Paula B. Tracy

Factor V (Quebec): a bleeding diathesis associated with a qualitative platelet Factor V deficiency.

Studies were performed on a French-Canadian family afflicted with a bleeding disorder exhibiting an autosomal dominant inheritance pattern and a severe bleeding diathesis after trauma. Clinical laboratory coagulation tests were unimpressive; the only persistent abnormalities include mild thrombocytopenia and moderately reduced Factor V clotting activities. Some individuals had prolonged Stypven times when platelet-rich plasma was used, suggesting that their platelets could not support functional prothrombinase complex assembly. Detailed studies were performed by use of plasma and isolated, washed platelets from a sister and brother. Bioassay data indicate that both individuals had Factor V activities of approximately 40 and 36% of normal, respectively. A comparison of the Factor V radioimmunoassay and bioassay data on the brothers plasma indicated that the circulating amount of Factor V functional activity was low relative to Factor V antigen concentration (approximately 65-75%). In both individuals, the platelet Factor V functional activities were extremely low (2-4%) relative to antigen levels present as determined by radioimmunoassay. These discrepancies between Factor V activities and antigen concentration do not appear to be due to an unstable Factor V molecule or to the presence of a Factor V or Factor Va inhibitor or inactivator. Kinetics of prothrombin activation by use of purified clotting factors indicated that thrombin-activated platelets from both individuals supported prothrombinase complex assembly identical to controls in the presence of added purified Factor Va. Consequently, their bleeding diathesis appears to reflect their platelet, rather than their plasma, Factor V activity. These results suggest that platelet Factor V is an essential component in maintaining stable and prolonged hemostasis after trauma.

Differential Effects of Anticoagulants on the Activation of Platelets Ex Vivo

BACKGROUND Because activation of platelets and of the coagulation system are interdependent mediators of thrombosis, platelet activation was characterized in whole blood in the presence of anticoagulants used to assess platelet function in vitro or as treatment for patients with occlusive arterial disease. METHODS AND RESULTS Blood was anticoagulated alone or in combination with citrate, ethylenediaminetetraacetatic acid, corn trypsin inhibitor (CTI, an inhibitor of activated factor XII), heparin, enoxaparin, recombinant tick anticoagulant peptide (rTAP), or recombinant hirudin. Platelet activation in response to adenosine diphosphate (ADP) or collagen was detected by assay of P-selectin on the platelet surface delineated by flow cytometry. Although minimal activation was seen without ADP, the fraction of platelets expressing P-selectin in response to ADP was greatest in blood anticoagulated with citrate compared with CTI and all other anticoagulants. ADP-induced platelet activation was greater in blood anticoagulated with heparin compared with an equipotent anti-Xa concentration of enoxaparin. More variable results were seen with collagen, but platelet activation in the presence of citrate was greater than that with CTI. CONCLUSIONS Interpretation of assays of inhibition of platelet activation by potentially therapeutic agents in vitro requires consideration of the effects of anticoagulants used. In addition, anticoagulants other than standard heparin may potentiate efficacy of antiplatelet drugs.

Platelets, leukocytes, and coagulation.

Considerable data now support the hypothesis that platelets actively regulate the propagation of coagulation by (1) expressing specific, high-affinity receptors for coagulation proteases, zymogens, and cofactors; (2) protecting the bound coagulation enzymes from inactivation/inhibition; (3) restricting coagulant activity to the site of vascular injury; and (4) amplifying the initiating stimulus to lead to explosive thrombin generation. Thrombin generation is sustained at the site of vascular injury by the recruitment of circulating monocytes and neutrophils to the growing thrombus via the interaction of PSGL-1, which is constitutively expressed by leukocytes, with P-selectin, which is expressed by activated platelets. Unique among cells, monocytes can provide the appropriate membrane surface for the assembly and function of all the coagulation complexes required for tissue factor–initiated thrombin production. More studies are required to further delineate the roles of neutrophils and lymphocytes in the procoagulant response. This review will discuss the recent investigations and controversies regarding the various mechanisms by which platelets and leukocytes function in, and regulate, thrombin generation.

Plasma Lipoproteins Support Prothrombinase and Other Procoagulant Enzymatic Complexes

The prothrombinase complex (factor [F]Xa, FVa, calcium ions, and lipid membrane) converts prothrombin to thrombin (FIIa). To determine whether plasma lipoproteins could provide a physiologically relevant surface, we determined the rates of FIIa production by using purified human coagulation factors, and isolated fasting plasma lipoproteins from healthy donors. In the presence of 5 nmol/L FVa, 5 nmol/L FXa, and 1.4 micromol/L prothrombin, physiological levels of very low density lipoprotein (VLDL) (0.45 to 0.9 mmol/L triglyceride, or 100 to 200 micromol/L phospholipid) yielded rates of 2 to 8 nmol Flla x L(-1) x s(-1) in a donor-dependent manner. Low density lipoprotein (LDL) and high density lipoprotein (HDL) also supported prothrombinase but at much lower rates (< or =1.0 nmol FIIa x L(-1) x s[-1]). For comparison, VLDL at 2 mmol/L triglyceride yielded approximately 50% the activity of 2X10(8) thrombin-activated platelets per milliliter. Although the FIIa production rate was slower on VLDL than on synthetic phosphatidylcholine/phosphatidylsenne vesicles (approximately 50 nmol FIIa x L(-1) x s[-1]), the prothrombin Km values were similar, 0.8 and 0.5 micromol/L, respectively. Extracted VLDL lipids supported rates approaching those of phosphatidylcholine/phosphatidylserine vesicles, indicating the importance of the intact VLDL conformation. However, the presence of VLDL-associated, factor-specific inhibitors was ruled out by titration experiments, suggesting a key role for lipid organization. VLDL also supported FIIa generation in an assay system comprising 0.1 nmol/L FVIIa; 0.55 nmol/L tissue factor; physiological levels of FV, FVIII, FIX, and FX; and prothrombin (3 nmol/L FIIa x L(-1) x s[-1]). These results indicate that isolated human VLDL can support all the components of the extrinsic coagulation pathway, yielding physiologically relevant rates of thrombin generation in a donor-dependent manner. This support is dependent on the intact lipoprotein structure and does not appear to be regulated by specific VLDL-associated inhibitors. Further studies are needed to determine the extent of this activity in vivo.

Human Brain Pericytes Differentially Regulate Expression of Procoagulant Enzyme Complexes Comprising the Extrinsic Pathway of Blood Coagulation

After vascular injury, pericytes may function in blood coagulation events that lead to thrombin formation due to their subendothelial location in the microvasculature. Pericytes from human cerebral cortex microvessels were isolated and characterized, and their ability to express and regulate procoagulant enzyme complexes was determined. Tissue factor was detected on the cell surface of cultured human brain pericytes by immunocytochemistry and was shown to form a functional complex with factor (F) VIIa to effect both FIX and FX activation. Treatment of pericytes with the calcium ionophore A23187 increased the observed tissue factor activity twofold to fivefold, which was shown to be due to an enhancement of cofactor activity and not the release of endogenous antigen stores. Pericytes also provided the appropriate membrane surface required for the assembly of a functional prothrombinase complex, so that in the presence of FVa and FXa, they effected thrombin formation 50 to 100 times faster than any other cell examined to date. In marked contrast to observations in other cell systems, pericyte expression of prothrombinase activity remained unaltered after treatment with A23187. As has been shown for platelets, the membrane receptor on pericytes for FXa assembly into the prothrombinase complex appears to at least partially consist of the FXa receptor effector cell protease receptor-1. These combined data indicate that pericytes can activate and propagate the coagulant response through the extrinsic pathway and that the activities of the required enzyme complexes can be differentially regulated in response to agonist stimulation. These observations support the concept that pericytes may play an important role in regulating coagulation events after cerebrovascular injury.

Unique in Vivo Modifications of Coagulation Factor V Produce a Physically and Functionally Distinct Platelet-derived Cofactor CHARACTERIZATION OF PURIFIED PLATELET-DERIVED FACTOR V/Va

Platelet- and plasma-derived factor Va (FVa) serve essential cofactor roles in prothrombinase-catalyzed thrombin generation. Platelet-derived FV/Va, purified from Triton X-100 platelet lysates was composed of a mixture of polypeptides ranging from ∼40 to 330 kDa, mimicking those visualized by Western blotting of platelet lysates and releasates with anti-FV antibodies. The purified, platelet-derived protein expressed significant cofactor activity such that thrombin activation led to only a 2–3-fold increase in cofactor activity yet expression of a specific activity identical to that of purified, plasma-derived FVa. Physical and functional differences between the two cofactors were identified. Purified, platelet-derived FVa was 2–3-fold more resistant to activated protein C-catalyzed inactivation than purified plasma-derived FVa on the thrombin-activated platelet surface. The heavy chain subunit of purified, platelet-derived FVa contained only a fraction (∼10–15%) of the intrinsic phosphoserine present in the plasma-derived FVa heavy chain and was resistant to phosphorylation at Ser692 catalyzed by either casein kinase II or thrombin-activated platelets. MALDI-TOF mass spectrometric analyses of tryptic digests of platelet-derived FV peptides detected an intact heavy chain uniquely modified on Thr402 with an N-acetylglucosamine or N-acetylgalactosamine, whereas Ser692 remained unmodified. N-terminal sequencing and MALDI-TOF analyses of platelet-derived FV/Va peptides identified the presence of a full-length heavy chain subunit, as well as a light chain subunit formed by cleavage at Tyr1543 rather than Arg1545 accounting for the intrinsic levels of cofactor activity exhibited by native platelet-derived FVa. These collective data are the first to demonstrate physical differences between the two FV cofactor pools and support the hypothesis that, subsequent to its endocytosis by megakaryocytes, FV is modified to yield a platelet-derived cofactor distinct from its plasma counterpart.

[21] Factor V

Publisher Summary This chapter constitutes a report on the procedures currently used in this laboratory to isolate unactivated factor V from bovine plasma. In addition, a method using conventional procedures for the partial purification of factor V from human plasma is presented. Factor V is extraordinarily sensitive to proteolysis and can be both activated and inactivated by enzymes that may accompany the coagulation process and subsequent events. Thus proper collection of blood is essential for the isolation of the native undegraded form of factor V. The method of collection that optimizes the likelihood of successful isolation of factor V is venipuncture into a combination of coagulation inhibitors. This is followed by a description of an affinity technique, based on the use of an immobilized monoclonal hybridoma antibody, that yields electrophoretically homogeneous human factor V. The immobilized antibody has properties such that it tightly and specifically interacts with human factor V under conditions of physiological ionic strength, but dissociates at elevated ionic strength, thus allowing its use as an affinity adsorbant.

Tissue factor pathway inhibitor-alpha inhibits prothrombinase during the initiation of blood coagulation

Significance The generation of thrombin by prothrombinase, a complex composed of activated (a) factors X (FXa) and V (FVa), is a final step in blood coagulation. We demonstrate that tissue factor pathway inhibitor (TFPI) blocks thrombin generation by prothrombinase at physiologically relevant rates and concentrations, but only during the initiation of clot formation. TFPI mediates this inhibitory activity through two high-affinity interactions, one with FXa and one with FVa. This is the first description of an endogenous human protein that inhibits prothrombinase under physiological conditions and may prevent a full thrombotic response to subthreshold coagulant stimuli that otherwise could occlude blood vessels. It provides unique understanding of thrombotic disorders and has important implications for development of anti-TFPI agents to treat hemophilia. Tissue factor (TF) pathway inhibitor (TFPI) is a well-characterized activated factor X (FXa)-dependent inhibitor of TF-initiated coagulation produced in two alternatively spliced isoforms, TFPIα and TFPIβ. The TFPIα C terminus has a basic sequence nearly identical to a portion of the factor V (FV) B domain necessary for maintaining FV in an inactive conformation via interaction with an acidic region of the B domain. We demonstrate rapid inhibition of prothrombinase by TFPIα mediated through a high-affinity exosite interaction between the basic region of TFPIα and the FV acidic region, which is retained in FXa-activated FVa and platelet FVa. This inhibitory activity is not mediated by TFPIβ and is lost upon removal of the acidic region of FVa by thrombin. The data identify a previously undescribed, isoform-specific anticoagulant function for TFPIα and are a unique description of physiologically relevant inhibition of prothrombinase. These findings, combined with previous descriptions of differential expression patterns of TFPIα and TFPIβ in platelets and endothelial cells, suggest that the TFPI isoforms may act through distinct mechanisms to inhibit the initial stages of intravascular coagulation, with TFPIβ acting to dampen TF expressed on the surface of vascular cells, whereas TFPIα dampens the initial prothrombinase formed on the activated platelet surface.

Megakaryocytes endocytose and subsequently modify human factor V in vivo to form the entire pool of a unique platelet‐derived cofactor

Summary.  Factor Va (FVa), derived from plasma or released from stimulated platelets, is the essential cofactor in thrombin production catalyzed by the prothrombinase complex. Plasma‐derived factor V (FV) is synthesized in the liver. The source(s) of the platelet‐derived cofactor remains in question. We identified a patient homozygous for the FVLeiden mutation, who received a liver transplant from a homozygous wild‐type FV donor. Eighteen days post‐transplant, phenotypic analysis of the patients platelet‐derived FV indicated that the platelets were acquiring wild‐type FV, consistent with the temporal differentiation of megakaryocytes and subsequent platelet production. Nine months post‐transplant, the platelet‐derived FV pool consisted entirely of wild‐type FV. Consequently, megakaryocyte endocytosis of plasma‐derived FV must account for the entire platelet‐derived pool, because blood‐borne platelets cannot bind or endocytose FV. Subsequent to this endocytic process, the patients platelet‐derived FV was cleaved to a partially active cofactor, and rendered resistant to phosphorylation catalyzed by a platelet‐associated kinase, and hence less susceptible to activated protein C‐catalyzed inactivation. These data provide the first in vivo demonstration of an endocytosed plasma protein undergoing intracellular modifications that alter its function. This process results in the sequestration of active FVa within the platelet compartment, poised for immediate action subsequent to release from platelets at a site of injury.

Intact platelet membranes, not platelet-released microvesicles, support the procoagulant activity of adherent platelets.

The possibility that platelets release microvesicles on adherence to either von Willebrand factor (vWf) or collagen was examined by flow cytometry analysis of the supernatant above layers of adherent platelets. No microvesicle release was detected as a result of adherence to vWf or to collagen, a known platelet agonist. Approximately 8% of the total platelet mass was released as microvesicles after thrombin stimulation of the vWf- or collagen-adherent platelets. A larger portion of the vWf-adherent platelet membranes (approximately 21%) was released as microvesicles subsequent to platelet stimulation with the nonphysiological agonist calcium ionophore A23187. Calpeptin, a calpain inhibitor, had no effect on microvesicle release, suggesting that calpain proteolysis of platelet cytoskeletal proteins was not responsible for microvesicle shedding under the conditions studied. Examination of the vWf-adherent platelets by scanning electron microscopy showed that virtually no microvesicles bound to exposed vWf multimers. No microvesicle binding to the adherent platelets was observed, indicating that the majority of the microvesicles were shed from the platelet and vWf surface on platelet activation. The ability of the microvesicle population to support procoagulant activity was measured with a prothrombinase activity assay and was compared with the activity supported by the adherent platelet membranes. More than 85% of the total prothrombinase activity remained associated with the adherent platelet membranes, both for unstimulated platelets and platelets stimulated with physiological agonists. Furthermore, the residual activity found in the buffer fraction containing detached platelets and any released microvesicles could be attributed to the detached platelets. No activity could be attributed to the microvesicles, as thrombin stimulation of either vWf-or collagen-adherent platelets did not promote increased procoagulant activity relative to the unstimulated adherent platelets, even though microvesicle release was detected as a result of agonist addition. Neither full platelet activation nor microvesicle shedding played an essential role in generating procoagulant activity in the adherent platelet system.