Exosite interactions determine the affinity of factor X for the extrinsic Xase complex.
(25/674)
The initiation of coagulation results from the activation of factor X by an enzyme complex (Xase) composed of the trypsin-like serine proteinase, factor VIIa, bound to tissue factor (TF) on phospholipid membranes. We have investigated the basis for the protein substrate specificity of Xase using TF reconstituted into vesicles of phosphatidylcholine, phosphatidylserine, or pure phosphatidylcholine. We show that occupation of the active site of VIIa within Xase by a reversible inhibitor or an alternate peptidyl substrate is sufficient to exclude substrate interactions at the active site but does not alter the affinity of Xase for factor X. This is evident as classical competitive inhibition of peptidyl substrate cleavage but as classical noncompetitive inhibition of factor X activation by active site-directed ligands. This implies that the productive recognition of factor X by Xase arises from a multistep reaction requiring an initial interaction at sites on the enzyme complex distinct from the active site (exosites), followed by active site interactions and bond cleavage. Exosite interactions determine protein substrate affinity, whereas the second binding step influences the maximum catalytic rate for the reaction. We also show that competitive inhibition can be achieved by interfering with exosite binding using factor X derivatives that are expected to have limited or abrogated interactions with the active site of VIIa within Xase. Thus, substrate interactions at exosites, sites removed from the active site of VIIa within the enzyme complex, determine affinity and binding specificity in the productive recognition of factor X by the VIIa-TF complex. This may represent a prevalent strategy through which distinctive protein substrate specificities are achieved by the homologous enzymes of coagulation. (+info)
Plasma lipoproteins enhance tissue factor-independent factor VII activation.
(26/674)
The effect of plasma lipoprotein fractions (large very-low-density lipoprotein, small very-low-density lipoprotein, intermediate-density lipoprotein, and low-density lipoprotein) on initiation of blood coagulation by supporting factor VII activation or by stimulating monocytes to express tissue factor was investigated in vitro. Endotoxin-free preparations of lipoprotein fractions did not induce functional tissue factor in monocytes, whereas all lipoprotein fractions enhanced tissue factor-independent activation of factor VII by factor Xa and by factors Xa/Va. In contrast, no or only slight enhancement of factor IXa-, factor IXa/VIIIa-, factor XIa-, or thrombin-mediated factor VII activation was observed. The effect of small very-low-density lipoprotein was less than that of large very-low-density lipoprotein, and intermediate-density and low-density lipoproteins caused an even lower but still significant increase of factor Xa- and factor Xa/Va-mediated factor VII activation. When the data were normalized for apolipoprotein B-100 content, differences remained between lipoprotein fractions. In contrast, when phospholipid content was used for normalization, differences between lipoprotein fractions in factor Xa- and factor Xa/Va-mediated factor VII activation disappeared, indicating that phospholipids were involved in factor VII activation. This was supported by enhancement of factor Xa-mediated factor VII activation by synthetic phospholipid vesicles containing negatively charged phospholipids. (+info)
A primate model of hyperacute renal allograft rejection.
(27/674)
Hyperacute renal allograft rejection is initiated by primary immune injury to vascular endothelium and is propagated by secondary vasoconstriction, platelet aggregation and intravascular coagulation. Previous dissociation of these primary and secondary events, with graft survival in one human, suggested that the more usual graft failure was due to secondary injury. As a basis for further modification studies, this primate model most closely resembled its counterpart in man, as the onset and intensity of functional, morphologic and biochemical alterations were similar. Unmodified allografts failed within 5 minutes. The earliest and most abnormal finding was marked reduction in renal blood flow affecting all compartments. By 5 minutes, histologic changes of hyperacute rejection as well as antibody and faint C3 deposits were noted, but biopsies suggested that the initial flow reduction was more likely due to vasoconstriction, which was then followed by vascular obstruction. Glomeruli appeared most damaged, but at the highest antibody titer arterial injury was more prominent. Early red cell sequestration and stasis was marked, followed by progressive platelet clumping and neutrophil infiltration. While the decline in renal venous C3 levels was prompt, as in man, early intrarenal activation of the coagulation, fibrinolytic and kinin-forming systems could not be demonstrated, and fibrin formation was sparse by light and fluorescence microscopy. Qualitatively similar histologic and functional alterations were noted in autograft controls. While the initiating event was unclear and may have been accentuated by the arteriovenous shunts utilized, the final mechanism was probably marked vasoconstriction with renal ischemia. Intrarenal C3 consumption was an important finding and was not associated with tissue deposits of antibody or complement; it may provide a parallel with the progressive complement-mediated injury associated with acute myocardial ischemia noted by others. Endothelial injury was not seen in arteries, and all alterations were delayed in onset and progressed more slowly than in allografts. These findings may elucidate the mechanism of early malfunction of most autografts. Treatment of additional autografts with increasing doses of heparin progressively reversed these changes and even prevented the initial reduction in blood flow. Therefore, many alterations consistent with hyperacute rejection which are probably immediately responsible for graft failure can also be initiated by nonspecific, nonimmunologic events and, where injury is less intense, can be prevented pharmacologically. This model provides a means of dissecting the injurious events and subsequent evaluation of the effectiveness and interaction of various agents on the damaging secondary alterations which occur during hyperacute rejection. (+info)
Surface-loop residue Lys316 in blood coagulation Factor IX is a major determinant for Factor X but not antithrombin recognition.
(28/674)
The active site of activated Factor IX (FIXa) and related blood-coagulation enzymes is surrounded by a number of highly variable surface loops, which contribute to the characteristic substrate specificity of each individual enzyme. FIX residue Lys(316) is located in one of these loops and mutation of this residue to Glu is associated with haemophilia B. In the present study we investigated the functional role of Lys(316) in human FIXa by analysing the purified and activated FIX mutants FIXa-K316E and FIXa-K316A. FIXa-K316E was indistinguishable from normal FIXa in binding the competitive active-site inhibitor p-aminobenzamidine. In addition, substitution of Glu for Lys(316) had no significant effect on the reactivity towards various synthetic tripeptide substrates. Inhibition by the macromolecular inhibitor antithrombin was only slightly reduced for both FIXa mutants (less than 2-fold). In contrast, proteolytic activity of FIXa-K316E towards the natural substrate Factor X (FX) was virtually lacking, while the Lys(316) to Ala mutation resulted in a more than 10-fold reduction in FX activation. Thus residue Lys(316) plays a key role in FIXa activity towards FX. The requirement for Lys at position 316 for FX activation was also evident in the presence of the cofactor activated Factor VIII, although to a lesser extent than in its absence. These data demonstrate that Lys(316) specifically determines the reactivity of FIXa towards its natural substrate FX, but not to synthetic peptide substrates or antithrombin. (+info)
Directed glycosylation of human coagulation factor X at residue 333. Insight into factor Va-dependent prothrombin catalysis.
(29/674)
Based on homology, amino acids 326-336 (143-154 in chymotrypsin numbering) of factor X (fX) comprise a flexible surface loop, which is susceptible to self-proteolysis and influences substrate catalysis. To investigate the role of this autolysis loop in fX function, a recombinant variant with a new site for asparagine-linked glycosylation has been produced by changing glutamine 333 to asparagine. Q333N fX is activated normally by factor VIIa and tissue factor, factors IXa and VIIIa, and Russell's viper venom. Proteolysis of the loop is prevented by the mutation. Reactivity of the free enzyme toward substrates and inhibitors is attenuated 4-20-fold; relative to wild type fXa, Spectrozyme Xa(TM) hydrolysis is 25%, inhibition by antithrombin III and the tissue factor pathway inhibitor is approximately 20%, and prothrombin activation in the absence of the cofactor Va is only 5%. Surprisingly, activities of the variant and wild type enzymes are equivalent when part of the prothrombinase complex. N-Glycanase cleaves the new oligosaccharide from Q333N fXa leaving aspartic acid. Q333D fXa is approximately 1.6-fold more reactive with Spectrozyme Xa(TM), antithrombin III and tissue factor pathway inhibitor, and prothrombin than its glycosylated counterpart, Q333N fXa, but still quite abnormal relative to wild type fXa. Like Q333N fXa, Q333D fXa is fully functional as part of the prothrombinase complex. We conclude that Gln-333 is geographically close to a site of proteolytic degradation but not to activator, cofactor, or membrane binding sites. Mutation of Gln-333 impairs catalytic function, but given normal prothrombin activation by the complexed enzyme, the importance of Gln-333 for catalysis is not manifest in the prothrombinase assembly, suggesting a conformational change in complexed fXa. (+info)
Effect of P(2)' site tryptophan and P(20)' site deletion of Momordica charantia trypsin inhibitor II on inhibition of proteinases.
(30/674)
Momordica charantia trypsin inhibitor II (MCTI-II) inhibits the amidolytic activity of factor Xa with a K(i) value 10-100-fold smaller than those of other squash family inhibitors. It also inhibits factor X activation mediated by factor VIIa-tissue factor complex or factor IXa. Comparison of other squash family inhibitors reveal Trp at position 7 (P(2)') and a deletion at position 25 (P(20)') are characteristics of MCTI-II. In order to elucidate the effect of these positions on the inhibitory activity, we chemically synthesized three inhibitors: S-MCTI-II whose amino acid sequence is identical to natural MCTI-II, S-MCTI-II(7L) whose P(2)'(Trp) is substituted with Leu, and S-MCTI-II(25N) whose P(20)'(deletion) is filled with Asn. The dissociation constants of the complexes of human factor Xa with S-MCTI-II, S-MCTI-II(7L), and S-MCTI-II(25N) were 1.3x10(-6) M, 2.8x10(-5) M, and 7.3x10(-6) M, respectively. They inhibited factor X activation mediated by factor VIIa with the same degree. As in the case of natural MCTI-II, S-MCTI-II suppressed factor X activation mediated by factor IXa, while S-MCTI-II(7L) and S-MCTI-II(25N) did not. Both the Trp at the P(2)' position and deletion at the P(20)' position are thus likely required for the inhibition of factor Xa, trypsin, and factor IXa, while these two positions do not affect factor X activation initiated by the factor VIIa-tissue factor complex. (+info)
Surface-dependent coagulation enzymes. Flow kinetics of factor Xa generation on live cell membranes.
(31/674)
The initial surface reactions of the extrinsic coagulation pathway on live cell membranes were examined under flow conditions. Generation of activated coagulation factor X (fXa) was measured on spherical monolayers of epithelial cells with a total surface area of 41-47 cm(2) expressing tissue factor (TF) at >25 fmol/cm(2). Concentrations of reactants and product were monitored as a function of time with radiolabeled proteins and a chromogenic substrate at resolutions of 2-8 s. At physiological concentrations of fVIIa and fX, the reaction rate was 3.05 +/- 0.75 fmol fXa/s/cm(2), independent of flux, and 10 times slower than that expected for collision-limited reactions. Rates were also independent of surface fVIIa concentrations within the range 0.6-25 fmol/cm(2). The transit time of fX activated on the reaction chamber was prolonged relative to transit times of nonreacting tracers or preformed fXa. Membrane reactions were modeled using a set of nonlinear kinetic equations and a lagged normal density curve to track the expected surface concentration of reactants for various hypothetical reaction mechanisms. The experimental results were theoretically predicted only when the models used a slow intermediate reaction step, consistent with surface diffusion. These results provide evidence that the transfer of substrate within the membrane is rate-limiting in the kinetic mechanisms leading to initiation of blood coagulation by the TF pathway. (+info)
Activation of human prothrombin by highly purified human factors V and X-a in presence of human antithrombin.
(32/674)
In this communication we describe the first method for isolating human Factor V. The final product contains no other coagulation components as judged by functional assays and is physically homogeneous as shown by isofocusing gel electrophoresis. In addition, we present a means for obtaining intrinsically activated human Factor X-a. This preparation is usually homogeneous as judged by isofocusing gel electrophoresis. However, on occasion, an additional minor electrophoretic species with Factor X-a activity is observed. Furthermore, we describe the use of isoelectric focusing in sucrose density gradients to free human prothrombin from contamination by coagulation factors and other components. These homogeneous human proteins are employed to examine the conversion of prothrombin to thrombin in the presence and absence of human antithrombin. The latter component is responsible for virtually all of the plasm's capacity to neutralize Factor X-a and thrombin. In the absence of antithrombin, prothrombin (67,800) is converted to the precursor P-2 (51,600) and the fragment F-a (19,500). Subsquently, P-2 is cleaved to form the precursor P-3 (37,000), and the fragment F-b (11,500). Finally, P3 IS proteolyzed to form the heavy chain T-h (29,500) and the light chain T-L (6,500) of active thrombin. In the presence of antithrombin, an additional prothrombin conversion pathway is observed in which the zymogen is directly cleaved to form P-3 and F-A + B (30,000) prior to thrombin generation. Trace amounts of free thrombin remain uninhibited by antithrombin and could bias the zymogen activation pathway. Hirudin is known to neutralized thrombin instantaneoulsly. We demonstrate that the purified leech protein also binds to P-3 and prevents thrombin formation. When hirudin is added to activation mixtures at concentrations sufficient to virtually suppress P-3 conversion to thrombin, molecular species from both activation pathways are observed. Thus two human prothrombin conversion sequences appear to be initiated by Factor X-3 and may be of physiological significance. (+info)