Our research project is designed to test our central hypothesis that activation of the contact factor pathway contributes to pathologic mechanisms that lead to vascular dysfunction, thrombin generation, and inflammatory responses during sepsis induced by specific infectious pathogens. Sepsis is a sequel of molecular and cellular events that perpetually change over the course of this life threatening disease condition. Failure of vasoregulation, poor tissue perfusion, edema, and systemic hypotension are hallmarks of severe sepsis, and, by triggering a cardiopulmonary and vascular collapse, leads to death when left untreated. Severe sepsis may be accompanied by disseminated intravascular coagulation (DIC) that aggravates the vasodilation and edema-associated tissue perfusion insufficiency. DIC can lead to the failure of hemostasis, and subsequent bleeding due to the consumption of coagulation factors and platelets. We focus on the contact activation pathway, because 1) there appears to be a causal relationship between pathological activation of the coagulation factor XII and the poor prognosis of some forms of sepsis, and 2) targeting the contact activation pathway as a therapeutic approach is unlikely to have detrimental consequences for the host. We will define the role of the molecular steps in the contact pathway of coagulation in the development and outcomes of severe sepsis. We will define the roles of FXII (Aim 1) and its procoagulant substrate FXI (Aim 2), and will translate our mechanistic in vitro and ex vivo studies to define th pathological role of activation of the contact pathway in 2 distinct primate models of severe sepsis. The potential translational relevance of our project will be the identification of safe and druggable molecular targets and mechanisms within the contact activation pathway. Our research may ultimately provide rationale for the development of selective contact activation pathway inhibitors that could benefit sepsis patients infected with pathogens that exploit the contact activation pathway for virulence. Importantly, this approach would not do harm to patients whose infection is controlled by endogenous extrinsic pathway-dependent fibrin formation as part of the innate immune response.
Sepsis is a prevalent, infection-induced acute severe inflammatory response syndrome that typically progresses into hypotension, failure of vasoregulation, insufficient organ perfusion and death within hours to days when left untreated. There is an unmet medical need for the development of safe and effective treatments for sepsis. Our research is designed to identify and characterize novel druggable molecular and cellular mechanisms that arise in sepsis and detrimentally contribute to a pathological state with excess vasodilation, increased blood coagulation, and reduced protective mechanisms that increase pathogen virulence.
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