Genetic and pharmacological modifications of thrombin formation in apolipoprotein e-deficient mice determine atherosclerosis severity and atherothrombosis onset in a neutrophil-dependent manner.

BACKGROUND: Variations in the blood coagulation activity, determined genetically or by medication, may alter atherosclerotic plaque progression, by influencing pleiotropic effects of coagulation proteases. Published experimental studies have yielded contradictory findings on the role of hypercoagulability in atherogenesis. We therefore sought to address this matter by extensively investigating the in vivo significance of genetic alterations and pharmacologic inhibition of thrombin formation for the onset and progression of atherosclerosis, and plaque phenotype determination. METHODOLOGY/PRINCIPAL FINDINGS: We generated transgenic atherosclerosis-prone mice with diminished coagulant or hypercoagulable phenotype and employed two distinct models of atherosclerosis. Gene-targeted 50% reduction in prothrombin (FII(-/WT):ApoE(-/-)) was remarkably effective in limiting disease compared to control ApoE(-/-) mice, associated with significant qualitative benefits, including diminished leukocyte infiltration, altered collagen and vascular smooth muscle cell content. Genetically-imposed hypercoagulability in TM(Pro/Pro):ApoE(-/-) mice resulted in severe atherosclerosis, plaque vulnerability and spontaneous atherothrombosis. Hypercoagulability was associated with a pronounced neutrophilia, neutrophil hyper-reactivity, markedly increased oxidative stress, neutrophil intraplaque infiltration and apoptosis. Administration of either the synthetic specific thrombin inhibitor Dabigatran etexilate, or recombinant activated protein C (APC), counteracted the pro-inflammatory and pro-atherogenic phenotype of pro-thrombotic TM(Pro/Pro):ApoE(-/-) mice. CONCLUSIONS/SIGNIFICANCE: We provide new evidence highlighting the importance of neutrophils in the coagulation-inflammation interplay during atherogenesis. Our findings reveal that thrombin-mediated proteolysis is an unexpectedly powerful determinant of atherosclerosis in multiple distinct settings. These studies suggest that selective anticoagulants employed to prevent thrombotic events may also be remarkably effective in clinically impeding the onset and progression of cardiovascular disease.

Anticoagulant therapy in critical organ ischaemia/reperfusion injury.

Ischaemia/reperfusion (I/R) injury is central to a number of pathologies including myocardial infarction and stroke. Several cellular processes are involved in the progress of I/R injury, involving complex interactions between coagulation and inflammatory or apoptotic processes. Besides for their anti-coagulant function, anticoagulant proteins such as activated protein C (APC), active site inhibited factor VIIa (ASIS), tissue factor pathway inhibitor (TFPI), and antithrombin (AT) are also known for their anti-inflammatory or cell protective effects. This review gives an overview of the application of these anti-coagulants in several animal models of I/R injury in critical organs and describes the effects of these proteins on cellular processes including inflammation and apoptosis. The future testing of mutant forms of some of these inhibitors including APC in a clinical setting should be actively explored.

Activated protein C protects against myocardial ischemia/ reperfusion injury via inhibition of apoptosis and inflammation.

OBJECTIVE: In spite of major advances in reperfusion therapy for patients presenting with acute coronary syndrome, long-term morbidity is still substantial. A limitation of initial treatment of myocardial ischemia is the lack of prevention of ischemia/reperfusion (I/R) injury. Activated protein C (APC), a crucial mediator in the coagulation process, plays a prominent role in the crosstalk between coagulation and inflammation and provides cytoprotective effects via inhibition of apoptosis and inflammation in several human and animal studies. METHODS AND RESULTS: APC was administered in an animal model for myocardial I/R. APC largely inhibited early myocardial I/R injury after varying reperfusion times, an effect that was absent on administration of heparin, a nonspecific anticoagulant agent. The protective effects of APC were absent in case of absence or blockade of protease activated receptor-1 (PAR-1), indicating a critical role for PAR-1 in this process. Furthermore, we showed a strong antiapoptotic effect of APC in the early phase of reperfusion combined with an antiinflammatory effect at an early stage (IL-6), as well as at a later stage (leukocyte infiltration). CONCLUSIONS: APC exerts strong protective effects on early myocardial I/R injury, primarily via inhibition of apoptosis and inflammation, which are regulated via PAR-1.

Contribution of platelet glycoprotein VI to the thrombogenic effect of collagens in fibrous atherosclerotic lesions.

Collagens (types I and III) are among the strongest thrombus-forming components of the vascular subendothelium. We compared the thrombogenic effects of four collagen-containing advanced atherosclerotic lesions with those of purified types I and III collagen fibers. Cell-free homogenates from the human plaques effectively promoted platelet adhesion and aggregate formation under high-shear flow conditions, as well as exposure of procoagulant phosphatidylserine (PS) on platelets. With all plaques, blocking of the glycoprotein VI (GPVI) receptor for collagen abolished aggregation and PS exposure. Blocking of platelet ADP receptors resulted in similar, but less complete inhibitory effects. Type I collagen was more potent than type III collagen in inducing aggregation and PS exposure under flow, via stimulation of GPVI and ADP receptors. Type I collagen also more strongly enhanced thrombin generation with platelets and tissue factor, again via GPVI activation and PS exposure. The plaque material enhanced thrombin generation, partly due to the presence of tissue factor and partly via GPVI and ADP receptors. Together, these results indicate that in advanced plaques collagen type I is a major trigger of thrombus formation and PS exposure, acting via GPVI and ADP release, while tissue factor directly enhances coagulation.