Project description:Rat skin heparin proteoglycans vary markedly in the proportions of their constituent polysaccharide chains that have high binding affinity for antithrombin. As the proportion of such chains in a proteoglycan rises, their degree of affinity for antithrombin also increases [Horner (1987) Biochem. J. 244, 693-698]. The antithrombin-binding-site densities of such chains have now been determined, by measuring heparin-induced enhancement of the intrinsic fluorescence of antithrombin and by chemical analysis for the disaccharide sequence glucuronosyl-N-sulphoglucosaminyl (3,6-di-O-sulphate), which is unique to this site in heparin [Lindahl, Bäckström, Thunberg & Leder (1980) Proc. Natl. Acad. Sci. U.S.A. 77, 6551-6555]. Antithrombin-binding-site density ranged from one to five sites per chain.

Project description:Approximately half of all rat skin heparin proteoglycans have polysaccharide chains that have no sites with high binding affinity for antithrombin. The rest have chains with high-affinity antithrombin-binding-site densities ranging from zero to five sites per chain, with a high degree of variation. Proteoglycans vary in size because of diversity in the number of chains per molecule; the relationship between proteoglycan size and high-affinity antithrombin-binding-site density has not been studied previously. Polydisperse heparin proteoglycans from rat skin, labelled biosynthetically with 35S, were fractionated by gel filtration on Bio-Gel A-150m and arbitrarily divided into five fractions of decreasing average molecular size. Fractionation of these products on antithrombin-agarose showed that the proportion of proteoglycans with high affinity for antithrombin decreased from 39% to 25% as molecular size decreased. However, as the molecular size of high-affinity proteoglycans decreased, the proportion of their chains that had high affinity increased from 29% to 59%. Therefore molecular size is a significant factor in determining the proportion of high-affinity chains in heparin proteoglycans. A model of heparin biosynthesis is proposed in which areas of specific enzyme activity that control the synthesis of the antithrombin-binding-site sequence are sparsely and nonrandomly distributed on mast-cell Golgi membranes. It is postulated that the likelihood of a developing proteoglycan encountering one of these hypothetical areas is molecular-size-dependent.

Project description:Rat skin heparin proteoglycan labelled biosynthetically with 35S was fractionated on a column of antithrombin-Sepharose into fractions with varying degrees of affinity for antithrombin. These were treated with NaOH to release heparin chains (Mr 60,000-100,000), by beta-elimination or incubated with serum to produce fragments of the same order of size as commercial heparin (Mr 5000-30,000), by endoglycosidase cleavage. Chains and fragments were then fractionated on antithrombin-Sepharose. The various fractions were deaminated with HNO2 at pH 1.5 followed by reduction with NaB3H4. Approx 90% of the incorporated 3H was associated with disaccharides. These were fractionated by high-performance ion-exchange chromatography. A unique minor component corresponding to the sequence glucuronosyl-N-sulphoglucosaminyl (3,6-di-O-sulphate) in the polysaccharide was found only in fractions with high affinity for antithrombin. The glucosamine residue linked to C-4 of this glucuronosyl unit was predominantly (or exclusively) N-sulphated rather than N-acetylated, pointing to a structural difference between the antithrombin-binding region of rat heparin and that of pig mucosal heparin. Calculations based on the distribution of the glucosaminyl 3-O-sulphate group showed that approximately two-thirds of the total antithrombin-binding regions present in the unfractionated material were accommodated by only 20% of the proteoglycan molecules, and by 10% of the polysaccharide chains. While most of the proteoglycan molecules thus lacked such regions (and hence affinity for antithrombin) a minor proportion of the polysaccharide chains contained on the average three binding regions per molecule. These findings support by direct chemical analysis an earlier proposal, based on anticoagulant activities of similar rat skin heparin fractions, that the distribution of antithrombin-binding sites in intact heparin proteoglycans is markedly non-random.

Project description:Glycosaminoglycan (GAG)-protein interactions modulate many important biological processes. Structure-function studies on GAGs may reveal probes and drugs, but their structural complexity and highly acidic nature confound such work. Productivity will increase if we are able to identify tight-binding oligosaccharides in silico. An extension of the CHARMM force field is presented to enable modeling of polysaccharides containing sulfamate functionality, and is used to develop a reliable alchemical free-energy perturbation protocol that estimates changes in affinity for the prototypical heparin-antithrombin system to within 2.3 kcal/mol using modest simulation times. Inclusion of water is crucial during simulation as solvation energy was equal in magnitude to the sum of all other thermodynamic factors. In summary, we have identified and optimized a reliable method for estimation of GAG-protein binding affinity, and shown that solvation is a crucial component in GAG-protein interactions.

Project description:[35S]Heparin proteoglycans were isolated from the skins and peritoneal mast cells of male rats aged 2 to 22 months. Their [35S]heparin chains were separated on antithrombin-agarose into fractions with high and low affinities for antithrombin. In skin, the proportion of 35S-labelled high-affinity heparin chains declined from 23% at 2 months to 8% at 12 months and did not change significantly between 12 and 22 months. In peritoneal mast cells, the proportion of 35S-labelled high-affinity heparin chains increased from 14% at 2 months to 21% at 4 months and then did not vary significantly until 15 months of age. By 21 months a consistent and significant decline to 8% occurred. The structures of high-affinity heparin proteoglycans did not change with age. Their decreased proportions, without change in their structure, may indicate that they are produced by a unique subset of mast cells, the proportion of which declines with age. [35S]heparan sulphate chains were isolated from skins and brains of rats in the same age range and fractionated on antithrombin-agarose. There were no significant variations in the proportions of 35S-labelled high-affinity heparan sulphate chains in skin (10%) or brain (24%) between 4 and 22 months of age.

Project description:35S-labelled heparins were recovered from adipose tissue, hearts, lungs, peritoneal cavities and skins of rats given H2(35)SO4. Their purification involved incubation with Pronase, precipitation with cetylpyridinium chloride in 1.0 M-NaCl, gradient elution from DEAE-Sephacel and incubation with chondroitinase ABC. Each product was divided into proteoglycan and "depolymerization products' fractions by gel filtration on Bio-Gel A-15m. Heparin chains were released from a portion of each proteoglycan fraction by beta-elimination with NaOH. Proteoglycans, chains and depolymerization products were separated by gradient elution from a column of antithrombin-agarose into fractions with no affinity, low affinity and high affinity for antithrombin. The relative sizes of the products were determined by gel filtration on columns of Bio-Gel A-50m, A-15m, A-1.5m and A-0.5m. Skin was the major source of heparin and contained the largest proteoglycans and the lowest proportion of depolymerization products. Lungs contained the smallest proteoglycans, the smallest depolymerization products and the highest proportion of depolymerization products. The highest proportions of proteoglycans, chains and depolymerization products with high affinity for antithrombin were found in adipose tissue. The lowest proportions of each of these fractions were found in the peritoneal cavity. The data suggest that there was relatively little biosynthesis of sites with high affinity for antithrombin in peritoneal-cavity mast cells and that heparin catabolism was most active in lungs. Each source of heparin was unique with respect to both biosynthesis and subsequent breakdown of its proteoglycans.

Project description:Recombinant antithrombin produced by baby hamster kidney (BHK) or Chinese hamster ovary (CHO) cells was separated into two fractions, containing comparable amounts of protein, by affinity chromatography on matrix-linked heparin. Fluorescence titrations showed that the more tightly binding fraction had a heparin affinity similar to that of plasma antithrombin (Kd approximately 20 nM), whereas the affinity of the more weakly binding fraction was nearly 10-fold lower (Kd approximately 175 nM). Analyses of the heparin-catalysed rate of inhibition of thrombin further showed that the fractions differed only in their affinity for heparin and not in the intrinsic rate constant of either the uncatalysed or the heparin-catalysed inactivation of thrombin. The recombinant antithrombin fraction with lower heparin affinity migrated more slowly than both the fraction with higher affinity and plasma antithrombin in SDS/PAGE under reducing conditions, consistent with a slightly higher apparent relative molecular mass. This apparent size difference was abolished by the enzymic removal of the carbohydrate side chains from the proteins. Such removal also increased the heparin affinity of the weakly binding fraction, so that it eluted from matrix-linked heparin at a similar position to the deglycosylated tightly binding fraction or plasma antithrombin. Analyses of N-linked carbohydrate side chains showed that the weakly binding fraction from CHO cells had a higher proportion of tetra-antennary and a lower proportion of biantennary oligosaccharides than the tightly binding fraction. We conclude that the recombinant antithrombin produced by the two cell lines is heterogeneously glycosylated and that the increased carbohydrate content of a large proportion of the molecules results in a substantial decrease in the affinity of these molecules for heparin. These findings are of particular relevance for studies aimed at characterizing the heparin-binding site of recombinant antithrombin by site-directed mutagenesis.

Project description:Regulation of blood coagulation is critical for maintaining blood flow, while preventing excessive bleeding or thrombosis. One of the principal regulatory mechanisms involves heparin activation of the serpin antithrombin (AT). Inhibition of several coagulation proteases is accelerated by up to 10,000-fold by heparin, either through bridging AT and the protease or by inducing allosteric changes in the properties of AT. The anticoagulant effect of short heparin chains, including the minimal AT-specific pentasaccharide, is mediated exclusively through the allosteric activation of AT towards efficient inhibition of coagulation factors (f) IXa and Xa. Here we present the crystallographic structure of the recognition (Michaelis) complex between heparin-activated AT and S195A fXa, revealing the extensive exosite contacts that confer specificity. The heparin-induced conformational change in AT is required to allow simultaneous contacts within the active site and two distinct exosites of fXa (36-loop and the autolysis loop). This structure explains the molecular basis of protease recognition by AT, and the mechanism of action of the important therapeutic low-molecular-weight heparins.

Project description:In order to promote homogeneity of recombinant antithrombin III interactions with heparin, an asparagine-135 to alanine substitution mutant was expressed in baculovirus-infected insect cells. The N135A variant does not bear an N-linked oligosaccharide on residue 135 and is therefore similar to the beta isoform of plasma antithrombin. Purified bv.hat3.N135A is homogeneous with respect to molecular mass, charge and elution from immobilized heparin. Second-order rate constants for thrombin and factor Xa inhibition determined in the absence and presence of heparin are in good agreement with values established for plasma antithrombin and these enzymes. Based on far- and near-UV CD, bv.hat3.N135A has a high degree of conformational similarity to plasma antithrombin. Near-UV CD, absorption difference and fluorescence spectroscopy studies indicate that it also undergoes an identical or very similar conformational change upon heparin binding. The Kds of bv.hat3.N135A for high-affinity heparin and pentasaccharide were determined and are in good agreement with those of the plasma beta-antithrombin isoform. The demonstrated similarity of bv.hat3.N135A and plasma antithrombin interactions with target proteinases and heparins suggest that it will be a useful base molecule for investigating the structural basis of antithrombin III heparin cofactor activity.

Project description:Heparanase is an endoglycosidase that participates in morphogenesis, tissue repair, heparan sulphates turnover and immune response processes. It is over-expressed in tumor cells favoring the metastasis as it penetrates the endothelial layer that lines blood vessels and facilitates the metastasis by degradation of heparan sulphate proteoglycans of the extracellular matrix. Heparanase may also affect the hemostatic system in a non-enzymatic manner, up-regulating the expression of tissue factor, which is the initiator of blood coagulation, and dissociating tissue factor pathway inhibitor on the cell surface membrane of endothelial and tumor cells, thus resulting in a procoagulant state. Trying to check the effect of heparanase on heparin, a highly sulphated glycosaminoglycan, when it activates antithrombin, our results demonstrated that heparanase, but not proheparanase, interacted directly with antithrombin in a non-covalent manner. This interaction resulted in the activation of antithrombin, which is the most important endogenous anticoagulant. This activation mainly accelerated FXa inhibition, supporting an allosteric activation effect. Heparanase bound to the heparin binding site of antithrombin as the activation of Pro41Leu, Arg47Cys, Lys114Ala and Lys125Alaantithrombin mutants was impaired when it was compared to wild type antithrombin. Intrinsic fluorescence analysis showed that heparanase induced an activating conformational change in antithrombin similar to that induced by heparin and with a KD of 18.81 pM. In conclusion, under physiological pH and low levels of tissue factor, heparanase may exert a non-enzymatic function interacting and activating the inhibitory function of antithrombin.