinal Target”. http://www.sciencedaily.com/releases/2010/11/101104154553.htm

4. Perumal V. Molecular Therapy and Nanocarrier Based Drug Delivery to Colon Cancer: Targeted Molecular Therapy (AEE788 and Celecoxib) and Drug Delivery (Celecoxib) To Colon Cancer. http://www.amazon.com/Molecular-Therapy-Nanocarrier-Delivery-Cancer/dp/3659162558

5. Xiaoyun Liao, Paul Lochhead, Reiko Nishihara, Teppei Morikawa, Aya Kuchiba, Mai Yamauchi, Yu Imamura, Zhi Rong Qian, Yoshifumi Baba, Kaori Shima, Ruifang Sun, Katsuhiko Nosho, Jeffrey A. Meyerhardt, Edward Giovannucci, Charles S. Fuchs, Andrew T. Chan, Shuji Ogino. Aspirin Use, TumorPIK3CAMutation, and Colorectal-Cancer Survival. New England Journal of Medicine, 2012; 367 (17): 1596 DOI:10.1056/NEJMoa1207756http://www.ncbi.nlm.nih.gov/pmc/articles/PMC3532946/

Gene Mutation Identifies Colorectal Cancer Patients Who Live Longer With Aspirin Therapy. http://www.sciencedaily.com/releases/2012/10/121024175357.htm

6. Fearon ER. Molecular Genetics of Colorectal Cancer. Annual Review of Pathology: Mechanisms of Disease 2011; 6: 479-507.http://www.annualreviews.org/doi/pdf/10.1146/annurev-pathol-011110-130235

7.  Jass JR. 2007. Classification of colorectal cancer based on correlation of clinical, morphological and molecular features. Hisopathology 50:113–130. http://www.amedeoprize.com/ap/pdf/histopathology.pdf

8.  Rex DK, Lehman GA, Ulbright TM, Smith JJ, Pound DC, et al.  Colonic neoplasia in asymptomatic persons with negative fecal occult blood tests: influence of age, gender, and family history. Am. J. Gastroenterol 1993. 88:825–831.http://www.ncbi.nlm.nih.gov/pubmed/8503374

9. Kerber RA, Neklason DW, Samowitz WS, Burt RW. Frequency of familial colon cancer and hereditary nonpolyposis colorectal cancer (Lynch syndrome) in a large population database. Fam. Cancer 2005; 4:239–44. http://www.ncbi.nlm.nih.gov/pubmed/16136384

10. Kinzler KW, Vogelstein B. Lessons from hereditary colorectal cancer. Cell 1996: 87:159–170. http://users.ugent.be/~fspelema/les%204-5%20HMG/kinzler%20clon.pdf

11. Sandra Van Schaeybroeck, Wendy L. Allen, Richard C. Turkington & Patrick G. Johnston. Implementing prognostic and predictive biomarkers in CRC clinical trials.(colorectal cancer)(Clinical report). Nature Reviews Clinical Oncology 2011: 8; 222-232. http://www.nature.com/nrclinonc/journal/v8/n4/abs/nrclinonc.2011.15.html

12. Lievre, A. et al. KRAS mutation status is predictive of response to cetuximab therapy in colorectal cancer. Cancer Res. 66 2006: 3992-3995. http://hwmaint.cancerres.aacrjournals.org/cgi/content/full/66/8/3992

13. Lievre, A. et al. KRAS mutations as an independent prognostic factor in patients with advanced colorectal cancer treated with cetuximab. J. Clin. Oncol. 2008: 26, 374-379. http://jco.ascopubs.org/content/26/3/374.full.pdf

14. Hurwitz, H. I., Yi, J., Ince, W., Novotny, W. F. & Rosen, O. The clinical benefit of bevacizumab in metastatic colorectal cancer is independent of K-ras mutation status: analysis of a phase III study of bevacizumab with chemotherapy in previously untreated metastatic colorectal cancer. Oncologist  2009: 14, 22-28. http://theoncologist.alphamedpress.org/content/14/1/22.full

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

I. By: Aviva Lev-Ari, PhD, RNCancer Genomic Precision Therapy: Digitized Tumor’s Genome (WGSA) Compared with Genome-native Germ Line: Flash-frozen specimen and Formalin-fixed paraffin-embedded Specimen Needed. https://pharmaceuticalintelligence.com/2013/04/21/cancer-genomic-precision-therapy-digitized-tumors-genome-wgsa-compared-with-genome-native-germ-line-flash-frozen-specimen-and-formalin-fixed-paraffin-embedded-specimen-needed/

II. By: Aviva Lev-Ari, PhD, RN. Critical Gene in Calcium Reabsorption: Variants in the KCNJ and SLC12A1 genes – Calcium Intake and Cancer Protection. https://pharmaceuticalintelligence.com/2013/04/12/critical-gene-in-calcium-reabsorption-variants-in-the-kcnj-and-slc12a1-genes-calcium-intake-and-cancer-protection/

III.  By: Stephen J. Williams, Ph.DIssues in Personalized Medicine in Cancer: Intratumor Heterogeneity and Branched Evolution Revealed by Multiregion Sequencing. https://pharmaceuticalintelligence.com/2013/04/10/issues-in-personalized-medicine-in-cancer-intratumor-heterogeneity-and-branched-evolution-revealed-by-multiregion-sequencing/

IV. By: Ritu Saxena, Ph.DIn Focus: Targeting of Cancer Stem Cells. https://pharmaceuticalintelligence.com/2013/03/27/in-focus-targeting-of-cancer-stem-cells/

V.  By: Ziv Raviv PhD. Cancer Screening at Sourasky Medical Center Cancer Prevention Center in Tel-Aviv. https://pharmaceuticalintelligence.com/2013/03/25/tel-aviv-sourasky-medical-center-cancer-prevention-center-excellent-example-for-adopting-prevention-of-cancer-as-a-mean-of-fighting-it/

VI. By: Ritu Saxena, PhD. In Focus: Identity of Cancer Stem Cells. https://pharmaceuticalintelligence.com/2013/03/22/in-focus-identity-of-cancer-stem-cells/

VII. By: Dror Nir, PhD. State of the art in oncologic imaging of Colorectal cancers. https://pharmaceuticalintelligence.com/2013/02/02/state-of-the-art-in-oncologic-imaging-of-colorectal-cancers/

Other posts by the group: Please see https://pharmaceuticalintelligence.com/?s=colon+cancer

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Coagulation: Transition from a familiar model tied to Laboratory Testing, and the New Cellular-driven Model


Coagulation: Transition from a familiar model tied to Laboratory Testing, and the New Cellular-driven Model

 

Curator: Larry H. Bernstein, MD, FCAP 

Short Title: Coagulation viewed from Y to cellular biology.

PART I.

Summary: This portion of the series on PharmaceuticalIntelligence(wordpress.com) isthe first of a three part treatment of the diverse effects on platelets, the coagulation cascade, and protein-membrane interactions.  It is highly complex as the distinction between intrinsic and extrinsic pathways become blurred as a result of  endothelial shear stress, distinctly different than penetrating or traumatic injury.  In addition, other factors that come into play are also considered.  The second part will be directed toward low flow states, local and systemic inflammatory disease, oxidative stress, and hematologic disorders, bringing NO and the role of NO synthase in the process.   A third part will be focused on management of these states.

Coagulation Pathway

The workhorse tests of the modern coagulation laboratory, the prothrombin time (PT) and the activated partial thromboplastin time (aPTT), are the basis for the published extrinsic and intrinsic coagulation pathways.  This is, however, a much simpler model than one encounters delving into the mechanism and interactions involved in hemostasis and thrombosis, or in hemorrhagic disorders.

We first note that there are three components of the hemostatic system in all vertebrates:

  • Platelets,
  • vascular endothelium, and
  • plasma proteins.

The liver is the largest synthetic organ, which synthesizes

  • albumin,
  • acute phase proteins,
  • hormonal and metal binding proteins,
  • albumin,
  • IGF-1, and
  • prothrombin, mainly responsible for the distinction between plasma and serum (defibrinated plasma).

According to WH Seegers [Seegers WH,  Postclotting fates of thrombin.  Semin Thromb Hemost 1986;12(3):181-3], prothrombin is virtually all converted to thrombin in clotting, but Factor X is not. Large quantities of thrombin are inhibited by plasma and platelet AT III (heparin cofactor I), by heparin cofactor II, and by fibrin.  Antithrombin III, a serine protease, is a main inhibitor of thrombin and factor Xa in blood coagulation. The inhibitory function of antithrombin III is accelerated by heparin, but at the same time antithrombin III activity is also reduced. Heparin retards the thrombin-fibrinogen reaction, but otherwise the effectiveness of heparin as an anticoagulant depends on antithrombin III in laboratory experiments, as well as in therapeutics. The activation of prothrombin is inhibited, thereby inactivating  any thrombin or other vulnerable protease that might otherwise be generated. [Seegers WH, Antithrombin III. Theory and clinical applications. H. P. Smith Memorial Lecture. Am J Clin Pathol. 1978;69(4):299-359)].  With respect to platelet aggregation, platelets aggregate with thrombin-free autoprothrombin II-A. Aggregation is dependent on an intact release mechanism since inhibition of aggregation occurred with adenosine, colchicine, or EDTA. Autoprothrombin II-A reduces the sensitivity of platelets to aggregate with thrombin, but enhances epinephrine-mediated aggregation. [Herman GE, Seegers WH, Henry RL. Autoprothrombin ii-a, thrombin, and epinephrine: interrelated effects on platelet aggregation. Bibl Haematol 1977;44:21-7.]

A tetrapeptide, residues 6 to 9 in normal prothrombin, was isolated from the NH(2)-terminal, Ca(2+)-binding part of normal prothrombin. The peptide contained two residues of modified glutamic acid, gamma-carboxyglutamic acid. This amino acid gives normal prothrombin the Ca(2+)-binding ability that is necessary for its activation.

Abnormal prothrombin, induced by the vitamin K antagonist, dicoumarol, lacks these modified glutamic acid residues and that this is the reason why abnormal prothrombin does not bind Ca(2+) and is nonfunctioning in blood coagulation. [Stenflo J, Fernlund P, Egan W, Roepstorff P. Vitamin K dependent modifications of glutamic acid residues in prothrombin.  Proc Natl Acad Sci U S A. 1974;71(7):2730-3.]

Interestingly, a murine monoclonal antibody (H-11) binds a conserved epitope found at the amino terminal of the vitamin K-dependent blood proteins prothrombin, factors VII and X, and protein C. The sequence of polypeptide recognized contains 2 residues of gamma-carboxyglutamic acid, and binding of the antibody is inhibited by divalent metal ions.  The antibody bound specifically to a synthetic peptide corresponding to residues 1-12 of human prothrombin that was synthesized as the gamma-carboxyglutamic acid-containing derivative, but binding to the peptide was not inhibited by calcium ion. This suggested that binding by divalent metal ions is not due simply to neutralization of negative charge by Ca2+. [Church WR, Boulanger LL, Messier TL, Mann KG. Evidence for a common metal ion-dependent transition in the 4-carboxyglutamic acid domains of several vitamin K-dependent proteins. J Biol Chem. 1989;264(30):17882-7.]

Role of vascular endothelium.

I have identified the importance of prothrombin, thrombin, and the divalent cation Ca 2+ (1% of the total body pool), mention of heparin action, and of vitamin K (inhibited by warfarin).  Endothelial functions are inherently related to procoagulation and anticoagulation. The subendothelial matrix is a complex of many materials, most important related to coagulation being collagen and von Willebrand factor.

What about extrinsic and intrinsic pathways?  Tissue factor, when bound to factor VIIa, is the major activator of the extrinsic pathway of coagulation. Classically, tissue factor is not present in the plasma but only presented on cell surfaces at a wound site, which is “extrinsic” to the circulation.  Or is it that simple?

Endothelium is the major synthetic and storage site for von Willebrand factor (vWF).  vWF is…

  • secreted from the endothelial cell both into the plasma and also
  • abluminally into the subendothelial matrix, and
  • acts as the intercellular glue binding platelets to one another and also to the subendothelial matrix at an injury site.
  • acts as a carrier protein for factor VIII (antihemophilic factor).
  • It  binds to the platelet glycoprotein Ib/IX/V receptor and
  • mediates platelet adhesion to the vascular wall under shear. [Lefkowitz JB. Coagulation Pathway and Physiology. Chapter I. in Hemostasis Physiology. In ( ???), pp1-12].

Ca++ and phospholipids are necessary for all of the reactions that result in the activation of prothrombin to thrombin. Coagulation is initiated by an extrinsic mechanism that

  • generates small amounts of factor Xa, which in turn
  • activates small amounts of thrombin.

The tissue factor/factorVIIa proteolysis of factor X is quickly inhibited by tissue factor pathway inhibitor (TFPI).The small amounts of thrombin generated from the initial activation feedback

  • to create activated cofactors, factors Va and VIIIa, which in turn help to
  • generate more thrombin.
  • Tissue factor/factor VIIa is also capable of indirectly activating factor X through the activation of factor IX to factor IXa.
  • Finally, as more thrombin is created, it activates factor XI to factor XIa, thereby enhancing the ability to ultimately make more thrombin.

 

Coagulation cascade

Coagulation cascade (Photo credit: Wikipedia)

Coagulation Cascade

The procoagulant plasma coagulation cascade has traditionally been divided into the intrinsic and extrinsic pathways. The Waterfall/Cascade model consists of two separate initiations,

  • intrinsic (contact)and
    • The intrinsic pathway is initiated by a complex activation process of the so-called contact phase components,
      • prekallikrein,
      • high-molecular weight kininogen (HMWK) and
      • factor XII

Activation of the intrinsic pathway is promoted by non-biological surfaces, such as glass in a test tube, and is probably not of physiological importance, at least not in coagulation induced by trauma.

Instead, the physiological activation of coagulation is mediated exclusively via the extrinsic pathway, also known as the tissue factor pathway.

  • extrinsic pathways

Tissue factor (TF) is a membrane protein which is normally found in tissues. TF forms a procoagulant complex with factor VII, which activates factor IX and factor X.

  • common pathway which ultimately merge at the level of Factor Xa

Regulation of thrombin generation. Coagulation is triggered (initiation) by circulating trace amounts of fVIIa and locally exposed tissue factor (TF). Subsequent formations of fXa and thrombin are regulated by a tissue factor pathway inhibitor (TFPI) and antithrombin (AT). When the threshold level of thrombin is exceeded, thrombin activates platelets, fV, fVIII, and fXI to augment its own generation (propagation).

Activated factors IX and X (IXa and Xa) will activate prothrombin to thrombin and finally the formation of fibrin. Several of these reactions are much more efficient in the presence of phospholipids and protein cofactors factors V and VIII, which thrombin activates to Va and VIIIa by positive feedback reactions.

We depict the plasma coagulation emphasizing the importance of membrane surfaces for the coagulation processes. Coagulation is initiated when tissue factor (TF), an integral membrane protein, is exposed to plasma. TF is expressed on subendothelial cells (e.g. smooth muscle cells and fibroblasts), which are exposed after endothelium damage. Activated monocytes are also capable of exposing TF.

A small amount, approximately 1%, of activated factor VII (VIIa) is present in circulating blood and binds to TF. Free factor VIIa has poor enzymatic activity and the initiation is limited by the availability of its cofactor TF. The first steps in the formation of a blood clot is the specific activation of factor IX and X by the TF-VIIa complex. (Initiation of coagulation: Factor VIIa binds to tissue factor and activates factors IX and X). Coagulation is propagated by procoagulant enzymatic complexes that assemble on the negatively charged membrane surfaces of activated platelets. (Propagation of coagulation: Activation of factor X and prothrombin).  Once thrombin has been formed it will activate the procofactors, factor V and factor VIII, and these will then assemble in enzyme complexes. Factor IXa forms the tenase complex together with its cofactor factor VIIIa, and factor Xa is the enzymatic component of the prothrombinase complex with factor Va as cofactor.

Activation of protein C takes place on the surface of intact endothelial cells. When thrombin (IIa) reaches intact endothelium it binds with high affinity to a specific receptor called thrombomodulin. This shifts the specific activity of thrombin from being a procoagulant enzyme to an anticoagulant enzyme that activates protein C to activated protein C (APC).  The localization of protein C to the thrombin-thrombomodulin complex can be enhanced by the endothelial protein C receptor (EPCR), which is a transmembrane protein with high affinity for protein C.  Activated protein C (APC) binds to procoagulant surfaces such as the membrane of activated platelets where it finds and degrades the procoagulant cofactors Va and VIIIa, thereby shutting down the plasma coagulation.  Protein S (PS) is an important nonenzymatic  cofactor to APC in these reactions. (Degradation of factors Va and VIIIa).

Blood Coagulation (Thrombin) and Protein C Pat...

Blood Coagulation (Thrombin) and Protein C Pathways (Blood_Coagulation_and_Protein_C_Pathways.jpg) (Photo credit: Wikipedia)

The common theme in activation and regulation of plasma coagulation is the reduction in dimensionality. Most reactions take place in a 2D world that will increase the efficiency of the reactions dramatically. The localization and timing of the coagulation processes are also dependent on the formation of protein complexes on the surface of membranes. The coagulation processes can also be controlled by certain drugs that destroy the membrane binding ability of some coagulation proteins – these proteins will be lost in the 3D world and not able to form procoagulant complexes on surfaces.

Activated protein C resistance

Activated protein C resistance (Photo credit: Wikipedia)

Assembly of proteins on membranes – making a 3D world flat

  • The timing and efficiency of coagulation processes are handled by reduction in dimensionality
  • – Make 3 dimensions to 2 dimensions
  • Coagulation proteins have membrane binding capacity
  • Membranes provide non-coagulant and procoagulant surfaces
  • – Intact cells/activated cells
  • Membrane binding is a target for anticoagulant drugs
  • – Anti-vitamin K (e.g. warfarin)

Modern View

It can be divided into the phases of initiation, amplification and propagation.

  • In the initiation phase, small amounts of thrombin can be formed after exposure of tissue factor to blood.
  • In the amplification phase, the traces of thrombin will be inactivated or used for amplification of the coagulation process.

At this stage there is not enough thrombin to form insoluble fibrin. In order to proceed further thrombin  activates platelets, which provide a procoagulant surface for the coagulation factors. Thrombin will also activate the vital cofactors V and VIII that will assemble on the surface of activated platelets. Thrombin can also activate factor XI, which is important in a feedback mechanism.

In the final step, the propagation phase, the highly efficient tenase and prothrombinase complexes have been assembled on the membrane surface. This yields large amounts of thrombin at the site of injury that can cleave fibrinogen to insoluble fibrin. Factor XI activation by thrombin then activates factor IX, which leads to the formation of more tenase complexes. This ensures enough thrombin is formed, despite regulation of the initiating TF-FVIIa complex, thus ensuring formation of a stable fibrin clot. Factor XIII stabilizes the fibrin clot through crosslinking when activated by thrombin.

Platelet Aggregation

The activities of adenylate and guanylate cyclase and cyclic nucleotide 3′:5′-phosphodiesterase were determined during the aggregation of human blood platelets with

  • thrombin, ADP
  • arachidonic acid and
  • epinephrine

[Aggregation is dependent on an intact release mechanism since inhibition of aggregation occurred with adenosine, colchicine, or EDTA.  (Herman GE, Seegers WH, Henry RL. Autoprothrombin ii-a, thrombin, and epinephrine: interrelated effects on platelet aggregation. Bibl Haematol 1977;44:21-7)].

The activity of guanylate cyclase is altered to a much larger degree than adenylate cyclase, while cyclic nucleotide phosphodiesterase activity remains unchanged. During the early phases of thrombin- and ADP-induced platelet aggregation a marked activation of the guanylate cyclase occurs whereas aggregation induced by arachidonic acid or epinephrine results in a rapid diminution of this activity. In all four cases, the adenylate cyclase activity is only slightly decreased when examined under identical conditions.

Platelet aggregation induced by a wide variety of aggregating agents including collagen and platelet isoantibodies results in the “release” of only small amounts (1–3%) of guanylate cyclase and cyclic nucleotide phosphodiesterase and no adenylate cyclase. The guanylate cyclase and cyclic nucleotide phosphodiesterase activities are associated almost entirely with the soluble cytoplasmic fraction of the platelet, while the adenylate cyclase is found exclusively in a membrane bound form. ADP and epinephrine moderately inhibit guanylate and adenylate cyclase in subcellular preparations, while arachidonic and other unsaturated fatty acids moderately stimulate (2–4-fold) the former.

  1. The platelet guanylate cyclase activity during aggregation depends on the nature and mode of action of the inducing agent.
  2. The membrane adenylate cyclase activity during aggregation is independent of the aggregating agent and is associated with a reduction of activity and
  3. Cyclic nucleotide phosphodiesterase remains unchanged during the process of platelet aggregation and release.

Furthermore, these observations suggest a role for unsaturated fatty acids in the control of intracellular cyclic GMP levels. Arachidonic acid, once deemed essential, is a derivative of linoleic acid. (Barbera AJ. Cyclic nucleotides and platelet aggregation effect of aggregating agents on the activity of cyclic nucleotide-metabolizing enzymes. Biochimica et Biophysica Acta (BBA) 1976; 444 (2): 579–595. http://dx.doi.org/10.1016/0304-4165(76)90402-5).

Leukocyte and platelet adhesion under flow

The basic principles concerning mechanical stress demonstrated by Robert Hooke (1635-1703) proved to be essential for the understanding of pathophysiological mechanisms in the vascular bed.

In physics, stress is the internal distribution of forces within a body that balance and react to the external loads applied to it. Stress is a 2nd order tensor. The hemodynamic conditions inside blood vessels lead to the development of superficial stresses near the vessel walls, which can be divided into two categories:

a) circumferential stress due to pulse pressure variation inside the vessel;

b) shear stress due to blood flow.

The direction of the shear stress vector is determined by the direction of the blood flow velocity vector very close to the vessel wall. Shear stress is applied by the blood against the vessel wall. Friction is the force applied by the wall to the blood and has a direction opposite to the blood flow. The tensions acting against the vessel wall are likely to be determined by blood flow conditions. Shear stresses are most complicated during turbulent flow, regions of flow recirculation or flow separation.

The notions of shear rate and fluid viscosity should be first clearly apprehended, since they are crucial for the assessment and development of shear stress. Shear rate is defined as the rate at which adjacent layers of fluid move with respect to each other, usually expressed as reciprocal seconds. The size of the shear rate gives an indication of the shape of the velocity profile for a given situation.  The determination of shear stresses on a surface is based on the fundamental assumption of fluid mechanics, according to which the velocity of fluid upon the surface is zero (no-slip condition). Assuming that the blood is an ideal Newtonian fluid with constant viscosity, the flow is steady and laminar and the vessel is straight, cylindrical and inelastic, which is not the case. Under ideal conditions a parabolic velocity profile could be assumed.

The following assumptions have been made:

  1. The blood is considered as a Newtonian fluid.
  2. The vessel cross sectional area is cylindrical.
  3. The vessel is straight with inelastic walls.
  4. The blood flow is steady and laminar.

The Haagen-Poisseuille equation indicates that shear stress is directly proportional to blood flow rate and inversely proportional to vessel diameter.

Viscosity is a property of a fluid that offers resistance to flow, and it is a measure of the combined effects of adhesion and cohesion. It increases as temperature decreases. Blood viscosity (non-Newtonian fluid) depends on shear rate, which is determined by blood platelets, red cells, etc. Moreover, it is slightly affected by shear rate changes at low levels of hematocrit. In contrast, as hematocrit increases, the effect of shear rate changes on blood viscosity becomes greater. Blood viscosity measurement is required for the accurate calculation of shear stress in veins or microcirculation.

It has to be emphasised that the dependence of blood viscosity on hematocrit is more pronounced in the microcirculation than in larger vessels, due to hematocrit variations observed in small vessels (lumen diameter <100 Ìm). The significant change of hematocrit in relation to vessel diameter is associated with the tendencyof red blood cells to travel closer to the centre of the vessels. Thus, the greater the decrease in vessel lumen, the smaller the number of red blood cells that pass through, resulting in a decrease in blood viscosity.

Shear stress and vascular endothelium

Endothelium responds to shear stress through various pathophysiological mechanisms depending on the kind and the magnitude of shear stresses. More specifically, the exposure of vascular endothelium to shear forces in the normal value range stimulates endothelial cells to release agents with direct or indirect antithrombotic properties, such as prostacyclin, nitric oxide (NO), calcium, thrombomodulin, etc.  The possible existence of so-called “mechanoreceptors” has provoked a number of research groups to propose receptors which “translate” mechanical forces into biological signals.

Under normal shear conditions, endothelial as well as smooth muscle cells have a rather low rate of proliferation. Changes in shear stress magnitude activate cellular proliferation mechanisms as well as vascular remodeling processes. More specifically, a high grade of shear stress increases wall thickness and expands the vessel’s diameter, so that shear stress values return to their normal values. In contrast, low shear stress induces a reduction in vessel diameter. Shear stresses stimulate vasoregulatory mechanisms which, together with alterations of arterial diameter, serves to maintain a mean shear stress level of about 15 dynes/cm2. The presence of low shear stresses is frequently accompanied by unstable flow conditions (e.g. turbulence flow, regions of blood recirculation, “stagnant” blood areas).

(Papaioannou TG, Stefanadis C. Vascular Wall Shear Stress: Basic Principles and Methods. Hellenic J Cardiol 2005; 46: 9-15.)

Leukocyte adhesion under flow in the microvasculature is mediated by binding between cell surface receptors and complementary ligands expressed on the surface of the endothelium. Leukocytes adhere to endothelium in a two-step mechanism: rolling (primarily mediated by selectins) followed by firm adhesion (primarily mediated by integrins). These investigators simulated the adhesion of a cell to a surface in flow, and elucidated the relationship between receptor–ligand functional properties and the dynamics of adhesion using a computational method called ‘‘Adhesive Dynamics.’’ This relationship was expressed in a one-to-one map between the biophysical properties of adhesion molecules and various adhesive behaviors.

Behaviors that are observed in simulations include firm adhesion, transient adhesion (rolling), and no adhesion. They varied the dissociative properties, association rate, bond elasticity, and shear rate and found that the unstressed dissociation rate, kro, and the bond interaction length, γ, are the most important molecular properties controlling the dynamics of adhesion.

(Chang KC, Tees DFJ and Hammer DA. The state diagram for cell adhesion under flow: Leukocyte rolling and firm adhesion. PNAS 2000; 97(21):11262-11267.)

The study of the effect of leukocyte adhesion on blood flow in small vessels is of primary interest to understand the resistance changes in venular microcirculation when blood is considered as a homogeneous Newtonian fluid. When studying the effect of leukocyte adhesion on the non-Newtonian Casson fluid flow of blood in small venules; the Casson model represents the effect of red blood cell aggregation. In this model the blood vessel is considered as a circular cylinder and the leukocyte is considered as a truncated spherical protrusion in the inner side of the blood vessel. Numerical simulations demonstrated that for a Casson fluid with hematocrit of 0.4 and flow rate Q = 0:072 nl/s, a single leukocyte increases flow resistance by 5% in a 32 m diameter and 100 m long vessel. For a smaller vessel of 18 m, the flow resistance increases by 15%.

(Das B, Johnson PC, and Popel AS. Computational fluid dynamic studies of leukocyte adhesion effects on non-Newtonian blood flow through microvessels. Biorheology  2000; 37:239–258.)

Biologists have identified many of the molecular constituents that mediate adhesive interactions between white blood cells, the cell layer that lines blood vessels, blood components, and foreign bodies. However, the mechanics of how blood cells interact with one another and with biological or synthetic surfaces is quite complex: owing to the deformability of cells, the variation in vessel geometry, and the large number of competing chemistries present (Lipowski et al., 1991, 1996).

Adhesive interactions between white blood cells and the interior surface of the blood vessels they contact is important in inflammation and in the progression of heart disease. Parallel-plate microchannels have been useful in characterizing the strength of these interactions, in conditions that are much simplified over the complex environment these cells experience in the body. Recent computational and experimental work by several laboratories have attempted to bridge this gap between behavior observed in flow chamber experiments, and cell surface interactions observed in the microvessels of anesthetized animals.

We have developed a computational simulation of specific adhesive interactions between cells and surfaces under flow. In the adhesive dynamics formulation, adhesion molecules are modeled as compliant springs. One well-known model used to describe the kinetics of single biomolecular bond failure is due to Bell, which relates the rate of dissociation kr to the magnitude of the force on the bond F. The rate of formation directly follows from the Boltzmann distribution for affinity. The expression for the binding rate must also incorporate the effect of the relative motion of the two surfaces. Unless firmly adhered to a surface, white blood cells can be effectively modeled as rigid spherical particles, as evidenced by the good agreement between bead versus cell in vitro experiments (Chang and Hammer, 2000).

Various in vitro, in vivo, and computational methods have been developed to understand the complex range of transient interactions between cells, neighboring cells, and bounding surfaces under flow. Knowledge gained from studying physiologically realistic flow systems may prove useful in microfluidic applications where the transport of blood cells and solubilized, bioactive molecules is needed, or in miniaturized diagnostic devices where cell mechanics or binding affinities can be correlated with clinical pathologies.

(King MR. Cell-Surface Adhesive Interactions in Microchannels and Microvessels.   First International Conference on Microchannels and Minichannels. 2003, Rochester, NY. Pp 1-6. ICMM2003-1012.

P-selectin role in adhesion of leukocytes and sickle cells blocked by heparin

Vascular occlusion is responsible for much of the morbidity associated with sickle cell disease. Although the underlying cause of sickle cell disease is a single nucleotide mutation that directs the production of an easily polymerized hemoglobin protein, both the erythrocyte sickling caused by hemoglobin polymerization and the interactions between a proadhesive population of sickle cells and the vascular endothelium are essential to vascular occlusion.

Interactions between sickle cells and the endothelium use several cell adhesion molecules. Sickle red cells express adhesion molecules including integrin, CD36, band 3 protein, sulfated glycolipid, Lutheran protein, phosphatidylserine, and integrin-associated protein. The proadhesive sickle cells may bind to endothelial cell P-selectin, E-selectin, vascular cell adhesion molecule-1 (VCAM-1), CD36, and integrins. Activation of endothelial cells by specific agonists enhances adhesion by inducing the expression of cellular adhesion molecules and by causing cell contraction, which exposes extracellular matrix proteins, such as thrombospondin (TSP), laminin, and fibronectin. Initial events likely involve the adhesion of sickle erythrocytes to activated endothelial cells under laminar flow. The resultant adhesion of cells to the vascular wall creates nonlaminar and arrested flow, which propagates vascular occlusion by both static and flow adhesion mechanisms. It is likely too that the distinct mechanisms of adhesion and of regulation of endothelial cell adhesivity pertain under dissimilar types of flow.

The expression of adhesion molecules by endothelial cells is affected by cell agonists such as thrombin, histamine, tumor necrosis factor  (TNF-), interleukin 1 (IL-1), platelet activating factor (PAF), erythropoietin, and vascular endothelial growth factor (VEGF), and by local environmental factors such as hypoxia, reperfusion, flow, as well as by sickle erythrocytes themselves. An important effector in sickle cell vascular occlusion is thrombin. Increased thrombin activity correlates with sickle cell disease pain episodes. In addition to generating fibrin clot, thrombin also acts on specific thrombin receptors on endothelial cells and platelets. Work from our laboratory has demonstrated that thrombin treatment causes a rapid increase of endothelial cell adhesivity for sickle erythrocytes under static conditions

We have also reported that sickle cell adhesion to endothelial cells under static conditions involves P-selectin. Although P-selectin plays a major role in the tethering, rolling, and firm adhesion of leukocytes to activated endothelial cells, its contribution to the initial steps is singular and essential to the overall adhesion process. Upon stimulation of endothelial cells by thrombin, P-selectin rapidly translocates from Weibel-Palade bodies to the luminal surface of the cells. Others have shown that sickle cell adhesion is decreased by unfractionated heparin, but the molecular target of this inhibition has not been defined. We postulated that the adhesion of sickle cells to P-selectin might be the pathway blocked by unfractionated heparin. Heparin is known to block certain types of tumor cell adherence, TSP-independent sickle cell adherence, and coagulation processes that are active in sickle cell disease. In one uncontrolled study, prophylactic administration of heparin reduced the frequency of sickle cell pain crises. The role of P-selectin in the endothelial adhesion of sickle red blood cells, the capacity of heparin to block selected P-selectin–mediated adhesive events, and the effect of heparin on sickle cell adhesion suggest an association among these findings.

We postulate that, in a manner similar to that seen for neutrophil adhesion, P-selectin may play a role in the tethering and rolling adhesion of sickle cells. As with neutrophils, integrins may then mediate the firm adhesion of rolling sickle erythrocytes. The integrin  is expressed on sickle reticulocytes and can mediate adhesion to endothelial cells, possibly via endothelial VCAM-4. The endothelial integrin, V3, also mediates sickle cell adhesion to endothelial cells. Other 1 and 3 integrins may also fulfill this role.

In this report we demonstrate that the flow adherence of sickle cells to thrombin-treated human vascular endothelial cells also uses P-selectin and that this component of adhesion is inhibited by unfractionated heparin. We also demonstrate that sickle cells adhere to immobilized recombinant P-selectin under flow conditions. This adhesion too was inhibited by unfractionated heparin, in a concentration range that is clinically attainable. These findings and the general role of P-selectin in initiating adhesion of blood cells to the endothelium suggest that unfractionated heparin may be useful in preventing painful vascular occlusion. A clinical trial to test this hypothesis is indicated.

(Matsui NM, Varki A, and Embury SH.  Heparin inhibits the flow adhesion of sickle red blood cells to P-selectin  Blood. 2002; 100:3790-3796)

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Nitric Oxide, Platelets, Endothelium and Hemostasis (Coagulation Part II)

Curator: Larry H. Bernstein, MD, FCAP 

Subtitle: Nitric oxide and hemostatic mechanisms.  Part II.

Summary: This is the second of a coagulation series on

http://pharmaceuticalIntelligence.com

Treating the diverse effects of NO on platelets, the coagulation cascade, and protein-membrane interactions with low flow states, local and systemic inflammatory disease, oxidative stress, and hematologic disorders.  It is highly complex as the distinction between intrinsic and extrinsic pathways become blurred as a result of  endothelial shear stress, distinctly different than penetrating or traumatic injury.  In addition, other factors that come into play are also considered.

Please refer to Part I. Coagulation Pathway

https://pharmaceuticalintelligence.com/2012/11/26/biochemistry-of-the-coagulation-cascade-and-platelet-aggregation/

The workhorse tests of the modern coagulation laboratory, the prothrombin time (PT) and the activated partial thromboplastin time (aPTT), are the basis for the published extrinsic and intrinsic coagulation pathways.  This is, however, a much simpler model than one encounters delving into the mechanism and interactions involved in hemostasis and thrombosis, or in hemorrhagic disorders.

We first note that there are three components of the hemostatic system in all vertebrates:

  • Platelets,
  • vascular endothelium, and
  • plasma proteins.

The liver is the largest synthetic organ, which synthesizes

  • albumin,
  • acute phase proteins,
  • hormonal and metal binding proteins,
  • albumin,
  • IGF-1, and
  • prothrombin, mainly responsible for the distinction between plasma and serum (defibrinated plasma).

Role of vascular endothelium.

I have identified the importance of prothrombin, thrombin, and the divalent cation Ca 2+ (1% of the total body pool), mention of heparin action, and of vitamin K (inhibited by warfarin).  Endothelial functions are inherently related to procoagulation and anticoagulation. The subendothelial matrix is a complex of many materials, most important related to coagulation being collagen and von Willebrand factor.

What about extrinsic and intrinsic pathways?  Tissue factor, when bound to factor VIIa, is the major activator of the extrinsic pathway of coagulation. Classically, tissue factor is not present in the plasma but only presented on cell surfaces at a wound site, which is “extrinsic” to the circulation.  Or is it that simple?

Endothelium is the major synthetic and storage site for von Willebrand factor (vWF).  vWF is…

  • secreted from the endothelial cell both into the plasma and also
  • abluminally into the subendothelial matrix, and
  • acts as the intercellular glue binding platelets to one another and also to the subendothelial matrix at an injury site.
  • acts as a carrier protein for factor VIII (antihemophilic factor).
  • It  binds to the platelet glycoprotein Ib/IX/V receptor and
  • mediates platelet adhesion to the vascular wall under shear. [Lefkowitz JB. Coagulation Pathway and Physiology. Chapter I. in Hemostasis Physiology. In ( ???), pp1-12].

Ca++ and phospholipids are necessary for all of the reactions that result in the activation of prothrombin to thrombin. Coagulation is initiated by an extrinsic mechanism that

  • generates small amounts of factor Xa, which in turn
  • activates small amounts of thrombin.

The tissue factor/factorVIIa proteolysis of factor X is quickly inhibited by tissue factor pathway inhibitor (TFPI).The small amounts of thrombin generated from the initial activation feedback

  • to create activated cofactors, factors Va and VIIIa, which in turn help to
  • generate more thrombin.
  • Tissue factor/factor VIIa is also capable of indirectly activating factor X through the activation of factor IX to factor IXa.
  • Finally, as more thrombin is created, it activates factor XI to factor XIa, thereby enhancing the ability to ultimately make more thrombin.

The reconceptualization of hemostasis 

The common theme in activation and regulation of plasma coagulation is the reduction in dimensionality. Most reactions take place in a 2D world that will increase the efficiency of the reactions dramatically. The localization and timing of the coagulation processes are also dependent on the formation of protein complexes on the surface of membranes. The coagulation processes can also be controlled by certain drugs that destroy the membrane binding ability of some coagulation proteins – these proteins will be lost in the 3D world and not able to form procoagulant complexes on surfaces.

Assembly of proteins on membranes – making a 3D world flat

• The timing and efficiency of coagulation processes are handled by reduction in dimensionality

– Make 3 dimensions to 2 dimensions

• Coagulation proteins have membrane binding capacity

• Membranes provide non-coagulant and procoagulant surfaces

– Intact cells/activated cells

• Membrane binding is a target for anticoagulant drugs

– Anti-vitamin K (e.g. warfarin)

Modern View

It can be divided into the phases of initiation, amplification and propagation.

  • In the initiation phase, small amounts of thrombin can be formed after exposure of tissue factor to blood.
  • In the amplification phase, the traces of thrombin will be inactivated or used for amplification of the coagulation process.

At this stage there is not enough thrombin to form insoluble fibrin. In order to proceed further thrombin  activates platelets, which provide a procoagulant surface for the coagulation factors. Thrombin will also activate the vital cofactors V and VIII that will assemble on the surface of activated platelets. Thrombin can also activate factor XI, which is important in a feedback mechanism.

In the final step, the propagation phase, the highly efficient tenase and prothrombinase complexes have been assembled on the membrane surface. This yields large amounts of thrombin at the site of injury that can cleave fibrinogen to insoluble fibrin. Factor XI activation by thrombin then activates factor IX, which leads to the formation of more tenase complexes. This ensures enough thrombin is formed, despite regulation of the initiating TF-FVIIa complex, thus ensuring formation of a stable fibrin clot. Factor XIII stabilizes the fibrin clot through crosslinking when activated by thrombin.

Platelet Aggregation

The activities of adenylate and guanylate cyclase and cyclic nucleotide 3′:5′-phosphodiesterase were determined during the aggregation of human blood platelets with

  • thrombin, ADP,
  • arachidonic acid and
  • epinephrine.

[Aggregation is dependent on an intact release mechanism since inhibition of aggregation occurred with adenosine, colchicine, or EDTA.  (Herman GE, Seegers WH, Henry RL. Autoprothrombin ii-a, thrombin, and epinephrine: interrelated effects on platelet aggregation. Bibl Haematol 1977;44:21-7)].

  1. The platelet guanylate cyclase activity during aggregation depends on the nature and mode of action of the inducing agent.
  2. The membrane adenylate cyclase activity during aggregation is independent of the aggregating agent and is associated with a reduction of activity and
  3. Cyclic nucleotide phosphodiesterase remains unchanged during the process of platelet aggregation and release.

The role of platelets in arterial thrombosis

Formation of a thrombus on a ruptured plaque is the product of a complex interaction between coagulation factors in the plasma and platelets.

  • Tissue factor (TF) released from the subendothelial tissue after endothelial damage induces a cascade of activation of coagulation factors ultimately leading to the formation of thrombin.
  • Thrombin cleaves fibrinogen to fibrin, which assembles into a mesh that supports the platelet aggregates.

The Platelet

The platelets are …

  • anucleated,
  • discoid shaped cell fragments
  • originating from megakaryocytes
  •  fragmented as they are released from the bone marrow

Whether they can in circumstances be developed at extramedullary sites (liver sinusoid) is another matter. They have a lifespan of 7-10 days.  Of special interest is:

  • They have a network of internal membranes forming a dense tubular system and the open canalicular system (OCS).
  • The plasma membrane is an extension of the OCS, thereby greatly increasing the surface area of the platelet.
  • The dense tubular system is comparable to the endoplasmatic reticulum in other cell types and is the main storage place of the majority of the platelet’s Ca2+.

Three types of secretory granules exist in platelets:

  • the dense granules
    •  In the dense granules serotonin
    • adenosine diphosphate (ADP) and
    • Ca2+ are stored.
    • a-granules contain
      • P-selectin,
      • fibrinogen,
      •  thrombospondin,
      • Von Willebrand Factor,
      • platelet factor 4 and
      • platelet derived growth factor
      • lysosomes.

Circulating platelets are kept in a resting state by endothelial cell derived

  • prostacyclin (PGI2) and
  • nitric oxide (NO).

PGI2 increases cyclic adenosine monophosphate (cAMP), the most potent platelet inhibitor.

Contact activation

The major regulator of the activation of the contact system is the plasma protease inhibitor, C1-INH, which inhibits activated fXII, kallikrein and fXIa. In addition, α2-macroglobulin is an important inhibitor of kallikrein and α1-antitrypsin for fXIa. Factor XII also converts the fXI to an active enzyme, fXIa, which, in turn, converts fIX to fIXa, thereby activating the intrinsic pathway of coagulation.

Activation

Several agonists can activate platelets;

  • ADP,
  • collagen,
  • thromboxane A2 (TxA2),
  • epinephrin,
  • serotonine and
  • thrombin,

which lead to activation previously referred to:

  • platelet shape change is
  • followed by aggregation and
  • granule secretion.

Upon activation the discoid shape changes into a spherical form.

Activation of platelets is increased by two positive feedback loops

  1. arachidonic acid is cleaved from phospholipids and transformed by cyclooxygenase

(COX) to prostaglandin G2 and H2,

  • followed by the formation of TxA2, a potent platelet agonist.

2.   the secretion of ADP by the dense granules,

  • resulting in activation of the ADP receptor P2Y12.

This causes inhibition of cyclic AMP and sustained aggregation.

Aggregation

The integrin receptor αIIbβ3 plays a vital role in platelet aggregation. The platelet agonists

  • induce a conformational change of the αIIbβ3 receptor and
  • exposition of binding domains for fibrinogen and von Willebrand Factor.

This allows cross-linking of platelets and the formation of aggregates.

In addition to shape change and aggregation, the membranes of the α- and dense granules fuse with the membranes of the OCS. This causes the release of their contents and the transportation of proteins embedded in their membrane to the plasma membrane.

This complex interaction between

  • endothelial cells
  • clotting factors
  • platelets and
  • other factors and cells

can be studied in both in vitro and in vivo model systems. The disadvantage of in vitro assays is that it studies the role of a certain protein or cell in isolation. Given the large number of participants and the complex interactions of thrombus formation there is need to study thrombosis and hemostasis in intact living animals, with all the components important for thrombus formation – a vessel wall and flowing blood – present.

Endothelial Damage and Role as “Primer”

  • Endothelial injury changes the permeability of the arterial wall.
  • This is followed by an influx of low-density lipoprotein (LDL).
  • This elicits an inflammatory response in the vascular wall.
  • Monocytes and T-cells bind to the endothelial cells promoting increased migration of the cells into the intima layer
  • The monocytes differentiate into macrophages, which take up modified lipoproteins and transform them into foam cells.
  • Concurrent with this process macrophages produce cytokines and proteases.

This is a vicious circle of lipid driven inflammation that leads to narrowing of the vessel’s lumen without early clinical consequences. Clinical manifestations of more advanced atherosclerotic disease are caused by destabilization of an atherosclerotic plaque formed as described.

  • The first recognizable lesion of the stable atherosclerotic plaque is the fatty streak, which consists of the above described foam cells and T-lymphocytes in the intima.
  • Further development of the lesion leads to the intermediate lesion, composed
  • of layers of macrophages and smooth muscle cells.
  • A more advanced stage is called the vulnerable plaque.
    • It has a large lipid core that is covered by a thin fibrous cap.
    • This cap separates the lipid contents of the plaque from the circulating blood.
    • The vulnerable plaque is prone to rupture, resulting in the formation of a thrombus on the site of disruption or the thrombus can be superimposed on plaque erosion without signs of plaque rupture.

The formation of a superimposed thrombus on a disrupted atherosclerotic plaque in the lumen of the artery leads to

  • an acute occlusion of the vessel
  • hypoxia of the downstream tissue.

Depending on the location of the atherosclerotic plaque this will cause a myocardial infarction, stroke or peripheral vascular disease.

Endothelial regulation of coagulation

The endothelium attenuates platelet activity by releasing

  • nitric oxide and
  • prostacyclin.

Several coagulation inhibitors are produced by endothelial cells.

Endothelium-derived TFPI (on its surface) is rapidly released into circulation after heparin administration, reducing the pro-coagulant activities of TF-fVIIa. Endothelial cells also secrete heparin-sulphate, a glycosaminoglycan which catalyzes anti-coagulant activity of AT. Plasma AT binds to heparin-sulphate located on the luminal surface and in the basement membrane of the endothelium. Thrombomodulin is another endothelium-bound protein with anti-coagulant and anti-inflammatory functions. In response to systemic pro-coagulant stimuli, tissue-type plasminogen activator (tPA) is transiently released from the Weibel-Palade bodies of endothelial cells to promote fibrinolysis. Downstream of the vascular injury, the complex of TF-fVIIa/fXa is inhibited by TFPI. Plasma (free) fXa and thrombin are rapidly neutralized by heparan-bound AT. Thrombin is also taken up by endothelial surface-bound thrombomodulin.

The protein C pathway works in hemostasis to control thrombin formation in the area surrounding the clot. Thrombin, generated via the coagulation pathway, is localized to the endothelium by binding to the integral membrane protein, thrombomodulin (TM). TM by occupying exosite I on thrombin, which is required for fibrinogen binding and cleavage, reduces thrombin’s pro-coagulant activities. TM bound thrombin  on the endothelial cell surface is able to cleave PC producing activated protein C (APC), a serine protease.  In the presence of protein S, APC inactivates FVa and FVIIIa. The proteolytic activity of APC is regulated predominantly by a protein C inhibitor.

Fibrinolytic pathway

Fibrinolysis is the physiological breakdown of fibrin to limit and resolve blood clots. Fibrin is degraded primarily by the serine protease, plasmin, which circulates as plasminogen. In an auto-regulatory manner, fibrin serves as both the co-factor for the activation of plasminogen and the substrate for plasmin. In the presence of fibrin, tissue plasminogen activator (tPA) cleaves plasminogen producing plasmin, which proteolyzes the fibrin. This reaction produces the protein fragment D-dimer, which is a useful marker of fibrinolysis, and a marker of thrombin activity because fibrin is cleaved from fibrinogen to fibrin.

Nitric Oxide and Platelet Energy Production

Nitric oxide (NO) has been increasingly recognized as an important intra- and intercellular messenger molecule with a physiological role in

  • vascular relaxation
  • platelet physiology
  • neurotransmission and
  • immune responses.

In vitro NO is a strong inhibitor of platelet adhesion and aggregation. In the blood stream, platelets remain in contact with NO that is permanently released from the endothelial cells and from activated macrophages. It  has been suggested that the activated platelet itself is able to produce NO. It has been proposed that the main intracellular target for NO in platelets is soluble cytosolic guanylate cyclase. NO activates the enzyme. When activated, intracellular cGMP elevation inhibits platelet activation. Further, elevated cGMP may not be the sole factor directly involved in the inhibition of platelet activation.

The reaction mechanism of Nitric oxide synthase

The reaction mechanism of Nitric oxide synthase (Photo credit: Wikipedia)

Platelets are fairly active metabolically and have a total ATP turnover rate of about 3–8 times that of resting mammalian muscle. Platelets contain mitochondria which enable these cells to produce energy both in the oxidative and anaerobic pathways.

  • Under aerobic conditions, ATP is produced by aerobic glycolysis which can account for 30–50% of total ATP production,
  • by oxidative metabolism using glucose and glycogen (6–11%), amino-acids (7%) or free fatty acids (20–40%).

The inhibition of mitochondrial respiration by removing oxygen or by respiratory chain blockers (antimycin A, cyanide, rotenone) results in the stimulation of glycolytic flux. This phenomenon indicates that in platelets glycolysis and mitochondrial respiration are tightly functionally connected. It has been reported that the activation of human platelets by high concentration of thrombin is accompanied by an acceleration of lactate production and an increase in oxygen consumption.

The results (in porcine platelets) indicate that:

  • NO is able to diminish mitochondrial energy production through the inhibition of cytochrome oxidase
  • The inhibitory effect of NO on platelet secretion (but not aggregation) can be attributed to the reduction of mitochondrial energy production.

Porcine blood platelets stimulated by collagen produce more lactate. This indicates that both glycolytic and oxidative ATP production supports platelet responses, and blocking of energy production in platelets may decrease their responses. It is well established that platelet responses have different metabolic energy (ATP) requirements increasing in the order:

  • Aggregation
  • < dense and alfa granule secretion
  • < acid hydrolase secretion.

In addition, exogenously added NO (in the form of NO donors) stimulates glycolysis in intact porcine platelets. Since in platelets glycolysis and mitochondrial respiration are tightly functionally connected, this indicates the stimulatory effect of NO on glycolysis in intact platelets may be produced by non-functional mitochondria.

Can this be the case?

  • NO donors are able to inhibit both mitochondrial respiration and platelet cytochrome oxidase.
  • Interestingly, the concentrations of NO donors inhibiting mitochondrial respiration and cytochrome oxidase were similar to those stimulating glycolysis in intact platelets.

Studies have shown that mitochondrial complex I is inhibited only after a prolonged (6–18 h) exposure to NO and

  • This inhibition appears to result from S-nitrosylation of critical thiols in the enzyme complex.
  • Further studies are needed to establish whether long term exposure of platelets to NO affects Mitochondrial complexes I and II.

Comparison of the concentrations of SNAP and SNP affecting cytochrome oxidase activity and mitochondrial respiration with those reducing the platelet responses indicates that NO does not reduce platelet aggregation through the inhibition of oxidative energy production. The concentrations of the NO donors inhibiting platelet secretion, mitochondrial respiration and cytochrome oxidase were similar. Thus, the platelet release reaction strongly depends on the oxidative energy production, and  in porcine platelets NO inhibits mitochondrial energy production at the step of cytochrome oxidase.

Taking into account that platelets may contain NO synthase and are able to produce significant amounts of NO it seems possible that nitric oxide can function in these cells as a physiological regulator of mitochondrial energy production.

Key words: glycolysis, mitochondrial energy production, nitric oxide, porcine platelets.
Abbreviations: NO, nitric oxide; SNAP, S-nitroso-N-acetylpenicyllamine; SNP, sodium nitroprusside.

[M Tomasiak, H Stelmach, T Rusak and J Wysocka.  Nitric oxide and platelet energy metabolism.  Acta Biochimica Polonica 2004; 51(3):789–803.]

Nitric Oxide and Platelet Adhesion

The adhesion of human platelets to monolayers of bovine endothelial cells in culture was studied to determine the role of endothelium-derived nitric oxide in the regulation of platelet adhesion. The adhesion of unstimulated and thrombin-stimulated platelets, washed and labelled with indium-111, was lower in the presence than in the absence of bradykinin or exogenous nitric oxide. The inhibitory action of both bradykinin and nitric oxide was abolished by hemoglobin, but not by aspirin, and was potentiated by superoxide dismutase to a similar degree. It appears that the effect of bradykinin is mediated by the release of nitric oxide from the endothelial cells, and that nitric oxide release contributes to the non-adhesive properties of vascular endothelium.

(Radomski MW, Palmer RMJ, Moncada S.   Endogenous Nitric Oxide Inhibits Human Platelet Adhesion to Vascular Endothelium. The Lancet  1987 330; 8567(2): 1057–1058.
http://dx.doi.org/10.1016/S0140-6736(87)91481-4)

1 The interactions between endothelium-derived nitric oxide (NO) and prostacyclin as inhibitors of platelet aggregation were examined to determine whether release of NO accounts for the inhibition of platelet aggregation attributed to EDRF.

2 Porcine aortic endothelial cells treated with indomethacin and stimulated with bradykinin (10-100 nM) released NO in quantities sufficient to account for the inhibition of platelet aggregation attributed to endothelium-derived relaxing factor (EDRF).

3 In the absence of indomethacin, stimulation of the cells with bradykinin (1-3 nM) released small amounts of prostacyclin and EDRF which synergistically inhibited platelet aggregation.

4 EDRF and authentic NO also caused disaggregation of platelets aggregated either with collagen or with U46619.

5 A reciprocal potentiation of both the anti- and the disaggregating activity was also observed between low concentrations of prostacyclin and authentic NO or EDRF released from endothelial cells.

6 It is likely that interactions between prostacyclin and NO released by the endothelium play a role in the homeostatic regulation of platelet-vessel wall interactions.

(Radomski MW, Palmer RMJ & Moncada S. The anti-aggregating properties of vascular endothelium: interactions between prostacyclin and nitric oxide. Br J Pharmac 1987; 92: 639-646.

 

Factor Xa–Nitric Oxide Signaling

Although primarily recognized for maintaining the hemostatic balance, blood proteases of the coagulation and fibrinolytic cascades elicit rapid cellular responses in

  • vascular
  • mesenchymal
  • inflammatory cell types.

Considerable effort has been devoted to elucidate the molecular interface between protease-dependent signaling and pleiotropic cellular responses. This led to the identification of several membrane protease receptors, initiating intracellular signal transduction and effector functions in vascular cells. In this context, thrombin receptor activation

  • generated second messengers in endothelium and smooth muscle cells,
  • released inflammatory cytokines from monocytes, fibroblasts, and endothelium, and
  • increased the expression of leukocyte-endothelial cell adhesion molecules.

Similarly, binding of factor Xa to effector cell protease receptor-1 (EPR-1) participated in

  • in vivo acute inflammatory responses,
  • platelet and brain pericyte prothrombinase activity, and
  • endothelial cell and smooth muscle cell signaling and proliferation.

Factor Xa stimulated a 5- to 10-fold increased release of nitric oxide (NO) in a dose-dependent reaction (0.1–2.5 mgyml) unaffected by the thrombin inhibitor hirudin but abolished by active site inhibitors, tick anticoagulant peptide, or Glu-Gly-Arg-chloromethyl ketone. In contrast, the homologous clotting protease factor IXa or another endothelial cell ligand, fibrinogen, was ineffective.

A factor Xa inter-epidermal growth factor synthetic peptide L83FTRKL88(G) blocking ligand binding to effector cell protease receptor-1 inhibited NO release by factor Xa in a dose-dependent manner, whereas a control scrambled peptide KFTGRLL was ineffective.

Catalytically active factor Xa induced hypotension in rats and vasorelaxation in the isolated rat mesentery, which was blocked by the NO synthase inhibitor L-NG-nitroarginine methyl ester (LNAME) but not by D-NAME. Factor Xa/NO signaling also produced a dose-dependent endothelial cell release of interleukin 6 (range 0.55–3.1 ngyml) in a reaction

  • inhibited by L-NAME and by the
  • inter-epidermal growth factor peptide Leu83–Leu88 but
  • unaffected by hirudin.
We observe that incubation of HUVEC monolayers with factor Xa which resulted in a concentration-dependent release of NO, as determined by cGMP accumulation in these cells, was inhibited by the nitric oxide synthase antagonist L-NAME.

Catalytically inactive DEGR-factor Xa or TAP-treated factor Xa failed to stimulate NO release by HUVEC.

To determine whether factor Xa-induced NO release could also modulate acute phase/inflammatory cytokine gene expression we examined potential changes in IL-6 release following HUVEC stimulation with factor Xa. HUVEC stimulation with factor Xa resulted in a concentration-dependent release of IL-6.

The specificity of factor Xa-induced cytokine release was investigated. Factor Xa-induced IL-6 release from HUVEC was quantitatively indistinguishable from that obtained with tumor necrosis factor-a or thrombin stimulation. This response was abolished by heat denaturation of factor Xa.

Maximal induction of interleukin 6 mRNA required a brief, 30-min stimulation with factor Xa, and was unaffected by subsequent addition of tissue factor pathway inhibitor (TFPI). These data suggest that factor Xa-induced NO release modulates endothelial cell-dependent vasorelaxation and IL-6 cytokine gene expression.

Here, we find that factor Xa induces the release of endothelial cell NO

  • regulating vasorelaxation in vivo and acute response cytokine gene expression in vitro.

This pathway requires a dual step cascade, involving

  • binding of factor Xa to EPR-1 and
  • a secondary as yet unidentified protease activated mechanism.

This pathway requiring factor Xa binding to effector cell protease receptor-1 and a secondary step of ligand-dependent proteolysis may preserve an anti-thrombotic phenotype of endothelium but also trigger acute phase responses during activation of coagulation in vivo.

In summary, these investigators have identified a signaling pathway centered on the ability of factor Xa to rapidly stimulate endothelial cell NO release. This involves a two-step cascade initiated by catalytic active site-independent binding of factor Xa to its receptor, EPR-1, followed by a second step of ligand dependent proteolysis.

(Papapetropoulos A, Piccardoni P, Cirino G, Bucci M, et al. Hypotension and inflammatory cytokine gene expression triggered by factor Xa–nitric oxide signaling. Proc. Natl. Acad. Sci. USA. Pharmacology. 1998; 95:4738–4742.)

Platelets and liver disease

Thrombocytopenia is a marked feature of chronic liver disease and cirrhosis. Traditionally, this thrombocytopenia was attributed to passive platelet sequestration in the spleen. More recent insights suggest an increased platelet breakdown and to a lesser extent decreased platelet production plays a more important role. Besides the reduction in number, other studies suggest functional platelet defects. This platelet dysfunction is probably both intrinsic to the platelets and secondary to soluble plasma factors. It reflects not only a decrease in aggregability, but also an activation of the intrinsic inhibitory pathways. (Witters P, Freson K, Verslype C, Peerlinck K, et al. Review article: blood platelet number and function in chronic liver disease and cirrhosis. Aliment Pharmacol Ther 2008; 27: 1017–1029).

The shortcomings of the old Y-shaped model of normal coagulation are nowhere more apparent than in its clinical application to the complex coagulation disorders of acute and chronic liver disease. In this condition, the clotting cascade is heavily influenced by numerous currents and counter-currents resulting in a mixture of pro- and anticoagulant forces that are themselves further subject to change with altered physiological stress such as super-imposed infection or renal failure.

Multiple mechanisms exist for thrombocytopenia common in patients with cirrhosis besides hypersplenism and expected altered thrombopoietin metabolism. Increased production of two important endothelial derived platelet inhibitors

  • nitric oxide and
  • prostacyclin

may contribute to defective platelet activation in vivo. On the other hand, high plasma levels of vWF in cirrhosis appear to support platelet adhesion.

Reduced levels of coagulation factors V, VII, IX, X, XI, and prothrombin are also commonly observed in liver failure. Vitamin K–dependent clotting factors (II, VII, IX, X) may be defective in function as a result of decreased  y-carboxylation (from vitamin K deficiency or intrinsically impaired carboxylase activity). Fibrinogen levels are decreased with advanced cirrhosis and in patients with acute liver failure.

A hyperfibrinolytic state may develop when plasminogen activation by tPA is accelerated on the fibrin surface. Physiologic stress including infection may be key in tipping this process off through increased release of tPA.  Not uncommonly, laboratory abnormalities in decompensated cirrhosis come to resemble disseminated intravascular coagulation (DIC). Relatively stable platelet levels and characteristically high factor VIII levels distinguish this process from DIC as does the absence of uncompensated thrombin generation. The features of both hyperfibrinolysis and DIC are often evident in the decompensated liver disease patient, and the term “accelerated intravascular coagulation and fibrinolysis” (AICF) has been proposed as a way to encapsulate the process under a single heading. The essence of AICF can be postulated to be the result of formation of a fibrin clot that is more susceptible to plasmin degradation due to elevated levels of tPA coupled with inadequate release of PAI to control tPA and lack of a-2 plasmin inhibitor to quench plasmin activity and the maintenance of high local concentrations of plasminogen on clot surfaces despite lower total plasminogen production. These normally balanced processes become pronounced when disturbed by additional stress such as infection.

Normal hemostasis and coagulation is now viewed as primarily a cell-based process wherein key steps in the classical clotting cascade

  • occur on the phospholipid membrane surface of cells (especially platelets)
  • beginning with activation of tissue factor and factor VII at the site of vascular breach
    •  which produces an initial “priming” amount of thrombin and a
    • subsequent thrombin burst.

Coagulation and hemostasis in the liver failure patient is influenced by multiple, often opposing, and sometimes changing variables. A bleeding diathesis is usually predominant, but the assessment of bleeding risk based on conventional laboratory tests is inherently deficient.

(Caldwell SH, Hoffman M, Lisman T, Gail Macik B, et al. Coagulation Disorders and Hemostasis in Liver Disease: Pathophysiology and Critical Assessment of Current Management. Hepatology 2006;44:1039-1046.)

Bleeding after Coronary Artery bypass Graft

Cardiac surgery with concomitant CPB can profoundly alter haemostasis, predisposing patients to major haemorrhagic complications and possibly early bypass conduit-related thrombotic events as well. Five to seven percent of patients lose more than 2 litres of blood within the first 24 hours after surgery, between 1% and 5% require re-operation for bleeding. Re-operation for bleeding increases hospital mortality 3 to 4 fold, substantially increases post-operative hospital stay and has a sizeable effect on health care costs. Nevertheless, re-exploration is a strong risk factor associated with increased operative mortality and morbidity, including sepsis, renal failure, respiratory failure and arrhythmias.

(Gábor Veres. New Drug Therapies Reduce Bleeding in Cardiac Surgery. Ph.D. Doctoral Dissertation. 2010. Semmelweis University)

Hypercoagulable State in Thalassemia

As the life expectancy of β-thalassemia patients has increased in the last decade, several new complications are being recognized. The presence of a high incidence of thromboembolic events, mainly in thalassemia intermedia patients, has led to the identification of a hypercoagulable state in thalassemia. Patients with thalassemia intermedia (TI) have, in general, a milder clinical phenotype than those with TM and remain largely transfusion independent. The pathophysiology of TI is characterized by extravascular hemolysis, with the release into the peripheral circulation of damaged red blood cells (RBCs) and erythroid precursors because of a high degree of ineffective erythropoiesis. This has also been recently attributed to severe complications such as pulmonary hypertension (PHT) and thromboembolic phenomena.

Many investigators have reported changes in the levels of coagulation factors and inhibitors in thalassemic patients. Prothrombin fragment 1.2 (F1.2), a marker of thrombin generation, is elevated in TI patients. The status of protein C and protein S was investigated in thalassemia in many studies and generally they were found to be decreased; this might be responsible for the occurrence of thromboembolic events in thalassemic patients.

The pathophysiological roles of hemolysis and the dysregulation of nitric oxide homeostasis are correlated with pulmonary hypertension in sickle cell disease and in thalassemia. Nitric oxide binds soluble guanylate cyclase, which converts GTP to cGMP, relaxing vascular smooth muscle and causing vasodilatation. When plasma hemoglobin liberated from intravascularly hemolyzed sickle erythrocytes consumes nitric oxide, the balance is shifted toward vasoconstriction. Pulmonary hypertension is aggravated and in sickle cell disease, it is linked to the intensity of hemolysis. Whether the same mechanism contributes to hypercoagulability in thalassemia is not yet known.

While there are diverse factors contributing to the hypercoagulable state observed in patients with thalassemia. In most cases, a combination of these abnormalities leads to clinical thrombosis. An argument has been made for the a higher incidence of thrombotic events in TI compared to TM patients  attributed to transfusion for TM. The higher rate of thrombosis in transfusion-independent TI compared to polytransused TM patients suggests a potential role for transfusions in decreasing the rate of thromboembolic events (TEE). The reduction of TEE in adequately transfused patients may be the result of decreased numbers of pathological RBCs.

(Cappellini MD, Musallam KM,  Marcon A, and Taher AT. Coagulopathy in Beta-Thalassemia: Current Understanding and Future Prospects. Medit J Hemat Infect Dis 2009; 1(1):22009029.
DOI 10.4084/MJHID.2009.0292.0), www.mjhid.org/article/view/5250.  ISSN 2035-3006.)

Microvascular Endothelial Dysfunction

Severe sepsis, defined as sepsis associated with acute organ dysfunction, results from a generalized inflammatory and procoagulant host response to infection. Coagulopathy in severe sepsis is commonly associated with multiple organ dysfunction, and often results in death. The molecule that is central to these effects is thrombin, although it may also have anticoagulant and antithrombotic effects through the activation of Protein C and induction of prostacyclin. In recent years, it has been recognized that chemicals produced by endothelial cells play a key role in the pathogenesis of sepsis. Thrombomodulin on endothelial cells coverts Protein C to Activated Protein C, which has important antithrombotic, profibrinolytic and anti-inflammatory properties. A number of studies have shown that Protein C levels are reduced in patients with severe infection, or even in inflammatory states without infection. Because coagulopathy is associated with high mortality rates, and animal studies have indicated that therapeutic intervention may result in improved outcomes, it was rational to initiate clinical studies.

Considering the coagulation cascade as a whole, it is the extrinsic pathway (via TF and thrombin activation) rather than the intrinsic pathway that is of primary importance in sepsis. Once coagulation has been triggered by TF activation, leading to thrombin formation, this can have further procoagulant effects, because thrombin itself can activate factors VIII, IX and X. This is normally balanced by the production of anticoagulant factors, such as TF pathway inhibitor, antithrombin and Activated Protein C.

It has been recognized that endothelial cells play a key role in the pathogenesis of sepsis, and that they produce important regulators of both coagulation and inflammation. They can express or release a number of substances, such as TF, endothelin-1 and PAI-1, which promote the coagulation process, as well as other substances, such as antithrombin, thrombomodulin, nitric oxide and prostacyclin, which inhibit it.

Protein C is the source of Activated Protein C. Although Protein C is a biomarker or indicator of sepsis, it has no known specific biological activity. Protein C is converted to Activated Protein C in the presence of normal endothelium. In patients with severe sepsis, the vascular endothelium becomes damaged. The level of thrombomodulin is significantly decreased, and the body’s ability to convert Protein C to Activated Protein C diminishes. Only when activated does Protein C have antithrombotic, profibrinolytic and anti-inflammatory properties.

Blood Coagulation (Thrombin) and Protein C Pat...

Blood Coagulation (Thrombin) and Protein C Pathways (Blood_Coagulation_and_Protein_C_Pathways.jpg) (Photo credit: Wikipedia)

Coagulation abnormalities can occur in all types of infection, including both Gram-positive and Gram-negative bacterial infections, or even in the absence of infection, such as in inflammatory states secondary to trauma or neurosurgery. Interestingly, they can also occur in patients with localized disease, such as those with respiratory infection. In a study by Günther et al., procoagulant activity in bronchial lavage fluid from patients with pneumonia or acute respiratory distress syndrome was found to be increased compared with that from control individuals, with a correlation between the severity of respiratory failure and level of coagulant activity.

Severe sepsis, defined as sepsis associated with acute organ dysfunction, results from a generalized inflammatory and procoagulant host response to infection.  Once the endothelium becomes damaged, levels of endothelial thrombomodulin significantly decrease, and the body’s ability to convert Protein C to Activated Protein C diminishes. The ultimate cause of acute organ dysfunction in sepsis is injury to the vascular endothelium, which can result in microvascular coagulopathy.

(Vincent JL. Microvascular endothelial dysfunction: a renewed appreciation of sepsis pathophysiology.
Critical Care 2001; 5:S1–S5. http://ccforum.com/content/5/S2/S1)

Endothelial Cell Dysfunction in Severe Sepsis

During the past decade a unifying hypothesis has been developed to explain the vascular changes that occur in septic shock on the basis of the effect of inflammatory mediators on the vascular endothelium. The vascular endothelium plays a central role in the control of microvascular flow, and it has been proposed that widespread vascular endothelial activation, dysfunction and eventually injury occurs in septic shock, ultimately resulting in multiorgan failure. This has been characterized in various models of experimental septic shock. Now, direct and indirect evidence for endothelial cell alteration in humans during septic shock is emerging.

The vascular endothelium regulates the flow of nutrient substances, diverse biologically active molecules and the blood cells themselves. This role of endothelium is achieved through the presence of membrane-bound receptors for numerous molecules, including proteins, lipid transporting particles, metabolites and hormones, as well as through specific junction proteins and receptors that govern cell–cell and cell–matrix interactions. Endothelial dysfunction and/or injury with subendothelium exposure facilitates leucocyte and platelet aggregation, and aggravation of coagulopathy. Therefore, endothelial dysfunction and/or injury should favour impaired perfusion, tissue hypoxia and subsequent organ dysfunction.

Anatomical damage to the endothelium during septic shock has been assessed in several studies. A single injection of bacterial lipopolysaccharide (LPS) has long been demonstrated to be a nonmechanical technique for removing endothelium. In endotoxic rabbits, observations tend to demonstrate that EC surface modification occurs easily and rapidly, with ECs being detached from the internal elastic lamina with an indication of subendothelial oedema.  Proinflammatory cytokines increase permeability of the ECs, and this is manifested approximately 6 hours after inflammation is triggered and becomes maximal over 12–24 hours as the combination of cytokines exert potentiating effects. Endothelial physical disruption allows inflammatory fluid and cells to shift from the blood into the interstitial space.

In sepsis

  • ECs become injured, prothrombotic and antifibrinolytic
  • They promote platelet adhesion
  • They promote leucocyte adhesion and inhibit vasodilation

An important point is that EC injury is sustained over time. In an endotoxic rabbit model, we demonstrated that endothelium denudation is present at the level of the abdominal aorta as early as after several hours following injury and persisted for at least 5 days afterward. After 21 days we observed that the endothelial surface had recovered. The de-endothelialized surface accounted for approximately 25% of the total surface.

Thrombomodulin and protein C activation at the microcirculatory level.

The endothelial cell surface thrombin (Th)-binding protein thrombomodulin (TM) is responsible for inhibition of thrombin activity. TM, when bound to Th, forms a potent protein C activator complex. Loss of TM and/or internalization results in Th–thrombin receptor (TR) interaction. Loss of TM and associated protein C activation represents the key event of decreased endothelial coagulation modulation ability and increased inflammation pathways.
( Iba T, Kidokoro A, Yagi Y: The role of the endothelium in changes in procoagulant activity in sepsis. J Am Coll Surg 1998; 187:321-329. Keywords: ATIII, antithrombin III; NF-κ, nuclear factor-κB; PAI,plasminogen activator inhibitor).

In order to test the role of the endothelial-derived relaxing factors NO and PGI2, we investigated, in dogs, the influence of a combination of NG-nitro-L-arginine methyl ester (an inhibitor of NO synthesis) and indomethacin (an inhibitor of PGI2 synthesis). In these dogs treated with indomethacin plus NG-nitro-L-arginine methyl ester, the severity of the oxygen extraction defect was lower than that observed in the deoxycholate-treated dogs, suggesting that other mediators and/or mechanisms may be involved in microcirculatory control during hypoxia. One of these mediators or mechanisms could be related to hyperpolarization. Membrane potential is an important determinant of vascular smooth muscle tone through its influence on calcium influx via voltage-gated calcium channels. Hyperpolarization (as well as depolarization) has been shown to be a means of cell–cell communication in upstream vasodilatation and microcirculatory coordination. It is important to emphasize that intercell coupling exclusively involves ECs.

Interestingly, it was recently shown that sepsis, a situation that is characterized by impaired tissue perfusion and abnormal oxygen extraction, is associated with abnormal inter-EC coupling and reduction in the arteriolar conducted response.  An intra-organ defect in blood flow related to abnormal vascular reactivity, cell adhesion and coagulopathy may account for impaired organ oxygen regulation and function. If specific classes of microvessels must or must not be perfused to achieve efficient oxygen extraction during limitation in oxygen delivery, then impaired vascular reactivity and vessel injury might produce a pathological limitation in supply. In sepsis, the inflammatory response profoundly alters circulatory homeostasis, and this has been referred to as a ‘malignant intravascular inflammation’ that alters vasomotor tone and the distribution of blood flow among and within organs. These mechanisms might coexist with other types of sepsis associated cell dysfunction. For example, data suggest that endotoxin directly impairs oxygen uptake in ECs and indicate the importance of endothelium respiration in maintaining vascular homeostasis under conditions of sepsis.

Consistent with the hypothesis that alteration in endothelium plays a major in the pathophysiology of sepsis, it was observed that chronic ecNOS overexpression in the endothelium of mice resulted in resistance to LPS-induced hypotension, lung injury and death . This observation was confirmed by another group of investigators, who used transgenic mice overexpressing adrenomedullin  – a vasodilating peptide that acts at least in part via an NO-dependent pathway. They demonstrated resistance of these animals to LPS-induced shock, and lesser declines in blood pressure and less severe organ damage than occurred in the control animals. It might therefore be of importance to favour ecNOS expression and function during sepsis. The recent negative results obtained with therapeutic strategies aimed at blocking inducible NOS with the nonselective NOS inhibitor NG-monomethyl-L-arginine in human septic shock further confirm the overall importance of favoring vessel dilatation.

(Vallet B. Bench-to-bedside review: Endothelial cell dysfunction in severe sepsis: a role in organ dysfunction?  Critical Care 2003; 7(2):130-138 (DOI 10.1186/cc1864). (Print ISSN 1364-8535; Online ISSN 1466-609X). http://ccforum.com/content/7/2/130

Thrombosis in Inflammatory Bowel Disease

An association between IBD and thrombosis has been recognized for more than 60 years. Not only are patients with IBD more likely to have thromboembolic complications, but it has also been suggested that thrombosis might be pathogenic in IBD.

Coagulation Described.  See Part I. (Cascade)

Endothelial injury exposes TF, which forms a complex with factor VII.  This complex activates factors X and, to a lesser extent, IX. TFPI prevents this activation progressing  further; for coagulation to progress, factor Xa must be produced via factors IX and VIII. Thrombin, generated by the initial production of factor Xa, activates factor VIII and, through factor XI, factor IX, resulting in further activation of factor X. This positive feedback loop allows coagulation to proceed. Fibrin polymers are stabilized by factor XIIIa. Activated proteins CS (APCS) together inhibit factors VIIIa and Va, whereas antithrombin (AT) inhibits factors VIIa, IXa, Xa, and XIa. Fibrinolysis balances this system through the action of plasmin on fibrin. Plasminogen activator inhibitor controls the plasminogen activator-induced conversion of plasminogen to plasmin.

Inflammation and Thrombotic Processes Linked

Although interest has recently moved away from the proposal that ischemia is a primary cause of IBD, it has become increasingly clear that inflammatory and thrombotic processes are linked.  A vascular component to the pathogenesis of CD was first proposed only a year after Crohn et al. described the condition.  Subsequently, in 1989, a series of changes comprising vascular injury, focal arteritis, fibrin deposition, arterial occlusion, and then microinfarction or neovascularization was proposed as a possible pathogenetic sequence in CD.  In this study, resin casts of the intestinal vasculature showed changes ranging from intravascular fibrin deposition to complete thrombotic occlusion. Furthermore, the early vascular changes appeared to precede mucosal changes, suggesting that they were more likely to cause rather than result from the pathologic features of CD. Subsequent studies showed that intravascular fibrin deposition occurred at the site of granulomatous destruction of mesenteric blood vessels, and positive immunostaining for platelet glycoprotein IIIa occurred in fibrinoid plugs of mucosal capillaries in CD. In addition, intracapillary thrombus has been identified in biopsies from inflamed rectal mucosa from patients with CD. When combined with evidence of ongoing intravascular coagulation in both active and quiescent CD, the above data point toward a thrombotic element contributing to the pathogenesis of CD.

Not only are many different prothrombotic changes described in association with IBD, but they can also have multiple causes. Hyperhomocysteinemia, for example, is known to predispose to thrombosis, and patients with IBD are more likely to have hyperhomocysteinemia than control subjects. Hyperhomocysteinemia in IBD might be due to multiple possible causes, such as deficiencies of vitamin B12 as a result of terminal ileal disease or resection; B6, which is commonly reduced in IBD.  A vegan diet can’t be discarded either because of seriously deficient methyl donors (S-adenosyl methionine).

The realization that platelets are not only prothrombotic but also proinflammatory has stimulated interest in their role in both the pathogenesis and complications of IBD. The association between thrombocytosis and active IBD was first described more than 30 years ago. More recent observations link decreased or normal platelet survival to IBD-related thrombocytosis, possibly due to increased thrombopoiesis. This in turn could be driven by an interleukin-6 –induced increase in thrombopoietin synthesis in the liver. Spontaneous in vitro platelet aggregation occurs in platelets isolated from 30% of patients with IBD but not in platelets from control subjects. Moreover, collagen, arachidonic acid, ristocetin, and ADP-induced platelet activation are more marked in platelets from patients with active IBD than in those from healthy volunteers.

The roles of activated platelets and PLAs in mucosal inflammation. Activated platelets can interact with other cells involved in the inflammatory response either through direct contact or through the release of soluble mediators. Activated platelets interact directly with activated vascular endothelium, causing the latter to express adhesion molecules and release inflammatory and chemotactic cytokines.

Platelet activation might be pathogenic in IBD in several ways. Platelet activation might increase platelet aggregation, hence increasing the likelihood of thrombus formation at sites of vascular injury, for example, within the mesenteric circulation. P-selectin is the major ligand for leukocyte-endothelial interaction and is responsible for the rolling of platelets, leukocytes, and PLAs on vascular endothelium. Moreover, platelets adherent to injured vascular endothelium support leukocyte adhesion via P-selectin, an effect that could contribute to leukocyte emigration from the vasculature into the lamina propria in patients with IBD. In addition, P-selectin is the major platelet ligand for platelet-leukocyte interaction, which in turn causes both leukocyte activation and further platelet activation.

Platelet-Leukocyte Aggregation

Recently, studies showing that platelets and leukocytes that circulate together in aggregates (PLA) are more activated than those that circulate alone have generated interest in the role of PLA in various inflammatory and thrombotic conditions. PLA numbers are increased in patients with ischemic heart disease, systemic lupus erythematosus and rheumatoid arthritis, myeloproliferative disorders, and sepsis and are increased by smoking.

We have recently shown that patients with IBD have more PLAs than both healthy and inflammatory control subjects (patients with inflammatory arthritides).  As with platelet activation, there was no correlation with disease activity, suggesting that increased PLA formation might be an underlying abnormality. PLAs could contribute to the pathogenesis of IBD in a number of ways. As previously mentioned, TF is key to the initiation of thrombus formation. TF has recently been demonstrated on the surface of activated platelets and in platelet-derived microvesicles. Interaction between neutrophils and activated platelets or microvesicles vastly increases the activity of “intravascular” TF.

Conclusion        

It is becoming increasingly apparent that thrombosis and inflammation are intrinsically linked. Hence the involvement of thrombotic processes in the pathogenesis of IBD, although perhaps not as the primary event, seems likely. Indeed, with the recently mounting evidence of the role of activated platelets and of their interaction with leukocytes in the pathogenesis of IBD, it seems even more probable that thrombosis plays some role in the pathogenic process.

(Irving PM, Pasi KJ, and Rampton DS. Thrombosis and Inflammatory Bowel Disease. Clinical Gastroenterology and Hepatology 2005;3:617–628. PII: 10.1053/S1542-3565(05)00154-0.)

Bleeding in Patients with Renal Insufficiency

Approximately 20–40% of critically ill patients will have renal insufficiency at the time of admission or will develop it during their ICU stay, depending on the definition of renal insufficiency and the case mix of the ICU. Such patients are also predisposed to bleeding because of uremic platelet dysfunction, typically multiple comorbidities, coagulopathies and frequent concomitant treatment with antiplatelet or anticoagulant agents.

The impairment in hemostasis in uremic patients is multifactorial and includes physiological defects in platelet hemostasis, an imbalance of mediators of normal endothelial function and frequent comorbidities such as vascular disease, anemia and the frequent need for medical interventions required to treat such comorbidities. Physiologic alterations in uremia include:

  • decreased platelet glycoprotein IIb–IIIa binding to both von Willebrand factor (vWf) and fibrinogen, causing an impairment in platelet aggregation;
  • increased prostacyclin and nitric oxide production, both potent inhibitors of platelet activation and vasoconstriction; and
  • decreased levels of platelet adenosine diphosphate (ADP) and serotonin, causing an impairment in platelet secretion.

In addition to other factors, small peptides containing the RGD (Arg-Gly-Asp) sequence of amino acids have been shown to be inhibitors of platelet aggregation that act by competing with vWf and fibrinogen for binding to the glycoprotein IIb–IIIa receptor.

Conclusion

ICU patients have dynamic risks of thrombosis and bleeding. Invasive procedures may require temporary interruption of anticoagulants. Consequently, approaches to thromboprophylaxis require daily reevaluation.

(Cook DJ, Douketis J, Arnold D, and Crowther MA. Bleeding and venous thromboembolism in the critically ill with emphasis on patients with renal insufficiency. Curr Opin Pulm Med 2009;15:455–462.)

Epicrisis

I have covered a large amount of material on one of the most complex systems in medicine, and still not comprehensive, with a sufficient dash of repetition.  The task is to have some grasp of the cell-mediated imbalances inherent if coagulation and bleeding disorders.  The key points are:

  • inflammation and oxidative stress invariably lurk in the background
  • the Y-shaped model with an extrinsic, intrinsic, and common pathway has no basis in understanding
  • the current model is based on a cell-mediated concept of endothelial damage and platelet-endothelial interaction
  • the model has 3 components: Initiation, Amplification, Propagation
  • NO and prostacyclin have key roles in the process
  • The plasma proteins involved are in the serine-protease class of enzymes
  • The conversion of Protein C to APC has a central role as anti-coagulant

Part II goes into organ aystem abnormalities that are all related to impairment of the Nitric Oxide balance and dual platelet-endothelial roles.

Part III will explore therapeutic targets and opportunities.

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