Sinh Tran

Effects of Prothrombin on the Individual Activated Protein C-mediated Cleavages of Coagulation Factor Va

The factor Va (FVa) inactivation by activated protein C (APC), mediated by cleavages at Arg306 and Arg506 in FVa, is inhibited by both factor Xa (FXa) and prothrombin. Although FXa is known to specifically inhibit the Arg506 cleavage, the effect of prothrombin has not been confined to one cleavage site. We used recombinant FV variants, FV:R506Q/R679Q and FV:R306Q/R679Q, to investigate the effect of prothrombin on the individual cleavage sites. The APC-mediated FVa inhibition was monitored by a prothrombinase-based FVa assay, and apparent first order rate constants were calculated for each of the cleavage sites both in the presence and absence of prothrombin. Prothrombin impaired cleavages at both Arg306 and Arg506 and the inhibition correlated with a delayed appearance of proteolytic products on Western blots. Almost complete inhibition was obtained at around 3 μm prothrombin, whereas half-maximal inhibition was obtained at 0.7 μm prothrombin. After cleavage of prothrombin by thrombin, the inhibitory activity was lost. The inhibitory effect of prothrombin on APC-mediated inhibition of FVa was seen both in the presence and absence of protein S, but in particular for the Arg306 sites, it was more pronounced in the presence of protein S. Thus, prothrombin inhibition of APC inactivation of FVa appears to be due to both impaired APC function and decreased APC cofactor function of protein S. In conclusion, FVa, being part of the prothrombinase complex, is protected from APC by both FXa and prothrombin. Release of products of prothrombin activation from the prothrombinase complex would alleviate the protection, allowing APC-mediated inactivation of FVa.

Effects of factor Xa and protein S on the individual activated protein C-mediated cleavages of coagulation factor Va.

Activated protein C inhibits the procoagulant function of activated factor V (FVa) through proteolytic cleavages at Arg-306, Arg-506, and Arg-679. The cleavage at Arg-506 is kinetically favored but protected by factor Xa (FXa). Protein S has been suggested to annihilate the inhibitory effect of FXa, a proposal that has been challenged. To elucidate the effects of FXa and protein S on the individual cleavage sites of FVa, we used recombinant FVa:Q306/Q679 and FVa:Q506/Q679 variants, which can only be cleaved at Arg-506 and Arg-306, respectively. In the presence of active site blocked FXa (FXa-1.5-dansyl-Glu-Gly-Arg), the FVa inactivation was followed over time, and apparent second order rate constants were calculated. Consistent with results on record, we observed that FXa-1.5-dansyl-Glu-Gly-Arg decreased the Arg-506 cleavage by 20-fold, with a half-maximum inhibition of ∼2 nm. Interestingly and in contrast to the inhibitory effect of FXa on the 506 cleavage, FXa stimulated the Arg-306 cleavage. Protein S counteracted the inhibition by FXa of the Arg-506 cleavage, whereas protein S and FXa yielded additive stimulatory effect of the cleavage at Arg-306. This suggests that FXa and protein S interact with distinct sites on FVa, which is consistent with the observed lack of inhibitory effect on FXa binding to FVa by protein S. We propose that the apparent annihilation of the FXa protection of the Arg-506 cleavage by protein S is due to an enhanced rate of Arg-506 cleavage of FVa not bound to FXa, resulting in depletion of free FVa and dissociation of FXa-FVa complexes.

Platelet Factor 4 Impairs the Anticoagulant Activity of Activated Protein C

Platelet factor 4 (PF4) is an abundant platelet α-granule chemokine released following platelet activation. PF4 interacts with thrombomodulin and the γ-carboxyglutamic acid (Gla) domain of protein C, thereby enhancing activated protein C (APC) generation by the thrombin-thrombomodulin complex. However, the protein C Gla domain not only mediates protein C activation in vivo, but also plays a critical role in modulating the diverse functional properties of APC once generated. In this study we demonstrate that PF4 significantly inhibits APC anti-coagulant activity. PF4 inhibited both protein S-dependent APC anticoagulant function in plasma and protein S-dependent factor Va (FVa) proteolysis 3- to 5-fold, demonstrating that PF4 impairs protein S cofactor enhancement of APC anticoagulant function. Using recombinant factor Va variants FVa-R506Q/R679Q and FVa-R306Q/R679Q, PF4 was shown to impair APC proteolysis of FVa at position Arg306 by 3-fold both in the presence and absence of protein S. These data suggest that PF4 contributes to the poorly understood APC resistance phenotype associated with activated platelets. Finally, despite PF4 binding to the APC Gla domain, we show that APC in the presence of PF4 retains its ability to initiate PAR-1-mediated cytoprotective signaling. In summary, we propose that PF4 acts as a critical regulator of APC generation, but also differentially targets APC toward cytoprotective, rather than anticoagulant function at sites of vascular injury with concurrent platelet activation.

High-Density Lipoprotein-Associated Apolipoprotein M Limits Endothelial Inflammation by Delivering Sphingosine-1-Phosphate to the Sphingosine-1-Phosphate Receptor 1.

Objective— Plasma high-density lipoproteins (HDL) are potent antiatherogenic and anti-inflammatory particles. However, HDL particles are highly heterogenic in composition, and different HDL-mediated functions can be ascribed to different subclasses of HDL. Only a small HDL population contains apolipoprotein M (ApoM), which is the main plasma carrier of the bioactive lipid mediator sphingosine-1-phosphate (S1P). Vascular inflammation is modulated by S1P, but both pro- and anti-inflammatory roles have been ascribed to S1P. The goal of this study is to elucidate the role of ApoM and S1P in endothelial anti-inflammatory events related to HDL. Approach and Results— Aortic or brain human primary endothelial cells were challenged with tumor necrosis factor-&agr; (TNF-&agr;) as inflammatory stimuli. The presence of recombinant ApoM-bound S1P or ApoM-containing HDL reduced the abundance of adhesion molecules in the cell surface, whereas ApoM and ApoM-lacking HDL did not. Specifically, ApoM-bound S1P decreased vascular adhesion molecule-1 (VCAM-1) and E-selectin surface abundance but not intercellular adhesion molecule-1. Albumin, which is an alternative S1P carrier, was less efficient in inhibiting VCAM-1 than ApoM-bound S1P. The activation of the S1P receptor 1 was sufficient and required to promote anti-inflammation. Moreover, ApoM-bound S1P induced the rearrangement of the expression of S1P-related genes to counteract TNF-&agr;. Functionally, HDL/ApoM/S1P limited monocyte adhesion to the endothelium and maintained endothelial barrier integrity under inflammatory conditions. Conclusions— ApoM-bound S1P is a key component of HDL and is responsible for several HDL-associated protective functions in the endothelium, including regulation of adhesion molecule abundance, leukocyte-endothelial adhesion, and endothelial barrier.

Activated protein C cofactor function of protein S: a critical role for Asp95 in the EGF1-like domain.

Protein S has an established role in the protein C anticoagulant pathway, where it enhances the factor Va (FVa) and factor VIIIa (FVIIIa) inactivating property of activated protein C (APC). Despite its physiological role and clinical importance, the molecular basis of its action is not fully understood. To clarify the mechanism of the protein S interaction with APC, we have constructed and expressed a library of composite or point variants of human protein S, with residue substitutions introduced into the Gla, thrombin-sensitive region (TSR), epidermal growth factor 1 (EGF1), and EGF2 domains. Cofactor activity for APC was evaluated by calibrated automated thrombography (CAT) using protein S-deficient plasma. Of 27 variants tested initially, only one, protein S D95A (within the EGF1 domain), was largely devoid of functional APC cofactor activity. Protein S D95A was, however, gamma-carboxylated and bound phospholipids with an apparent dissociation constant (Kd(app)) similar to that of wild-type (WT) protein S. In a purified assay using FVa R506Q/R679Q, purified protein S D95A was shown to have greatly reduced ability to enhance APC-induced cleavage of FVa Arg306. It is concluded that residue Asp95 within EGF1 is critical for APC cofactor function of protein S and could define a principal functional interaction site for APC.

The Gas6-Axl Interaction Mediates Endothelial Uptake of Platelet Microparticles

Upon activation, platelets release plasma membrane-derived microparticles (PMPs) exposing phosphatidylserine on their surface. The functions and clearance mechanism of these microparticles are incompletely understood. As they are pro-coagulant and potentially pro-inflammatory, rapid clearance from the circulation is essential for prevention of thrombotic diseases. The tyrosine kinase receptors Tyro3, Axl, and Mer (TAMs) and their ligands protein S and Gas6 are involved in the uptake of phosphatidylserine-exposing apoptotic cells in macrophages and dendritic cells. Both TAMs and their ligands are expressed in the vasculature, the functional significance of which is poorly understood. In this study, we investigated how vascular TAMs and their ligands may mediate endothelial uptake of PMPs. PMPs, generated from purified human platelets, were isolated by ultracentrifugation and labeled with biotin or PKH67. The uptake of labeled microparticles in the presence of protein S and Gas6 in human aortic endothelial cells and human umbilical vein endothelial cells was monitored by flow cytometry, Western blotting, and confocal/electron microscopy. We found that both endothelial cell types can phagocytose PMPs, and by using TAM-blocking antibodies or siRNA knockdown of individual TAMs, we show that the uptake is mediated by endothelial Axl and Gas6. As circulating PMP levels were not altered in Gas6−/− mice compared with Gas6+/+ mice, we hypothesize that the Gas6-mediated uptake is not a means to clear the bulk of circulating PMPs but may serve to locally phagocytose PMPs generated at sites of platelet activation and as a way to effect endothelial responses.

Mapping of the factor Xa-binding site on factor Va by site-directed mutagenesis.

Activated coagulation factor V functions as a cofactor to factor Xa in the conversion of prothrombin to thrombin. Based on the introduction of extra carbohydrate side chains in recombinant factor V, we recently proposed several regions in factor Va to be important for factor Xa binding. To further define which residues are important for factor Xa binding, we prepared fifteen recombinant factor V variants in which clusters of charged amino acid residues were mutated, mainly to alanines. The factor V variants were expressed in COS-1 cells, and their functional properties evaluated in a prothrombinase-based assay, as well as in a direct binding test. Four of the factor V variants, 501A/510A/511D, 501A/510A/511D/513A, 513A/577A/578A, and 501A/510A/511D/513A/577A/578A exhibited markedly reduced factor Xa-cofactor activity tested in the prothrombinase assay, and reduced binding affinity as judged by the direct binding assay. These factor Va variants were normally cleaved at Arg-506 by activated protein C, and the interaction between the factor Xa-factor Va complex and prothrombin was unaffected by the introduced mutations. Based on the integration of all available data, we propose a key factor Xa binding surface to be centered on Arg-501, Arg-510, Ala-511, Asp-513, Asp-577, and Asp-578 in the factor Va A2 domain. These residues form an elongated charged factor Xa binding cluster on the factor Va surface.

Novel APC-cleavage sites in FVa provide insights into mechanisms of action of APC and its cofactor protein S

Summary.  Background: Activated protein C (APC) inhibits factor Va (FVa) by cleaving at Arg306, Arg506 and Arg679. Protein S serves as cofactor, in particular for the Arg306 site, and a protein S‐mediated relocation of the active site of APC closer to the membrane has been proposed as a mechanism. Recently, it was demonstrated that FVa, which was mutated at all three APC‐cleavage sites (FVa‐306Q/506Q/679Q), could still be cleaved by APC. These sites were close to Arg306 and Arg506 but not further defined. Objective: To identify and characterize the additional APC‐cleavage sites in FVa. Methods: The cDNA for FV‐306Q/506Q/679Q was used as a template to create FV variants with one or more possible cleavage sites being mutated. The FV variants were expressed and their sensitivity for APC characterized functionally and with Western blotting. Results: The additional APC‐cleavage sites were located at Lys309, Arg313, Arg316, Arg317 and Arg505. FVa‐306Q/309Q/313Q/316Q/317Q/505Q/506Q/679Q (denoted 8M‐FVa) was APC resistant. To investigate individual sites, they were mutated back using 8M‐FV as a template. The kinetics of APC‐degradation of these variants demonstrated that protein S was equally efficient in enhancing the APC effect for all the novel sites. Conclusions: Multiple APC‐cleavage sites close to Arg306 and a single site close to Arg506 were identified. Protein S was equally efficient as APC cofactor for all novel sites. The stimulation by protein S of the Arg505 cleavage argues against a specific protein S‐mediated stimulation of cleavage at Arg306 due to relocation of the APC active site closer to the membrane.

Factor V-short and protein S as synergistic tissue factor pathway inhibitor (TFPIα) cofactors

Essentials FV‐Short, a normal splice isoform of Factor V, binds tissue factor pathway inhibitor (TFPIα) with high affinity. FV‐Short functions as a synergistic TFPIα cofactor with protein S in inhibition of Factor Xa. FV‐Short is much more efficient as TFPIα cofactor than full length FV. TFPIα‐cofactor activity of FV‐Short is lost upon activation of coagulation by thrombin‐mediated cleavage.