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Query: UNIPROT:O95477 (
membrane-bound
)
29,236
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The endothelial cell
protein C
receptor (EPCR) binds
protein C
and facilitates activation by the thrombin-thrombomodulin complex. EPCR also binds
activated protein C
(
APC
) and inhibits
APC
anticoagulant activity. In this study, we detected a soluble form of EPCR in normal human plasma. Plasma EPCR appears to be approximately 43, 000 D, and circulates at approximately 100 ng/ml (98.4+/-27.8 ng/ml, n = 22). Plasma EPCR was purified from human citrated plasma using ion exchange, immunoaffinity, and
protein C
affinity chromatography. Flow cytometry experiments demonstrated that plasma EPCR bound
APC
with an affinity similar to that previously determined for recombinant soluble EPCR (Kdapp = 30 nM). Furthermore, plasma EPCR inhibited both
protein C
activation on an endothelial cell line and
APC
anticoagulant activity in a one-stage Factor Xa clotting assay. The physiological function of plasma EPCR is uncertain, but if the local concentrations are sufficiently high, particularly in disease states, the present data suggest that the soluble plasma EPCR could attenuate the
membrane-bound
EPCR augmentation of
protein C
activation and the anticoagulant function of
APC
.
...
PMID:Identification of functional endothelial protein C receptor in human plasma. 921 19
The location of the active site of
membrane-bound
activated protein C
(
APC
) relative to the phospholipid surface was determined both in the presence and absence of its cofactor, protein S, using fluorescence resonance energy transfer (FRET).
APC
was chemically modified to create the FRET donor species, Fl-FPR-
APC
, with a fluorescein dye (Fl) covalently attached to the active site via a D-Phe-Pro-Arg (FPR) tether and located in the active site near S4. FRET was observed when Fl-FPR-
APC
was titrated in the presence of Ca2+ ions with phosphatidylcholine/phosphatidylserine (4:1) vesicles containing the FRET acceptor, octadecylrhodamine (OR). Assuming a random orientation of transition dipoles (kappa2 = 2/3), the average distance of closest approach between the fluorescein in the active site of the
membrane-bound
APC
and the OR at the membrane surface is 94 A. The same calcium-dependent distance was obtained for both small and large unilamellar vesicles and for vesicles that contained phosphatidylethanolamine. The active site of
membrane-bound
APC
is therefore located far above the phospholipid surface. Upon addition of protein S, the efficiency of Fl-FPR-
APC
to OR energy transfer increased due to a protein S-dependent rotational and/or translational movement of the
APC
protease domain relative to the surface. If this movement were solely translational, then the average height of the fluorescein in the
membrane-bound
APC
.protein S complex would be 84 A above the surface. The extent of Fl-FPR-
APC
to OR energy transfer was unaltered by the addition of thrombin-inactivated protein S. The protein S effect was also specific for
APC
, since the addition of protein S to similarly-labeled derivatives of factor Xa, factor IXa, or factor VIIa did not alter the locations of their active sites. This direct measurement demonstrates that the binding of the protein S cofactor to its cognate enzyme elicits a relocation of the active site of
APC
relative to the membrane surface and thereby provides a structural explanation for the recently observed protein S-dependent change in the site of factor Va cleavage by
APC
.
...
PMID:Protein S alters the active site location of activated protein C above the membrane surface. A fluorescence resonance energy transfer study of topography. 931 8
Thrombomodulin is a cofactor protein on vascular endothelial cells that inhibits the procoagulant functions of thrombin and enhances thrombin-catalyzed activation of anticoagulant
protein C
. Thrombomodulin also accelerates the proteolytic activation of a plasma procarboxypeptidase referred to as thrombin-activable fibrinolysis inhibitor (TAFI). In this study, we describe structures on recombinant
membrane-bound
thrombomodulin that are required for human TAFI activation. Deletion of the N-terminal lectin-like domain and epidermal growth factor (EGF)-like domains 1 and 2 had no effect on TAFI or
protein C
activation, whereas deletions including EGF-like domain 3 selectively abolished thrombomodulin cofactor activity for TAFI activation. Provided that thrombomodulin EGF-like domain 3 was present, TAFI competitively inhibited
protein C
activation catalyzed by the thrombin-thrombomodulin complex. A thrombomodulin construct lacking EGF-like domain 3 functioned normally as a cofactor for
protein C
activation but was insensitive to inhibition by TAFI. Thus, the anticoagulant and antifibrinolytic cofactor activities of thrombomodulin have distinct structural requirements:
protein C
binding to the thrombin-thrombomodulin complex requires EGF-like domain 4, whereas TAFI binding also requires EGF-like domain 3.
...
PMID:Activation of thrombin-activable fibrinolysis inhibitor requires epidermal growth factor-like domain 3 of thrombomodulin and is inhibited competitively by protein C. 957 59
We have used our previously described ex vivo mesothelial cell (MC)-mediated gene therapy strategy (Gene Ther. 2:393-401, 1995) to modify the functional properties of the rat parietal peritoneal mesothelium in vivo by expression of a
membrane-bound
recombinant protein on the MC surface. Rat primary MCs were stably transfected (using strontium phosphate DNA coprecipitation) with a plasmid containing the gene for rat thrombomodulin (TM), a transmembrane glycoprotein that functions as an essential cofactor for the physiological activation of the anticoagulant
protein C
by the enzyme thrombin. As demonstrated by immunohistochemistry and by direct equilibrium binding with radiolabeled thrombin, genetically modified MCs expressed high levels of TM antigen on their surface in vitro. As judged by a thrombin-dependent
protein C
activation assay, such MC
membrane-bound
TM was biologically active. Once reseeded on the denuded parietal peritoneal surface of syngeneic recipients, these TM-transfected MCs continued to express TM antigen in vivo for at least 90 days. Moreover, the recombinant TM expressed on the reconstituted parietal mesothelium retained its ability to activate
protein C
in a thrombin-dependent manner. Our data indicate that MC-mediated expression of TM can be used to augment the anticoagulant properties of the parietal peritoneal surface. In general, our results suggest that ex vivo MC-mediated gene therapy can be used to deliver other therapeutic transmembrane proteins to the MC surface to enhance the functional repertoire of the parietal mesothelium in vivo.
...
PMID:Enhancement of the functional repertoire of the rat parietal peritoneal mesothelium in vivo: directed expression of the anticoagulant and antiinflammatory molecule thrombomodulin. 960 18
The single-chain procofactor factor V is cleaved by thrombin (FVaIIa) at Arg709, Arg1018, and Arg1545 and by a variety of other proteases to generate a cofactor species with various levels of cofactor function. Having demonstrated previously that monocyte-bound forms of cathepsin G and elastase cleave and activate factor V, studies were initiated here using purified proteins to probe factor V structure/function. Electrophoretic, Western blotting, and amino-terminal sequence analyses revealed that cathepsin G cleaves factor V at several sites (Phe1031, Leu1447, Tyr1518, and potentially Tyr696), ultimately generating an amino-terminal 103 kDa heavy chain and a carboxy-terminal 80 kDa light chain (FVaCG). Elastase also cleaves factor V at several sites (Ile708, Ile819, Ile1484, and potentially Thr678), generating a cofactor species, FVaHNE, with an amino-terminal 102 kDa heavy chain and a carboxy-terminal 90 kDa light chain. Incubation of FVaIIa with either cathepsin G or elastase resulted in cleavage within the heavy chain, releasing peptides of approximately 2000 and approximately 3000 Da, respectively, generating FVaIIa/CG and FVaIIa/HNE. The functional activity of each cofactor species was assessed either by clotting assay or by employing a purified prothrombinase assay using saturating amounts of factor Xa. Significant differences in cofactor function were observed between the two assay systems. Whereas FVaIIa, FVaCG, FVaIIa/CG, FVaHNE, and FVaIIa/HNE all had similar cofactor activities in the purified prothrombinase assay, FVaCG and FVaHNE had no cofactor activity in the clotting-based assay, and FVaIIa/CG and FVaIIa/HNE had approximately 30-35% clotting activity relative to FVaIIa. These disparate results led us to examine the binding interactions of these cofactors with the various prothrombinase components. Kinetic analyses indicated that FVaIIa (Kd(app) = 0.096 nM), FVaIIa/CG (Kd(app) = 0.244 nM), and FVaIIa/HNE (Kd(app) = 0.137 nM) bound to
membrane-bound
factor Xa much more effectively than FVaCG (Kd(app) = 1.46 nM) and FVaHNE (Kd(app) = 0.818 nM). In contrast, studies of the
activated protein C
(
APC
)-catalyzed inactivation of each of the factor V(a) species indicated that they were all equivalent substrates for
APC
with no differences observed in the rate of inactivation or the cleavage mechanism, suggesting that
APC
interacts with the light chain at a site distinct from factor Xa. The Km values for prothrombin, as well as the kcat values for each of the FV(a) species, were all similar (approximately 0.25 microM and approximately 1900 min-1). In addition, kinetic analyses indicated that whereas FVaCG and FVaHNE exhibited a slightly reduced ability to interact with phospholipid vesicles (approximately 2-3-fold), the remaining FV(a) species assembled equally well on this surface. Collectively, these data indicate that FVaCG and FVaHNE have a diminished capacity to support factor Xa binding; however, cleavage at Arg1545 and removal of the extended B-domain in these cofactors restore near-total factor Xa binding. Thus, cleavage at Arg1545 optimizes cofactor function within prothrombinase by facilitating factor Xa binding to
membrane-bound
FVa.
...
PMID:Proteolysis of factor V by cathepsin G and elastase indicates that cleavage at Arg1545 optimizes cofactor function by facilitating factor Xa binding. 971 13
According to a recent hypothesis (Sandhoff, K., and Kolter, T. (1996) Trends Cell Biol. 6, 98-103), glycolipids, which originate from the plasma membrane, are exposed to lysosomal degradation on the surface of intralysosomal vesicles. Taking the interaction of
membrane-bound
lipid substrates and lysosomal hydrolases as an experimental model, we studied the degradation of glucosylceramides with different acyl chain lengths by purified glucocerebrosidase in a detergent-free liposomal assay system. Our investigation focused on the stimulating effect induced by lysosomal components such as sphingolipid activator
protein C
(SAP-C or saposin C), anionic lysosomal lipids, bis(monoacylglycero)phosphate, and dolichol phosphate, as well as degradation products of lysosomal lipids, e.g. dolichols and free fatty acids. The size of the substrate-containing liposomal vesicles was varied in the study. Enzymatic hydrolysis of glucosylceramide carried by liposomes made of phosphatidylcholine and cholesterol was rather slow and only weakly accelerated by the addition of SAP-C. However, the incorporation of anionic lipids such as bis(monoacylglycero)phosphate, dolichol phosphate, and phosphatidylinositol into the substrate carrying liposomes stimulated glucosylceramide hydrolysis up to 30-fold. Dolichol was less effective. SAP-C activated glucosylceramide hydrolysis under a variety of experimental conditions and was especially effective for the increase of enzyme activity when anionic lipids were inserted into the liposomes. Glucosylceramides with short acyl chains were found to be degraded much faster than the natural substrates. Dilution experiments indicated that the added enzyme molecules associate at least partially with the membranes and act there. Surface plasmon resonance experiments demonstrated binding of SAP-C at concentrations up to 1 microM to liposomes. At higher concentrations (2.5 microM SAP-C), liposomal lipids were released from the liposome coated chip. A model for lysosomal glucosylceramide hydrolysis is discussed.
...
PMID:Lysosomal degradation on vesicular membrane surfaces. Enhanced glucosylceramide degradation by lysosomal anionic lipids and activators. 980 87
Protein S is an important anticoagulant protein acting as cofactor to
activated protein C
(
APC
) in the degradation of
membrane-bound
factors Va and VIIIa. Binding of protein S to the membrane depends on the Gla-domain, whereas sites for
APC
-interaction are located in the thrombin-sensitive region (TSR) and the first EGF domain. The aims of the present investigation were to localize the sites on protein S which are involved in
APC
-cofactor function and to elucidate possible orientations of the TSR in relation to the membrane. For these purposes, we determined the epitope for a calcium-dependent monoclonal antibody (HPS67) against the TSR, which inhibits
APC
cofactor activity even though it does not impede protein S binding to the membrane. HPS67 did not recognize wild-type mouse protein S but gained reactivity against a recombinant mouse protein in which G49 and R52 were mutated to R and Q (found in human protein S), respectively, suggesting these two residues to be part of a surface exposed epitope for HPS67. This information helped in the validation and refinement of the structural model for the Gla-TSR-EGF1-modules of protein S. The X-ray structure of a Fab-fragment mimicking HPS67 was docked onto the protein S model. The observation that HPS67 did not inhibit phospholipid binding of protein S has implications for the possible orientation of protein S on the membrane surface. In the proposed model for
membrane-bound
protein S, there is no contact between the TSR and the membrane. Rather, the TSR is free to interact with
membrane-bound
APC
.
...
PMID:Topological studies of the amino terminal modules of vitamin K-dependent protein S using monoclonal antibody epitope mapping and molecular modeling. 984 74
The effect of replacing the gamma-carboxyglutamic acid domain of
activated protein C
(
APC
) with that of prothrombin on the topography of the
membrane-bound
enzyme was examined using fluorescence resonance energy transfer. The average distance of closest approach (assuming kappa2 = 2/3) between a fluorescein in the active site of the chimera and octadecylrhodamine at the membrane surface was 89 A, compared with 94 A for wild-type
APC
. The gamma-carboxyglutamic acid domain substitution therefore lowered and/or reoriented the active site, repositioning it close to the 84 A observed for the
APC
. protein S complex. Protein S enhances wild-type
APC
cleavage of factor Va at Arg306, but the inactivation rate of factor Va Leiden by the chimera alone is essentially equal to that by wild-type
APC
plus protein S. These data suggest that the activities of the chimera and of the
APC
.protein S complex are equivalent because the active site of the chimeric protein is already positioned near the optimal location above the membrane surface to cleave Arg306. Thus, one mechanism by which protein S regulates
APC
activity is by relocating its active site to the proper position above the membrane surface to optimize factor Va cleavage.
...
PMID:Relocating the active site of activated protein C eliminates the need for its protein S cofactor. A fluorescence resonance energy transfer study. 1002 58
Blood coagulation is a response to vascular injury leading to the activation of platelets and coagulation factors with the ultimate formation of a fibrin plug. Several coagulation factors are zymogens of serine proteases that require vitamin K for normal biosynthesis. The active forms of these proteases and their cofactors form
membrane-bound
macromolecular complexes. In the final step prothrombin is activated to thrombin by active factor X in complex with its cofactor, factor V. Thrombin then cleaves designated peptide bonds in fibrinogen, resulting in the formation of fibrin monomers that polymerize to insoluble fibrin strands. This process is regulated by an anticoagulant counterpart, the so-called
protein C
anticoagulant system. Balance between the two systems is crucial to avoid bleeding on the one hand and thrombosis on the other. The coagulation and anticoagulation proteases, factors VII, IX, and X, and
protein C
, have a common domain structure with an N-terminal gamma-carboxyglutamic acid (Gla)-containing domain that is followed by two domains that are homologous to the epidermal growth factor (EGF), whereas the C-terminal half of each protein is occupied by a trypsin-like serine protease domain. Prothrombin also has an N-terminal Gla domain and a C-terminal serine protease domain, but they are separated by two so-called kringle domains rather than EGF-like domains. Finally, the vitamin K-dependent cofactor protein S has one domain with thrombin-sensitive bonds and four EGF-like domains in tandem between the Gla domain and a C-terminal domain that is homologous to plasma steroid hormone-binding proteins. The N-terminal noncatalytic Gla and EGF-like domains that provide the coagulation serine proteases with unique properties, such as affinity for certain biological membranes, and also mediate protein-protein interactions, are the subject of this review.
...
PMID:Contributions of Gla and EGF-like domains to the function of vitamin K-dependent coagulation factors. 1020 Sep 12
The inactivation of factor Va is a complex process which includes bond cleavage (at three sites) and dissociation of the A2N.A2C peptides, with intermediate activity in each species. Quantitation of the functional consequences of each step in the reaction has allowed for understanding of the presentation of disease in individuals possessing the factor V polymorphism factor VLEIDEN.
APC
cleavage of
membrane-bound
bovine factor Va (Arg306, Arg505, Arg662) leads to the dissociation of fragments of the A2 domain, residues 307-713 (A2N.A2C + A2C-peptide), leaving behind the
membrane-bound
A1.LC species. Evaluation of the dissociation process by light scattering yields invariant mass loss estimates as a function of
APC
concentration. The rate constant for A2 fragment dissociation varies with [
APC
], reaching a maximal value of k = 0.028 s-1, the unimolecular rate constant for A2 domain fragment dissociation. The
APC
binding site resides in the factor Va light chain (LC) (Kd = 7 nM), suggesting that the
membrane-bound
LC.A1 product would act to sequester
APC
. This inhibitory interaction (LC.A1.
APC
) is demonstrated to exist with either purified factor Va LC or the products of factor Va inactivation. Utilizing these experimental data and the reported rates of bond cleavage, binding constants, and product activity values for factor Va partial inactivation products, a model is developed which describes factor Va inactivation and accounts for the defect in factor VLEIDEN. The model accurately predicts the rates of inactivation of factor Va and factor VaLEIDEN, and the effect of product inhibition. Modeled reaction progress diagrams and activity profiles (from either factor Va or factor VaLEIDEN) are coincident with experimentally derived data, providing a mechanistic and kinetic explanation for all steps in the inactivation of normal factor Va and the pathology associated with factor VLEIDEN.
...
PMID:A model describing the inactivation of factor Va by APC: bond cleavage, fragment dissociation, and product inhibition. 1034 14
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