Jevgenia Zilberman-Rudenko

Coagulation Factor XI Promotes Distal Platelet Activation and Single Platelet Consumption in the Bloodstream Under Shear Flow

Objective— Coagulation factor XI (FXI) has been shown to contribute to thrombus formation on collagen or tissue factor–coated surfaces in vitro and in vivo by enhancing thrombin generation. Whether the role of the intrinsic pathway of coagulation is restricted to the local site of thrombus formation is unknown. This study was aimed to determine whether FXI could promote both proximal and distal platelet activation and aggregate formation in the bloodstream. Approach and Results— Pharmacological blockade of FXI activation or thrombin activity in blood did not affect local platelet adhesion, yet reduced local platelet aggregation, thrombin localization, and fibrin formation on immobilized collagen and tissue factor under shear flow, ex vivo. Downstream of the thrombus formed on immobilized collagen or collagen and 10 pmol/L tissue factor, platelet CD62P expression, microaggregate formation, and progressive platelet consumption were significantly reduced in the presence of FXI function-blocking antibodies or a thrombin inhibitor in a shear rate– and time-dependent manner. In a non-human primate model of thrombus formation, we found that inhibition of FXI reduced single platelet consumption in the bloodstream distal to a site of thrombus formation. Conclusions— This study demonstrates that the FXI–thrombin axis contributes to distal platelet activation and procoagulant microaggregate formation in the blood flow downstream of the site of thrombus formation. Our data highlight FXI as a novel therapeutic target for inhibiting distal platelet consumption without affecting proximal platelet adhesion.

Hypoxia-inducible Factor 3-alpha Expression is Associated With the Stable Chondrocyte Phenotype

The hypoxia‐inducible factors HIF‐1α and HIF‐2α are important regulators of the chondrocyte phenotype but little is known about HIF‐3α in cartilage. The objective of this study was to characterize HIF‐3α (HIF3A) expression during chondrocyte differentiation in vitro and in native cartilage tissues. HIF3A, COL10A1, and MMP13 were quantified in mesenchymal stem cells (MSCs) and articular chondrocytes from healthy and osteoarthritic (OA) tissue in three‐dimensional cultures and in human embryonic epiphyses and adult articular cartilage. HIF3A was found to have an inverse association with hypertrophic markers COL10A1 and MMP13 in chondrogenic cells and tissues. In healthy chondrocytes, HIF3A was induced by dexamethasone and increased during redifferentiation. By comparison, HIF3A expression was extremely low in chondrogenically differentiated MSCs expressing high levels of COL10A1 and MMP13. HIF3A was also lower in redifferentiated OA chondrocytes than in healthy chondrocytes. In human embryonic epiphyseal tissue, HIF3A expression was lowest in the hypertrophic zone. Distinct splice patterns were also found in embryonic cartilage when compared with adult articular cartilage and redifferentiated chondrocytes. These in vitro and in vivo findings suggest that HIF3A levels are indicative of the hypertrophic state of chondrogenic cells and one or more splice variants may be important regulators of the chondrocyte phenotype.

Biorheology of Platelet Activation in the Bloodstream Distal to Thrombus Formation

Thrombus growth at the site of vascular injury is mediated by the sequential events of platelet recruitment, activation and aggregation concomitant with the initiation of the coagulation cascade, resulting in local thrombin generation and fibrin formation. While the biorheology of a localized thrombus formation has been well studied, it is unclear whether local sites of thrombin generation propagate platelet activation within the bloodstream. In order to study the physical biology of platelet activation downstream of sites of thrombus formation, we developed a platform to measure platelet activation and microaggregate formation in the bloodstream. Our results show that thrombi formed on collagen and tissue factor promote activation and aggregation of platelets in the bloodstream in a convection-dependent manner. Pharmacological inhibition of the coagulation factors (F) X, XI or thrombin dramatically reduced the degree of distal platelet activation and microaggregate formation in the bloodstream without affecting the degree of local platelet deposition and aggregation on a surface of immobilized collagen. Herein we describe the development and an example of the utility of a platform to study platelet activation and microaggregate formation in the bloodstream (convection-limited regime) relative to the local site of thrombus formation.

Prothrombotic skeletal muscle myosin directly enhances prothrombin activation by binding factors Xa and Va.

To test the hypothesis that skeletal muscle myosins can directly influence blood coagulation and thrombosis, ex vivo studies of the effects of myosin on thrombogenesis in fresh human blood were conducted. Addition of myosin to blood augmented the thrombotic responses of human blood flowing over collagen-coated surfaces (300 s-1 shear rate). Perfusion of human blood over myosin-coated surfaces also caused fibrin and platelet deposition, evidencing myosins thrombogenicity. Myosin markedly enhanced thrombin generation in both platelet-rich plasma and platelet-poor plasma, indicating that myosin promoted thrombin generation in plasma primarily independent of platelets. In purified reaction mixtures composed only of factor Xa, factor Va, prothrombin, and calcium ions, myosin greatly enhanced prothrombinase activity. The Gla domain of factor Xa was not required for myosins prothrombinase enhancement. When binding of purified clotting factors to immobilized myosin was monitored using biolayer interferometry, factors Xa and Va each showed favorable binding interactions. Factor Va reduced by 100-fold the apparent Kd of myosin for factor Xa (Kd ∼0.48 nM), primarily by reducing koff, indicating formation of a stable ternary complex of myosin:Xa:Va. In studies to assess possible clinical relevance for this discovery, we found that antimyosin antibodies inhibited thrombin generation in acute trauma patient plasmas more than in control plasmas (P = .0004), implying myosin might contribute to acute trauma coagulopathy. We posit that myosin enhancement of thrombin generation could contribute either to promote hemostasis or to augment thrombosis risk with consequent implications for myosins possible contributions to pathophysiology in the setting of acute injuries.

Utility of microfluidic devices to study the platelet–endothelium interface

Abstract The integration of biomaterials and understanding of vascular biology has led to the development of perfusable endothelialized flow models, which have been used as valuable tools to study the platelet–endothelium interface under shear. In these models, the parameters of geometry, compliance, biorheology, and cellular complexity are varied to recapitulate the physical biology of platelet recruitment and activation under physiologically relevant conditions of blood flow. In this review, we summarize the mechanistic insights learned from perfusable microvessel models and discuss the potential utility as well as challenges of endothelialized microfluidic devices to study platelet function in the bloodstream in vitro.

Effect of Pneumatic Tubing System Transport on Platelet Apheresis Units

Platelet apheresis units are transfused into patients to mitigate or prevent bleeding. In a hospital, platelet apheresis units are transported from the transfusion service to the healthcare teams via two methods: a pneumatic tubing system (PTS) or ambulatory transport. Whether PTS transport affects the activity and utility of platelet apheresis units is unclear. We quantified the gravitational forces and transport time associated with PTS and ambulatory transport within our hospital. Washed platelets and supernatants were prepared from platelet apheresis units prior to transport as well as following ambulatory or PTS transport. For each group, we compared resting and agonist-induced platelet activity and platelet aggregate formation on collagen or von Willebrand factor (VWF) under shear, platelet VWF-receptor expression and VWF multimer levels. Subjection of platelet apheresis units to rapid acceleration/deceleration forces during PTS transport did not pre-activate platelets or their ability to activate in response to platelet agonists as compared to ambulatory transport. Platelets within platelet apheresis units transported via PTS retained their ability to adhere to surfaces of VWF and collagen under shear, although platelet aggregation on collagen and VWF was diminished as compared to ambulatory transport. VWF multimer levels and platelet GPIb receptor expression was unaffected by PTS transport as compared to ambulatory transport. Subjection of platelet apheresis units to PTS transport did not significantly affect the baseline or agonist-induced levels of platelet activation as compared to ambulatory transport. Our case study suggests that PTS transport may not significantly affect the hemostatic potential of platelets within platelet apheresis units.

Utility and development of microfluidic platforms for platelet research

The formation of a hemostatic plug to staunch blood loss at sites of vascular injury relies on the dynamical processes of platelet recruitment and activation of the coagulation cascade in the setting of the biorheology of blood flow.[1–3] Thus, elucidation of the molecular mechanisms of thrombus formation has relied on the use of engineering principles to design platforms to study platelet cell biology under physiologically relevant shear flow conditions. Historically this necessitated the use of custom-made parallel-plate flow chambers coupled with fluorescent or phase-contrast microscopy, restricting these studies to cell biology or biochemistry laboratories that collaborated with engineering and physics departments.[4–6] Recent advances in fabrication, standardization and commercialization of microfluidics has now allowed for the widespread distribution of microfluidic platforms amongst the platelet research community. Moreover, the silos or cell biology, biochemistry, engineering and physics are rapidly dissolving, with the composition of research teams now spanning data science, quantitative biology, and translational medicine. This review series presents an overviewof the history, current use and future applications of microfluidic platforms for platelet research. The shear-dependent binding of the platelet receptor glycoprotein (GP)Ib to von Willebrand Factor (VWF) is requisite for the initial step of platelet recruitment to exposed subendothelial extracellular matrix proteins under flow.[7,8] The review by Hastings et al. describes the use of microfluidic devices for the study of biophysics of platelet biology under shear, with the review of Zhang et al. focusing on the utility of microfluidics to study GPIb-VWF interactions. Concomitant with platelet recruitment is activation of the coagulation cascade to generate thrombin and form fibrin. The review by Nagy et al. describes the use of microfluidic platforms to study the role of the platelet surface as a site of catalysis for thrombin generation under physiologically relevant shear flow conditions. The review by ZilbermanRudenko et al. then explores the use of endothelialized microfluidic platforms to combine the study of platelet recruitment and activation of the coagulation cascade in the physiological context of vascular cells and shear. It has been shown that transfusion of platelets during resuscitation drastically improves trauma patient survival.[9–11] Inversely, increased platelet counts and activity is deleterious in the setting of cardiovascular disease or cancer.[12–14] Yet, standard clinical tests provide incomplete guidance for selecting patients who might benefit from platelet transfusion or antiplatelet therapy, balancing safety with efficacy.[15–19] Herein the reviews by Li et al. and Schoeman et al. discuss the utility of microfluidic technologies which mimic the biorheology of the vasculature to interrogate platelet response to therapy, assess hemostasis and diagnose clinical bleeding defects. Finally, the review by Thon et al. introduces the use of microfluidic platforms as an organ-on-the-chip bioinspired approach to generate platelets ex vivo, with potential applications in transfusion medicine. Taken together, the goal of this series of reviews is to provide the readership of Platelets a state-of-the-art overview of the development and use of microfluidic platforms to study and assess the function of platelets in health and disease.

Removal of the C-Terminal Domains of ADAMTS13 by Activated Coagulation Factor XI induces Platelet Adhesion on Endothelial Cells under Flow Conditions

Platelet recruitment to sites of vascular injury is mediated by von Willebrand factor (VWF). The shear-induced unraveling of ultra-large VWF multimers causes the formation of a “stringlike” conformation, which rapidly recruits platelets from the bloodstream. A disintegrin and metalloproteinase with a thrombospondin type 1 motif, member 13 (ADAMTS13) regulates this process by cleaving VWF to prevent aberrant platelet adhesion; it is unclear whether the activity of ADAMTS13 itself is regulated. The serine proteases α-thrombin and plasmin have been shown to cleave ADAMTS13. Based on sequence homology, we hypothesized that activated coagulation factor XI (FXIa) would likewise cleave ADAMTS13. Our results show that FXIa cleaves ADAMTS13 at the C-terminal domains, generating a truncated ADAMTS13 with a deletion of part of the thrombospondin type-1 domain and the CUB1-2 domains, while α-thrombin cleaves ADAMTS13 near the CUB1-2 domains and plasmin cleaves ADAMTS13 at the metalloprotease domain and at the C-terminal domain. Using a cell surface immunoassay, we observed that FXIa induced the deletion of the CUB1-2 domains from ADAMTS13 on the surface of endothelial cells. Removal of the C-terminal domain of ADAMTS13 by FXIa or α-thrombin caused an increase in ADAMTS13 activity as measured by a fluorogenic substrate (FRETS) and blocked the ability of ADAMTS13 to cleave VWF on the endothelial cell surface, resulting in persistence of VWF strands and causing an increase in platelet adhesion under flow conditions. We have demonstrated a novel mechanism for coagulation proteinases including FXIa in regulating ADAMTS13 activity and function. This may represent an additional hemostatic function by which FXIa promotes local platelet deposition at sites of vessel injury.

Differential Roles for the Coagulation Factors XI and XII in Regulating the Physical Biology of Fibrin.

In the contact activation pathway of the coagulation, zymogen factor XII (FXII) is converted to FXIIa, which triggers activation of FXI leading to the activation of FIX and subsequent thrombin generation and fibrin formation. Feedback activation of FXI by thrombin has been shown to promote thrombin generation in a FXII-independent manner and FXIIa can bypass FXI to directly activate FX and prothrombin in the presence of highly negatively charged molecules, such as long-chain polyphosphates (LC polyP). We sought to determine whether activation of FXII or FXI differentially regulate the physical biology of fibrin formation. Fibrin formation was initiated with tissue factor, ellagic acid (EA), or LC polyP in the presence of inhibitors of FXI and FXII. Our data demonstrated that inhibition of FXI decreased the rate of fibrin formation and fiber network density, and increased the fibrin network strength and rate of fibrinolysis when gelation was initiated via the contact activation pathway with EA. FXII inhibition decreased the fibrin formation and fibrin density, and increased the fibrinolysis rate only when fibrin formation was initiated via the contact activation pathway with LC polyP. Overall, we demonstrate that inhibition of FXI and FXII distinctly alter the biophysical properties of fibrin.