Carboxylate polyanions accelerate inhibition of thrombin by heparin cofactor II

The heparin cofactor II (HCII)/thrombin inhibition reaction is enhanced by various carboxylate polyanions. In the presence of polyaspartic acid, the HCII/thrombin reaction is accelerated more than 1000-fold with the second-order rate constant increasing from 3.2 x 10(4) M-1 min-1 (in the absence of polyAsp) to 3.6 x 10(7) M-1 min-1 as the polyAsp concentration is increased from 1 to 250 micrograms/ml. This accelerating effect was observed for HCII/thrombin, though to varying degrees, with other carboxylate polyanions. In contrast to HCII, the rate of antithrombin III inhibition of thrombin was decreased in the presence of polyAsp. The HCII/thrombin complex is rapidly formed in the presence of 10 micrograms/ml polyAsp when 125I-labeled-thrombin is incubated with plasma. It is possible that at physiological sites rich in carboxylate polyanions, thrombin may be preferentially inhibited by HCII.     

Affinity chromatography of sulphated polysaccharides separately fractionated on antithrombin III and heparin cofactor II immobilized on concanavalin A—Sepharose

Three sulphated polysaccharides, dermatan sulphate, fucan and heparin, were fractionated according to their affinity towards antithrombin III (ATIII) and heparin cofactor II (HCII), the two main physiological thrombin (IIa) inhibitors. Both inhibitors were immobilized on concanavalin A—Sepharose, which binds to the glycosylated chains of the proteins while the protein-binding site for the polysaccharide remains free. Each polysaccharide was fractionated into bound and unbound fractions either for ATIII or HCII. The eluted fractions were tested for their ability to catalyse and interactions. The possible presence of a unique binding site for ATIII and HCII, on each sulphated polysaccharide, was also studied.     

The effect of complex-formation with polyanions on the redox properties of cytochrome c.

1. The stable complex formed between mammalian cytochrome c and phosvitin at low ionic strength was studied by partition in an aqueous two-phase system. Oxidized cytochrome c binds to phosvitin with a higher affinity than reduced cytochrome c. The difference was equivalent to a decrease of the redox potential by 22 mV on binding. 2. Complex-formation with phosvitin strongly inhibited the reaction of cytochrome c with reagents that react as negatively charged species, such as ascorbate, dithionite, ferricyanide and tetrachlorobenzoquinol. Reaction with uncharged reagents such as NNN'N'-tetramethylphenylenediamine and the reduced form of the N-methylphenazonium ion (present as the methylsulphate) was little affected by complex-formation, whereas oxidation of the reduced cytochrome by the positively charged tris-(phenanthroline)cobalt(III) ion was greatly stimulated. 3. A similar pattern of inhibition and stimulation of reaction rates was observed when phosvitin was replaced by other macromolecular polyanions such as dextran sulphate and heparin, indicating that the results were a general property of complex-formation with polyanions. A weaker but qualitatively similar effect was observed on addition of inositol hexaphosphate and ATP. 4. It is suggested that the effects of complex-formation with polyanions on the reactivity of cytochrome c with redox reagents are mainly the result of replacing the positive charge on the free cytochrome by a net negative charge. Any steric effects on polyanion binding are small in comparison with such electrostatic effects.     

Interaction of S-protein of complement with thrombin and antithrombin III during coagulation. Protection of thrombin by S-protein from antithrombin III inactivation

S-protein, the inhibitor in plasma of the membrane attack complex of complement, appears to have a second function in coagulation. S-protein during clotting enters into a trimolecular complex with thrombin and antithrombin III (ATIII). Functionally, S-protein in the presence of low concentrations of heparin, protects thrombin from inactivation by ATIII. Complex formation between S-protein and thrombin, and between S-protein, thrombin, and ATIII, was demonstrated by agarose gel electrophoresis and by two-dimensional immunoelectrophoresis of purified proteins and in recalcified, clotted plasma. Formation of the trimolecular S-thrombin-ATIII complex was strictly dependent on the presence of thrombin. No association was detectable between S-protein and ATIII or between S-protein and prothrombin. Heparin was not required for the formation of the bimolecular S-protein-thrombin complex or the trimolecular S-protein-ATIII complex. The protective effect of S-protein on inactivation of thrombin by ATIII was demonstrated in functional assays with purified proteins and in plasma only in the presence of low concentrations of heparin. Thus, S-protein may mediate its effect by scavenging heparin required for ATIII activation. It is suggested that the protection of thrombin by S-protein from inactivation by ATIII may be of physiological importance.     

Amino acid residues of heparin cofactor II required for stimulation of thrombin inhibition by sulphated polyanions

A variety of sulphated polyanions in addition to heparin and dermatan sulphate stimulate the inhibition of thrombin by heparin cofactor II (HCII). Previous investigations indicated that the binding sites on HCII for heparin and dermatan sulphate overlap but are not identical. In this study we determined the concentrations (IC50) of various polyanions required to stimulate thrombin inhibition by native recombinant HCII in comparison with three recombinant HCII variants having decreased affinity for heparin (Lys-173-->Gln), dermatan sulphate (Arg-189-->His), or both heparin and dermatan sulphate (Lys-185-->Asn). Pentosan polysulphate, sulphated bis-lactobionic acid amide, and sulphated bis-maltobionic acid amide resembled dermatan sulphate, since their IC50 values were increased to a much greater degree (>/=8-fold) by the mutations Arg-189-->His and Lys-185-->Asn than by Lys-173-->Gln (Gln and Lys-185-->Asn (>/=6-fold) than by Arg-189-->His (相似文献   

Activation of heparin cofactor II by fibroblasts and vascular smooth muscle cells

Inhibition of thrombin by heparin cofactor II (HCII) is accelerated by dermatan sulfate, heparan sulfate, and heparin. Purified HCII or defibrinated plasma was incubated with washed confluent cell monolayers, 125I-thrombin was added, and the rate of formation of covalent 125I-thrombin-inhibitor complexes was determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Fibroblasts and porcine aortic smooth muscle cells accelerated inhibition of thrombin by HCII 2.3-7.5-fold but had no effect on other thrombin inhibitors in plasma. Human umbilical vein endothelial cells and mouse macrophage-derived cells did not accelerate the thrombin-HCII reaction. IMR-90 normal human fetal lung fibroblasts treated with heparinase or heparitinase accelerated the thrombin-HCII reaction to the same degree as untreated cells. In contrast, treatment with chondroitinase ABC almost totally abolished the ability of these cells to activate HCII while chondroitinase AC had little or no effect, suggesting that dermatan sulfate was responsible for the activity observed. [35S]Sulfate-labeled proteoglycans were isolated from IMR-90 fibroblast monolayers and conditioned medium and fractionated into two peaks on Sepharose CL-2B. The lower Mr proteoglycans contained 74-76% dermatan sulfate and were 11-25 times more active with HCII than the higher Mr proteoglycans which contained 68-97% heparan sulfate. The activity of the lower Mr proteoglycans decreased 70-90% by degradation of the dermatan sulfate component with chondroitinase ABC. These results confirm that dermatan sulfate proteoglycans are primarily responsible for activation of HCII by IMR-90 fibroblasts. We suggest that HCII may inhibit thrombin when plasma is exposed to vascular smooth muscle cells or fibroblasts.     

Characterization of the heparin-binding site of glia-derived nexin/protease nexin-1.

The interaction of heparin with glia-derived nexin (GDN) has been characterized and compared to that observed between heparin and antithrombin III (ATIII). Heparin was fractionated according to its affinity for immobilized GDN, and the ability of various fractions to accelerate the inhibition rate of thrombin by either GDN or ATIII was examined. Fractions with different affinities for GDN accelerated the thrombin-GDN reaction to a similar extent; heparin with a high affinity for immobilized GDN stimulated the reaction only about 30% more than the fraction that did not bind to immobilized GDN. Slightly greater differences were observed for the effect of these fractions on the thrombin-ATIII reaction; heparin that did not bind to the GDN affinity column was about 60% more effective than heparin with a high affinity for GDN in accelerating the inhibition of thrombin by ATIII. The CNBr fragment of GDN between residues 63 and 144 was able to reduce the heparin-accelerated rate of inhibition of thrombin by GDN indicating that this region of GDN was able to bind the heparin molecules responsible for the acceleration. Shorter synthetic peptides within this sequence did not significantly reduce the rate, suggesting that the heparin-binding activity of fragment 63-144 depends on a specific conformation of the polypeptide chain. Fragment 63-144 was less effective in decreasing the heparin-accelerated rate of inhibition of thrombin by ATIII. The results are discussed in terms of the heparin species that are responsible for the acceleration of the GDN- and ATIII-thrombin reactions and the heparin-binding sites of GDN and ATIII.     

Antithrombin III enhances inducible nitric oxide synthase gene expression in vascular smooth muscle cells

Evidence suggests that antithrombin III (ATIII) exerts anti-inflammatory properties in addition to its anti-coagulative mechanisms. In animal models of sepsis, ATIII affected cytokine plasma concentrations with a decrease of pro-inflammatory cytokines. In addition to cytokines, excessive production of nitric oxide (NO) derived from inducible nitric oxide synthase (iNOS) might represent another important mediator of the cytotoxic events during sepsis. Regarding ATIII as a potential anti-inflammatory modulator, one may speculate that ATIII inhibits the synthesis of iNOS-derived NO. However, our data demonstrate that ATIII further stimulates iNOS gene expression when applied together with either interleukin-1 beta or the combination of lipopolysaccharide plus interferon-gamma. The most prominent synergistic effects on NO synthesis were found when ATIII was given at higher concentrations (1, 5, and 10 U/ml). Although the mechanisms of ATIII signal transduction remain to be established, intensification of interleukin-1 beta or interferon-gamma/lipopolysaccharide-induced NO synthesis by ATIII does not attribute to the anti-inflammatory properties of ATIII.     

Antithrombin activity of a peptide corresponding to residues 54-75 of heparin cofactor II

Heparin cofactor II (HCII) is a highly specific serine proteinase inhibitor, which complexes covalently with thrombin in a reaction catalyzed by heparin and other polyanions. The molecular basis for the thrombin specificity may be explained by the identification here of a segment of HCII including residues 54-75 that binds to thrombin. A synthetic peptide, HCII(54-75), based on this segment of HCII, Gly-Glu-Glu-Asp-Asp-Asp-Tyr-Leu-Asp-Leu-Glu- Lys-Ile-Phe-Ala-Glu-Asp-Asp-Asp-Tyr-Ile-Asp inhibited thrombin's cleavage of fibrinogen. Clotting activity of thrombin was inhibited 50% at a concentration of 28 microM. Polyacrylamide gel electrophoresis showed that HCII(54-75) inhibited thrombin's cleavage of both the A alpha and B beta polypeptides in fibrinogen. However, the peptide did not block thrombin's active site, as hydrolysis of chromogenic substrates was not inhibited. HCII(54-75) probably binds to the same site on thrombin as do carboxyl-terminal residues of hirudins, thrombin inhibitors of leeches. HCII(54-75) inhibited binding of thrombin to a synthetic peptide corresponding to residues 54-66 of hirudin PA, but the hirudin peptide was about 30-fold more potent in binding and clotting assays. Both synthetic peptides, as a result of their polyanionic character, might be expected to stimulate the reaction of HCII with thrombin. However, the hirudin-related peptide inhibited this reaction, suggesting that it blocked a site on thrombin required for interaction with HCII. HCII(54-75) had a net stimulatory effect on the thrombin-HCII reaction as a consequence of its lower affinity for thrombin and greater negative charge relative to the hirudin-related peptide. These studies suggest that residues 54-75 of HCII interact with a noncatalytic binding site on thrombin and that this interaction contributes to efficient inhibition of thrombin by HCII.     

Heparin cofactor II: cDNA sequence, chromosome localization, restriction fragment length polymorphism, and expression in Escherichia coli

Heparin cofactor II (HCII) is an inhibitor of thrombin in plasma that is activated by dermatan sulfate or heparin. An apparently full-length cDNA for HCII was isolated from a human liver lambda gt11 cDNA library. The cDNA consisted of 2215 base pairs (bp), including an open-reading frame of 1525 bp, a stop codon, a 3'-noncoding region of 654 bp, and a poly(A) tail. The deduced amino acid sequence contained a signal peptide of 19 amino acid residues and a mature protein of 480 amino acids. The sequence of HCII demonstrated homology with antithrombin III and other members of the alpha 1-antitrypsin superfamily. Blot hybridization of an HCII probe to DNA isolated from sorted human chromosomes indicated that the HCII gene is located on chromosome 22. Twenty human leukocyte DNA samples were digested with EcoRI, PstI, HindIII, KpnI, or BamHI, and Southern blots of the digests were probed with HCII cDNA fragments. A restriction fragment length polymorphism was identified with BamHI. A slightly truncated form of the cDNA, coding for Met-Ala instead of the N-terminal 18 amino acids of mature HCII, was cloned into the vector pKK233-2 and expressed in Escherichia coli. The resultant protein of apparent molecular weight 54,000 was identified on an immunoblot with 125I-labeled anti-HCII antibodies. The recombinant HCII formed a complex with 125I-thrombin in a reaction that required the presence of heparin or dermatan sulfate.     

Molecular mapping of the thrombin-heparin cofactor II complex

We used 55 Ala-scanned recombinant thrombin molecules to define residues important for inhibition by the serine protease inhibitor (serpin) heparin cofactor II (HCII) in the absence and presence of glycosaminoglycans. We verified the importance of numerous basic residues in anion-binding exosite-1 (exosite-1) and found 4 additional residues, Gln24, Lys65, His66, and Tyr71 (using the thrombin numbering system), that were resistant to HCII inhibition with and without glycosaminoglycans. Inhibition rate constants for these exosite-1 (Q24A, K65A, H66A, Y71A) thrombin mutants (0.02-0.38 x 10(8) m(-1) min(-1) for HCII-heparin when compared with 2.36 x 10(8) m(-1) min(-1) with wild-type thrombin and 0.03-0.53 x 10(8) m(-1) min(-1) for HCII-dermatan sulfate when compared with 5.23 x 10(8) m(-1) min(-1) with wild-type thrombin) confirmed that the structural integrity of thrombin exosite-1 is critical for optimal HCII-thrombin interactions in the presence of glycosaminoglycans. However, our results are also consistent for HCII-glycosaminoglycan-thrombin ternary complex formation. Ten residues surrounding the active site of thrombin were implicated in HCII interactions. Four mutants (Asp51, Lys52, Lys145/Thr147/Trp148, Asp234) showed normal increased rates of inhibition by HCII-glycosaminoglycans, whereas four mutants (Trp50, Glu202, Glu229, Arg233) remained resistant to inhibition by HCII with glycosaminoglycans. Using 11 exosite-2 thrombin mutants with 20 different mutated residues, we saw no major perturbations of HCII-glycosaminoglycan inhibition reactions. Collectively, our results support a "double bridge" mechanism for HCII inhibition of thrombin in the presence of glycosaminoglycans, which relies in part on ternary complex formation but is primarily dominated by an allosteric process involving contact of the "hirudin-like" domain of HCII with thrombin exosite-1.     

Structure-function relationships in heparin cofactor II: spectral analysis of aromatic residues and absence of a role for sulfhydryl groups in thrombin inhibition

This study characterizes the structural and functional significance of sulfhydryl residues in human plasma heparin cofactor II (HCII). For quantification of sulfhydryl groups, the extinction coefficient of HCII was redetermined and found to be 0.593 ml mg-1 cm-1 using second-derivative spectroscopy and multicomponent analysis assuming 4, 10, and 2 residues of tryptophan, tyrosine, and tyrosine-O-sulfate per mole of protein, respectively. The results show that tyrosine-O-sulfate residues in HCII and in cholecystokinin peptide fragments (as model compounds) do not significantly contribute to the absorbance spectrum from 280 to 300 nm. A total of three sulfhydryl groups per mole of HCII was detected by Ellman's reagent titration, with or without treatment with dithioerythritol, indicating the absence of intramolecular disulfide bonds. Incubation of HCII with 0.1-10 mM dithioerythritol did not diminish its heparin-enhanced thrombin inhibition activity. Treatment with various sulfhydryl-specific reagents, including p-mercuribenzoate, HgCl2, and N-substituted maleimide derivatives, inactivated HCII. Titration with Ellman's reagent after these reactions identified the modification site as a cysteinyl residue(s). However, complete methanethio derivatization of the sulfhydryl groups of HCII using methyl methanethiosulfonate did not alter heparin-catalyzed thrombin inhibition. These results indicate that the sulfhydryl groups of HCII are not essential for thrombin inhibition. HCII differs from antithrombin III, which contains an essential disulfide bond for heparin-dependent thrombin inhibition (Longas, M. O., et al. (1980) J. Biol. Chem. 255, 3436). Furthermore, within the "serpin" (serine proteinase inhibitor) superfamily, HCII resembles chicken ovalbumin in occurrence of sulfhydryl residues and reactivity with various sulfhydryl group-directed compounds.     

Thermodynamic analysis of heparin binding to human antithrombin.

The binding of heparin to human antithrombin III (ATIII) was investigated by titration calorimetry (TC) and differential scanning calorimetry (DSC). TC measurements of homogeneous high-affinity pentasaccharide and octasaccharide fragments of heparin in 0.02 M phosphate buffer and 0.15 M sodium chloride (pH 7.3) yielded binding constants of (7.1 +/- 1.3) x 10(5) M-1 and (6.7 +/- 1.2) x 10(6) M-1, respectively, and corresponding binding enthalpies of -48.3 +/- 0.7 and -54.4 +/- 5.4 kJ mol-1. The binding enthalpy of heparin in phosphate buffer (0.02 M, 0.15 M NaCl, pH 7.3) was estimated from TC measurements to be -55 +/- 10 kJ mol-1, while the enthalpy in Tris buffer (0.02 M, 0.15 M NaCl, pH 7.3) was -18 +/- 2 kJ mol-1. The heparin-binding affinity was shown by fluorescence measurements not to change under these conditions. The 3-fold lower binding enthalpy in Tris can be attributed to the transfer of a proton from the buffer to the heparin-ATIII complex. DSC measurements of the ATIII unfolding transition exhibited a sharp denaturation peak at 329 +/- 1 K with a van 't Hoff enthalpy of 951 +/- 89 kJ mol-1, based on a two-state transition model and a much broader transition from 333 to 366 K. The transition peak at 329 K accounted for 9-18% of the total ATIII. At sub-saturate heparin concentrations, the lower temperature peak became bimodal with the appearance of a second transition peak at 336 K. At saturate heparin concentration only the 336 K peak was observed. This supports a two domain model of ATIII folding in which the lower stability domain (329 K) binds and is stabilized by heparin.     

A peptide model for the heparin binding site of antithrombin III.

A peptide model for the heparin binding site of antithrombin III (ATIII) was synthesized to elucidate the structural consequences of heparin binding. This peptide [ATIII(123-139)] and a sequence-permuted analogue (ATIII random) showed similar conformational behavior (as analyzed by circular dichroism spectroscopy) in aqueous and organic media. In the presence of heparin, however, the peptide ATIII(123-139) assumed a stable conformation, whereas peptide ATIII random did not. Complex formation was saturable and sensitive to salt. The ATIII(123-139)-heparin complex contained beta-structure, rather than helical structure. This finding is incompatible with current models of heparin binding and suggests that heparin binding may induce nonnative structures at the binding site which could, in turn, lead to activation of ATIII. The peptide ATIII(123-139) was able to inhibit the binding of ATIII by heparin, consistent with the notion that this peptide may be a model for the heparin binding site.     

The role of surface charge on the accelerating action of heparin on the antithrombin III-inhibited activity of alpha-thrombin

We have compared surface charge and the surface charge density on the polyanions heparin and potassium polyvinyl sulfate (KPVS), as well as on hydrolyzed heparin and KPVS, with their accelerating effect on the inhibitory action of antithrombin III on thrombin. Polyelectrolyte titration of thrombin with KPVS or heparin at pH 7.4 clearly indicates an electrostatic interaction. In contrast, at the same pH no electrostatic interaction is observed between polyanions and antithrombin III. KPVS accelerates the inhibitory action of antithrombin III to the same extent as heparin on the basis of charge equivalence. Heparin and KPVS with a mean distance between two charged centers of less than 0.75 and 0.95 nm, respectively, accelerate strongly whereas hydrolysates with lower charge densities are far less active. The following observations are indicated. Intramolecular neutralization of oppositely charged residues occurs within thrombin, antithrombin III, and partially hydrolyzed heparin. Heparin acts on the antithrombin III-thrombin reaction through cooperative electrostatic binding to thrombin and nonelectrostatic interaction with antithrombin III. This indicates a quasi-catalytic action of the polyelectrolyte. Hydrolysis of only a few N-sulfate residues within the heparin molecule decreases the linear surface charge density to such an extent that the accelerating action is drastically reduced. The loss of accelerating capacity agrees with the sudden loss of counterion condensation due to the decrease of the linear surface charge density beyond limits postulated by Manning in a theory of polyelectrolytes.     

Important role of arginine 129 in heparin-binding site of antithrombin III. Identification of a novel mutation arginine 129 to glutamine

An hereditary abnormal antithrombin III (ATIII Geneva) with defective heparin cofactor activity was characterized by DNA single strand amplification and subsequent direct sequencing. ATIII Geneva was found to have a G to A transition in Exon IIIa leading to an Arg-129 to Gln mutation. This amino acid is part of the ATIII region comprising residues 114-154, which contains the highest proportion of basic residues (Arg or Lys), and is known from chemical modification studies to be involved in heparin binding. The variant protein did not bind heparin-Sepharose and was isolated from the propositus plasma by immunoaffinity chromatography. High affinity (for ATIII) heparin had only a minimal effect on thrombin and activated factor X inhibition by the purified abnormal ATIII. Taken together, these results demonstrate an important role for Arg-129 in the binding and interaction of ATIII with heparin of high affinity. We propose that a cooperation between Lys-125, Arg-129, Lys-136, and Arg-47 exposed at the surface of the inhibitor allows the binding of the essential pentasaccharide domain of heparin which is specific for the ATIII interaction.     

Differential susceptibilities of DNA polymerases-alpha and -beta to polyanions.

The effects of various polyanions including synthetic polynucleotides on DNApolymerases-alpha and -beta from blastulae of the sea urchin Hemicentrotus pulcherrimus and HeLa cells were studied. Only DNA polymerase-alpha was inhibited by polyanions, such as polyvinyl sufate, dextran sulfate, heparin, poly(G), poly(I), poly(U) and poly(ADP-Rib). Of the various polynucleotides tested, poly(G) and poly(I) were the strongest inhibitors. Kinetic studies showed that the Ki value for poly(G) was 0.3 microgram/ml and that poly(G) had 20-fold higher affinity than activated DNA for the template-primer site of DNA polymerase-alpha. Poly(U) and poly(ADP-Rib) were also inhibitory, but they were one hundredth as inhibitory as poly(G) or poly(I). Poly(A), poly(C), poly(A).poly(U) AND POLY(I).poly(C) were not inhibitory to DNA polymerase-alpha. In contrast, DNA olymerase-beta was not affected at all by these polyanions under the same conditions.     

Effects of different heparins on the enhancement of the thrombin-antithrombin reaction

Kinetic analyses were made of the thrombin/antithrombin III (ATIII) reaction in the presence of catalytic amounts of three kinds of mammalian HA-heparin (bovine, pig and whale), which have the same affinities for ATIII. In the absence of NaCl, the first-order rate constant was higher with whale HA-heparin than with the other two HA-heparins. However, the strength of the interactions of thrombin with the HA-heparins was in the order, bovine greater than pig greater than whale. Thus, the slow reactions in the case of bovine and pig HA-heparins were probably due to preferential binding of the two HA-heparins to thrombin rather than to ATIII, thus causing the HA-heparins to be inhibitory for the reaction by reducing the turnover rates of the polysaccharides as catalysts. In the presence of 0.15M NaCl, the first-order rate constants were slightly higher in the case of pig HA-heparin than of the other two HA-heparins. Since the strength of the interactions of these HA-heparins with thrombin was in the order, pig greater than or equal to bovine greater than whale, the faster reactions were probably due to higher associations of the enzyme with the essential HA-heparin-ATIII complex.     

Heparan sulphate with no affinity for antithrombin III and the control of haemostasis

Heparan sulphate with no affinity for antithrombin III (ATIII) was observed to cause acceleration of the factor Xa:ATIII interaction by 1100-fold (k2, 7 X 10(7) M-1.min-1) and the prothrombinase:ATIII interaction by 2900-fold (k2, 2.5 X 10(7) M-1.min-1). Although high-affinity heparan sulphate catalyzed higher acceleration and at lower concentration, in natural mixtures of the two forms the activity of the no affinity form predominated. Heparan sulphate had no significant effect on the thrombin:ATIII interaction but inhibited its potentiation by heparin (Kd 0.3 microM). From the estimated concentration of heparan sulphate on the endothelial cell surface it is proposed that the non-thrombogenic property of blood vessels is due to the acceleration of the factor Xa or prothrombinase:ATIII interaction by the greater mass of surface-bound heparan sulphate rather than by the much smaller proportion of heparin-like molecules (with high affinity for antithrombin III) which may be present.     

Poster Sessions AP02: Proteins,Amino Acids,Peptides and Metabolism. The effect of proline rich polypeptide on the interaction between activated factor X and anti‐thrombin III

The effect of the hypothalamic neurosecretory Proline Rich Polypeptide (PRP) on the interaction of human Factor Xa (Xa) with human antithrombin III (ATIII) was investigated by SDS–PAGE and Western Blot analysis. Xa runs as two bands with masses of ～51 and ～47 kDa. A fraction of the ATIII (～55 kDa) undergoes a conformational change upon interaction with Xa to run slower at ～58 kDa. Xa and ATIII form a 1° duplex complex of ～109 and ～104 kDa, a 2° duplex complex of ～99 and ～94 kDa, and a 3° duplex complex of ～66 and ～62 kDa. Additionally, a Xa degradation product (～35 kDa) is noted. Pre‐incubation of 1.5 μg of either Xa or ATIII with 8 μg PRP for 15′ at R.T., or essentially simultaneous addition of all three, increases the 2° complex upper band, 3° complex lower band, ATIII conformational change, and the Xa degradation product. It also decreases the 3° complex upper band and the native ATIII. Xa/PRP premixtures cause a decrease in unreacted Xa. ATIII/PRP premixtures produce an increase in the 1° complex lower band and a decrease in the unreacted Xa upper band. Xa/ATIII/PRP mixtures increase both bands of the 1° complex. Thus, 8 μg PRP promotes 1° complex formation as well as formation of the 2° and 3° degradation complexes. It also promotes modification of ATIII and degradation of Xa, possibly by autolysis and/or promotion of proteolysis of the 1° complex by free Xa. Data obtained indicate the role of PRP in the molecular mechanisms of blood clotting. (Supported, in part, from a grant by the Office of Sponsored Programs and Research, BGSU.)