Zymogen factor IX potentiates factor IXa-catalyzed factor X activation

Intrinsic factor X activation is accelerated >10(7)-fold by assembly of the entire complex on the activated platelet surface. We have now observed that increasing the concentration of zymogen factor IX to physiologic levels ( approximately 100 nM) potentiates factor IXa-catalyzed activation of factor X on both activated platelets and on negatively charged phospholipid vesicles. In the presence and absence of factor VIIIa, factor IX (100 nM) lowered the K(d,appFIXa) approximately 4-fold on platelets and 2-10-fold on lipid vesicles. Treatment of two factor IX preparations with active-site inhibitors did not affect these observations. Autoradiographs of PAGE-separated reactions containing either (125)I-labeled factor IX or (125)I-labeled factor X showed that the increased factor X activation was not due to factor Xa-mediated feedback activation of factor IX and that there was increased cleavage of factor X heavy chain in the presence of factor IX in comparison with control reactions but only in the presence of both the enzyme and the surface. Since plasma concentrations of prothrombin, factor VII, protein C, or protein S did not by themselves potentiate factor Xa generation and did not interfere with the potentiation of the reaction of factor IX, the effect is specific for factor IX and is not attributable to the Gla domain of all vitamin K-dependent proteins. These observations indicate that under physiologic conditions, plasma levels of the zymogen factor IX specifically increase the affinity of factor IXa for the intrinsic factor X activation complex.     

Lipid-bound factor Xa regulates tissue factor activity

The activation of coagulation factor X by tissue factor (TF) and coagulation factor VIIa (VIIa) on a phospholipid surface is thought to be the key step in the initiation of blood coagulation. In this reaction, the product, fXa, is transiently and reversibly bound to the TF-VIIa enzyme complex. This in effect leads to a probabilistic inhibition of subsequent fX activations; a new fX substrate molecule cannot be activated until the old fXa molecule leaves. In this study, we demonstrate that benzamidine and soybean trypsin inhibitor-conjugated Sepharose beads, which bind fXa and sequester it away from the reaction, serve to enhance fX activation by the TF-VIIa complex. Thus, removal of fXa from the reactive zone, by either flow, fXa sequestration, or binding to distant lipid surfaces, can serve to enhance the levels of TF-VIIa activity. Using resonance energy transfer, we found the dissociation constants of fX and fXa for 100 nm diameter phospholipid vesicles to be on the order of 30-60 nM, consistent with previous measurements employing planar lipid surfaces. On the basis of the measurements of binding of fXa to phospholipid surfaces, we demonstrate that the rates of fX activation by the TF-VIIa complex under a variety of experimental conditions depend inversely on the amount of product (fXa) bound to the TF-phospholipid surface. These data support an inhibitory role for the reaction product, fXa, and indicate that models previously employed in understanding this initial coagulation reaction must now be re-evaluated to account for both the product occupancy of the phospholipid surface and the binding of the product to the enzyme. Moreover, the inhibitory properties of fXa can be described on the basis of the estimated surface density of fXa molecules on the TF-phospholipid surface.     

肝细胞生长因子是一个强的肾营养因子

肝细胞生长因子是目前已知生物活性最广泛的生长因子之一,能刺激多种上皮和内皮细胞进行有丝分裂、运动以及促进肾小管形态发生,在组织器官损伤修复、形态发生和肿瘤转移过程中发挥重要作用,在肾脏的发育、急性损伤、再生中具有较强的作用。     

Binding of factor VIIIa and factor VIII to factor IXa on phospholipid vesicles.

The activation of factor X by factor IXa (fIXa) in the presence of phosphatidylcholine-phosphatidylserine (PCPS) vesicles is markedly accelerated by thrombin-activated factor VIII (fVIIIa). The interaction between highly purified fVIIIa and fIXa in this complex was studied fluorometrically at 25 degrees C by using a derivative of D-phenylalanyl-prolyl-arginyl-fIXa which was modified at the active site with fluorescein-5-maleimide (Fl-M-FPR-fIXa). Titration of Fl-M-FPR-fIXa with fVIIIa at fixed PCPS resulted in a large, saturable increase in anisotropy (delta r = 0.09). The titration data were fit to a model assuming a reversible equilibrium between fVIIIa and fIXa, resulting in an apparent dissociation constant of 2 nM and a stoichiometry of 1 mol of fVIIIa/mol of Fl-M-FPR-fIXa. The initial velocity of factor X activation was measured under identical conditions except that active fIXa and factor X were included, which yielded binding parameters similar to those determined fluorometrically. Thus, the fluorescence method accurately reflects complex formation between fVIIIa and fIXa on the phospholipid surface, and the fVIIIa-fIXa interaction is not influenced by the presence of the substrate, factor X. Addition of fVIII to Fl-M-FPR-fIXa and PCPS produced a small, saturable increase in anisotropy (delta r = 0.03), followed by a larger increase (delta r = 0.07) upon addition of thrombin to activate fVIII. Thus, fVIII binds fIXa, but proteolytic modification of fVIII must occur before the complete fVIIIa-dependent structural change in the active site of fIXa, as reflected in the anisotropy change, occurs     

Inactivation of factor VIII by factor IXa.

Factor VIII (FVIII) is the nonproteolytic cofactor for FIXa in the tenase complex of blood coagulation. FVIII is proteolytically activated by thrombin and FXa in vitro to form a heterotrimer with full procoagulant activity. Activated protein C inactivates thrombin-activated FVIII through cleavage adjacent to position Arg 336 in the cofactor. We have investigated the interaction of FIXa and FVIII and subjected FVIII polypeptides to N-terminal amino acid sequence analysis. Contrary to previous reports, we were unable to demonstrate the activation of FVIII by FIXa. Incubation of these two proteins at equimolar or close to equimolar concentrations resulted in the inactivation of FVIII, coincident with cleavage of the FVIII heavy chain adjacent to Arg 336 and the light chain adjacent to Arg 1719. These cleavages were detected in the presence or absence of thrombin, indicating that FIXa does not stabilize thrombin-activated FVIIIa. APC cleaved FVIII at the same position in the heavy chain, and simultaneous incubation of FVIII, APC, and FIXa did not result in stabilization of the cofactor. We conclude that FIXa does not play a role in the stabilization or activation of FVIII.     

Escherichia coli elongation factor G blocks stringent factor

The relationship between the binding domains of elongation factor G(EF-G) and stringent factor (SF) on ribosomes was studied. The binding of highly purified, radioactively labeled, protein factors to ribosomes was monitored with a column system. The data show that binding of EF-G to ribosomes in the presence of fusidic acid and GDP or of the noncleavable analogue GDPCP prevents subsequent binding of SF to ribosomes. In addition, stabilization of the EF-G-ribosome complex by fusidic acid inhibits SF's enzymatic activities. Removal of protein L7/L12 from ribosomes leads to weaker binding of EF-G, while SF's binding and activity are unaffected. In the absence of L7/L12, EF-G-dependent inhibition of SF binding and function is reduced. The data presented in this report suggest that these two factors bind at overlapping, or at least interacting, ribosomal domains.