Binding of heparin fractions and other polysulfated polysaccharides to plasma fibronectin: effects of molecular size and degree of sulfation of polysaccharides

Heparin was divided into four fractions on fibronectin-Sepharose. The higher affinity fraction for fibronectin was larger in molecular size, higher in sulfate content and higher in affinity for anti-thrombin III. Together with these heparin fractions, the following three series of heparin samples were examined to compare the affinity for fibronectin-Sepharose: four fractions separated on Sephadex G-100; five fractions separated on antithrombin III-Sepharose, and six partially and completely N-desulfated heparins. The result showed that the affinity of heparin for fibronectin was dependent exclusively on its molecular size, and that an appropriate level of sulfate content in heparin (1.9-2.4 mol/disaccharide) was essential for the affinity. The sulfated preparations of glycosaminoglycans (heparan sulfate, dermatan sulfate and chondroitin 4-sulfate) and neutral polysaccharides (amylose and dextran) having higher sulfate content than heparin were found to display higher affinity for fibronectin than heparin. This suggested that highly sulfated polysaccharides showed potent affinity irrespective of their polysaccharide structure. The sulfated chondroitin 4-sulfate having a sulfate content and molecular size comparable to those of heparin was inferior to heparin with respect to affinity. A competitive dissociation experiment indicated that heparin and other polysulfated polysaccharides share a common binding site on the fibronectin molecule.     

Studies on the mechanism of the rate-enhancing effect of heparin on the thrombin-antithrombin III reaction.

The rate of the reaction between thrombin and antithrombin III is greatly increased in the presence of heparin. Several mechanisms for this effect are possible. To study the problems commercial heparin was fractionated into one fraction of high anticogulant activity and one of low anticoagulant activity by affinity chromatography on matrix-bound antithrombin III. The strength of the binding of the two heparin fractions to antithrombin III and thrombin, respectively, was determined by a crossed immunoelectrophoresis technique. As was to be expected, the high activity fraction was strongly bound to antithrombin III while the low activity fraction was weakly bound. In contrast, thrombin showed equal binding affinity for both heparin fractions. The ability of the two heparin fractions to catalyse the inhibition of thrombin by antithrombin III was determined and was found to be much greater for the high activity heparin fraction. A mechanism for the reaction between thrombin and antithrombin III in the presence of small amounts of heparin is suggested, whereby antithrombin III first binds heparin and this complex then inhibits thrombin by interaction with both the bound heparin and the antithrombin III.     

Kinetic analysis of various heparin fractions and heparin substitutes in the thrombin inhibition reaction

Kinetic characteristics of several heparin preparations and substitute heparins were determined to help understand the bases for activity differences. Several materials were highly active in factor Xa inhibition and the reaction rate at constant factor Xa concentration appeared to be predicted by the extent of intrinsic antithrombin III fluorescence change induced by the polysaccharide. Heparin fractions of different molecular weight and affinity for antithrombin III showed similar kinetic parameters in catalysis of the thrombin-antithrombin III reaction when these parameters were expressed on the basis of antithrombin III-binding heparin. The latter was determined by stoichiometric titration of the antithrombin III fluorescence change by the heparin preparation. However, the various heparin fractions showed very different specific activities per mg of total polysaccharide. This indicated that functional heparin molecules had similar kinetic properties regardless of size or antithrombin III-binding affinity and is possible because the Km for antithrombin III is determined by diffusion rather than by binding affinity. Substitute heparins and depolymerized heparin were poor catalysts for thrombin inhibition, due at least partially to their affinity for thrombin. This latter binary interaction inhibits thrombin reaction in the heparin-catalyzed reaction.     

Diversity-oriented chemical modification of heparin: Identification of charge-reduced N-acyl heparin derivatives having increased selectivity for heparin-binding proteins

The diversity-oriented chemical modification of heparin is shown to afford charge-reduced heparin derivatives that possess increased selectivity for binding heparin-binding proteins. Variable N-desulfonation of heparin was employed to afford heparin fractions possessing varied levels of free amine. These N-desulfonated heparin fractions were selectively N-acylated with structurally diverse carboxylic acids using a parallel synthesis protocol to generate a library of 133 heparin-derived structures. Screening library members to compare affinity for heparin-binding proteins revealed unique heparin-derived structures possessing increased affinity and selectivity for individual heparin-binding proteins. Moreover, N-sulfo groups in heparin previously shown to be required for heparin to bind specific proteins have been replaced with structurally diverse non-anionic moieties to afford identification of charge-reduced heparin derivatives that bind these proteins with equivalent or increased affinity compared to unmodified heparin. The methods described here outline a process that we feel will be applicable to the systematic chemical modification of natural polyanionic polysaccharides and the preparation of synthetic oligosaccharides to identify charge-reduced high affinity ligands for heparin-binding proteins.     

Purification of rat adipose tissue lipoprotein lipase by affinity chromatography.

Lipoprotein lipase (EC 3.1.1.3) from rat adipose tissue was purified by affinity chromatography with heparin-Sepharose. Elution was carried out with buffered solutions of increasing NaCl molarity. Proteins without affinity for heparin were eluted with 0.5 M NaCl, while lipoprotein lipase activity was eluted as two peaks with 1.16 M NaCl (In earlier work on human adipose tissue (Etienne et al. (1974) C.R. Acad. Sc. Paris 279, 1487-1490) two fractions with lipoprotein lipase activity were also obtained). Phospholipase activity was detected in the fraction eluted with buffered 0.5 M NaCl and containing proteins without affinity for heparin. On feeding the fasting rats with fresh cream or glucose two peaks were also obtained, but the first peak had clearly increased while the second one had remained virtually unchanged.     

[Identification and characterization of two phospholipase A2 activities in resident mouse peritoneal macrophages.]

The interaction between bovine antithrombin, a plasma proteinase inhibitor, and heparin species of different molecular weights was studied. A commercial heparin preparation was divided by gel chromatography into a number of fractions with average molecular weights ranging from 6000 to 34700. Each of these fractions was further fractionated by affinity chromatography on matrix-bound antithrombin. In the latter procedure, those heparin fractions that had molecular weights lower than about 14000 were separated into three peaks. The material in the first of these was not adsorbed on the column, and the other two peaks corresponded to the low-affinity and high-affinity peaks described previously. In contrast, high-molecular-weight heparin samples gave only the low-affinity and high-affinity fractions. U.v. difference absorption studies showed that the non-adsorbed heparin fraction bound to antithrombin in solution with a binding constant at physiological ionic strength only slightly lower than that of low-affinity heparin. The division between the two fractions thus is arbitrary and only dependent on the conditions selected for the affinity-chromatography experiment. Stoicheiometries and binding constants for the binding of several high-affinity heparin species to antithrombin were determined by fluorescence titrations. High-affinity heparin fractions of equal elution positions in the beginning of the peaks of the affinity chromatographies, but with different molecular weights, showed stoicheiometries that were not experimentally distinguishable from 1:1 and also had no appreciable differences in binding constants. However, the anticoagulant activities, calculated on a molar basis, of these fractions increased markedly with molecular weight, a behaviour that thus cannot be explained by differences in the binding of the fractions to antithrombin. In contrast, high-affinity samples of similar molecular weights, which were eluted at increasing ionic strengths from matrix-linked antithrombin, were found to have an increasing proportion of chains with two binding sites for antithrombin and also to have progressively higher binding constants. These binding properties at least partly explain the increasing anticoagulant activities that were observed for these fractions.     

Location of antithrombin-binding regions in rat skin heparin proteoglycans.

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.     

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.     

Dependence of antithrombin III and thrombin binding stoichiometries and catalytic activity on the molecular weight of affinity-purified heparin

Heparin was fractionated by affinity chromatography on immobilized antithrombin III followed by gel filtration on Sephadex G-100. Eighteen fractions were obtained ranging in molecular weight from 9,700 to 34,300 as determined by sedimentation equilibrium. The binding stoichiometries of antithrombin III and thrombin interactions with the heparin of these fractions were measured, using changes in intrinsic and extrinsic fluorescence. Catalytic activity also was measured for each of the heparin fractions. As the molecular weight of heparin varied from about 10,000 to 30,000, the average number of antithrombin and thrombin sites/heparin molecule varied from 1.0 to 2.1 and 2.4 to 6.8. In addition, the molar specific activity increased 5.7-fold, an increase which correlated directly with the product of the number of antithrombin III and thrombin molecules bound. Thus as the number of bound molecules increased with increased molecular weight, the rate of reaction/bound antithrombin III increased in proportion to the number of bound thrombin molecules and vice versa. This can be explained by assuming that heparin functions as a template for both proteins, that all bound thrombin and antithrombin III molecules are accessible to each other, and that the rate at which a bound molecule reacts is proportional to the number of molecules of its interacting counterpart bound. These observations and conclusions are similar to those of Hoylaerts et al. (Hoylaerts, M., Owen, W. G., and Collen, D. (1984) J. Biol. Chem. 259, 5670-5677), who demonstrated that the rate at which single molecules of antithrombin III, covalently attached to heparin, react increases as the thrombin binding capacity (chain length) of heparin increases.     

Endothelial binding sites for heparin. Specificity and role in heparin neutralization.

The specificity of endothelial binding sites for heparin was investigated with heparin fractions and fragments differing in their Mr, charge density and affinity for antithrombin III, as well as with heparinoids and other anionic polyelectrolytes (polystyrene sulphonates). The affinity for endothelial cells was estimated by determining I50 values in competition experiments with 125I-heparin. We found that affinity for endothelial cells increases as a function of Mr and charge density (degree of sulphation). Binding sites are not specific receptors for heparin. Other anionic polyelectrolytes, such as pentosan polysulphates and polystyrene sulphonates, competed with heparin for binding to endothelial cells. Fractions of standard heparin with high affinity for antithrombin III also had greater affinity for endothelium. However, these two properties of heparin (affinity for antithrombin III and affinity for endothelial cells) could be dissociated. Oversulphated heparins and oversulphated low-Mr heparin fragments had lower anticoagulant activity and higher affinity for endothelial cells than did their parent compounds. Synthetic pentasaccharides, bearing the minimal sequence for binding to antithrombin III, did not bind to endothelial cells. Binding to endothelial cells involved partial neutralization of heparin. Bound heparin exhibited only 5% and 7% of antifactor IIa and antifactor Xa specific activity, respectively. In the presence of 200 nM-antithrombin III, and in the absence of free heparin, a limited fraction (approx. 30%) of bound heparin was displaced from endothelial cells during a 1 h incubation period. These data suggested that a fraction of surface-bound heparin could represent a pool of anticoagulant.     

Rat heparins. A study of the relative sizes and antithrombin-binding characteristics of heparin proteoglycans, chains and depolymerization products from rat adipose tissue, heart, lungs, peritoneal cavity and skin.

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.     

Purification of a heparin binding FGF receptor (HB-FGFR) from adult bovine brain membranes

A new form of high affinity fibroblast growth factor receptor has been purified from adult bovine brain membranes. Purification was performed by chromatography on DEAE-Trisacryl and wheat germ agglutinin-agarose followed by FGF-2 affinity chromatography. Affinity labeling of purified fractions with 125I-FGF-2 showed after cross-linking a 170-kDa complex, suggesting the existence of a 150-kDa FGF receptor. No cross-reactivity with anti-FGF receptor 1 (FGFR-1 or flg) or with anti-receptor 2 (FGFR-2 or bek) antibodies could be detected with this partially purified receptor. Heparitinase treatment of the partially purified FGF receptor abolished the formation of the ligand receptor complex. The complex was restored in the presence of heparin in a dose dependent fashion, supporting the idea that heparin-like molecules are needed for proper binding. Further purification of the receptor was achieved by heparin-Sepharose affinity chromatography and yielded a purification of over 320,000-fold. The purified receptor fraction was radiolabeled and loaded on RPLC C4 column. Eluted fractions were analysed by SDS-PAGE. A major 150-kDa band was detected. These data show for the first time a new form of FGF receptor isolated from bovine brain membranes. This purified receptor displays affinity for heparin and was therefore named heparin binding FGF receptor (HB-FGFR). It remains unclear whether the receptor is a proteo-heparin sulfate or whether heparans are strongly associated and therefore are copurified. Large scale preparations are in progress for core protein structure studies.     

Heterogeneity of depolymerized heparin SEC fractions: to pool or not to pool?

In the structural analysis of heparin and heparan sulfate, it is customary to combine or pool like-sized fractions obtained by size-exclusion chromatography (SEC) of enzymatically derived heparin oligosaccharides. In this study, we examine the heterogeneity of preparative-scale SEC fractions obtained from enzymatic digests of porcine intestinal mucosa heparin. Each fraction was profiled by capillary electrophoresis with UV detection (CE−UV) using a 60 mM formic acid running buffer at pH 3.43. Differences in the composition and relative concentration of components of the SEC fractions were observed for disaccharides and larger oligosaccharides. The heterogeneity of the fractions becomes more pronounced when heparin is digested using a heparin lyase cocktail. The heterogeneity of preparative SEC fractions was further investigated by reversed-phase ion-pairing ultraperformance liquid chromatography coupled with mass spectrometry (RPIP−UPLC−MS) using the ion-pairing reagent, tributylamine (Bu₃N). Our results suggest that preliminary profiling of preparative SEC fractions prior to pooling may simplify efforts to identify and/or isolate rare structures.     

Purification of heparinase and heparitinase by affinity chromatography on glycosaminoglycan-bound ah-sepha-rose 4b

Heparinase and heparitinase were separated from an extract of Flavobacterium heparinum, induced with heparin by using column chromatography on hydroxylapatite. As the heparinase preparation contained chondroitinases B and C, chondroitinase B was removed by rechromatography on a hydroxylapatite column. Chondroitinase C was then eliminated by column chromatography on O-phosphono(“phospho”)-cellulose. The heparinase preparation thus obtained was free from sulfoamidase for 2-deoxy-2-sulfoamino-D-glucose (GlcN-2S), sulfatase for 2-amino-2-deoxy-6-O-sulfo D-glucose (GlcN-6S), as well as (δ_4,5glycosiduronase for the unsaturated disaccharides obtained from heparin. The remaining sulfatase for 4-deoxy-α-L-thero-hex-4-enopyranosyluronic acid 2-sulfate (δUA-2S) in the heparinase preparation was removed by affinity chromatography with dermatan sulfate-bound AH-Sepharose 4B coated with dermatan sulfate. The heparitinase preparation separated by column chromatography on hydroxyla patite was purified by affinity chromatography with heparin-bound AH-Sepharose 4B coated with heparin. Sulfatase for 2-amino-2-deoxy-6-O-sulfo-D-glucose (GlcN-6S) and δ_4,5glycosiduronase for the unsaturated disaccharides obtained from heparin were removed by this chromatography. Sulfatase for 4-deoxy-α-L-threo-hex-4-enopyranosyluronic acid 2-sulfate (δUA-2S) remaining in the heparitinase preparation was finally removed by column chromatography on hydroxylapatite. The recoveries of the purified preparations of heparinase and heparitinase were estimated to be 39 and 50%, respectively, from the crude enzyme fractions obtained by the first column chromatography on hydroxyl- patite. The purified heparinase and heparitinase were free from all enzymes that could degrade the sulfated unsaturated disaccharides produced from heparin with heparinase.     

Antithrombin binding of low molecular weight heparins and inhibition of factor Xa

Fluorescence and stopped flow methods were used to compare clinically used heparins with regard to their ability to bind to antithrombin and to accelerate the inactivation of factor Xa. Titration of antithrombin with both low molecular weight heparin (LMWH) (enoxaparin, fragmin and ardeparin) and unfractionated heparin (UFH) produced an equivalent fluorescence increase and indicates similar affinity of all heparin preparations to antithrombin. However, relative to UFH enoxaparin, the LMWH with the smallest average molecular mass, contained only 12% material with high affinity for antithrombin. The rate of factor Xa inhibition by antithrombin increased with the concentration of the examined heparins to the same limiting value, but the concentration required for maximal acceleration depended on the preparation. According to these data the high affinity fraction of the heparin preparations increased the intrinsic fluorescence and inhibitory activity equally without additional effects by variations in chain length and chemical composition. In contrast, in the presence of Ca UFH accelerated the inhibition of factor Xa by antithrombin 10-fold more efficiently than comparable concentrations of the high affinity fractions of enoxaparin and fragmin. The bell-shaped dependence of this accelerating effect suggests simultaneous binding of both proteins to heparin. In conclusion, under physiologic conditions the anti-factor Xa activity of heparin results from a composite effect of chain length and the content of material with high affinity to antithrombin. Thus, the reduced antithrombotic activity of LMWH relative to UFH results from a smaller content of high affinity material and the absence of a stimulating effect of calcium.     

Hydrophobic-interaction chromatography of glycosaminoglycuronans: the contribution of N-acetyl groups in heparin and heparan sulfate to the affinity for hydrophobic gels, and variety of molecular species in beef-kidney heparan sulfate

Contribution of N-acetyl groups in heparin and heparan sulfate to their affinity for hydrophobic gels was examined by use of a series of semi-synthetic, N-acetylated, hog-intestinal heparins, a whale-intestinal heparin, and a beef-kidney heparan sulfate. Chromatography on Phenyl-Sepharose CL-4B in 3.8-1.0M ammonium sulfate-10mM hydrochloric acid indicated that an increasing N-acetyl content, which is correlated to a decreasing N-sulfate content, results in a marked increase in the affinity for the gels. The variety of molecular species in beef-kidney heparan sulfate, previously fractionated by conventional chromatographic procedures, was demonstrated by separating further, by hydrophobic-interaction chromatography, the polysaccharide into several fractions composed of molecular species distinctly different in N-acetyl and sulfate content, and in molecular size.     

Biosynthesis of heparin. Availability of glucosaminyl 3-O-sulfation sites

Heparin preparations isolated from pig intestinal mucosa and from bovine lung were fractionated with regard to affinity for antithrombin. The resulting fractions, with high (HA) or low (LA) affinity for the proteinase inhibitor, were analyzed by 13C NMR or by identification of di- and tetrasaccharides obtained through deaminative cleavage with nitrous acid. Structural differences between corresponding HA and LA fractions were essentially restricted to minor constituents, in particular 3-O-sulfated glucosamine units that occurred (1 or 2 residues/chain) in all HA preparations but were scarce or absent in LA heparin. The HA fractions also consistently showed higher contents of nonsulfated iduronic acid and, to a lesser extent, N-acetylated glucosamine units than the LA fractions. The two tetrasaccharide sequences, -IdoA-GlcNAc(6-OSO3)-GlcA-GlcNSO3- and -IdoA-GlcNAc(6-OSO3)-GlcA-GlcNSO3(6-OSO3)- , recently implicated as part of the acceptor site for glucosaminyl 3-O-sulfate groups (Kusche, M., B?ckstr?m, G., Riesenfeld, J., Petitou, M., Choay, J., and Lindahl, U. (1988) J. Biol. Chem. 263, 15474-15484), were identified in mucosal LA heparin; it was calculated that the preparation contained approximately one potential acceptor site/polysaccharide chain. Yet this material did not yield any labeled HA components on incubation with adenosine 3'-phosphate 5'-phospho-[35S]sulfate in the presence of glucosaminyl 3-O-sulfotransferase, solubilized from a mouse mastocytoma microsomal fraction. The failure to incorporate any 3-O-sulfate groups could conceivably be explained by the occurrence of a D-glucuronic rather than L-iduronic acid unit linked at the reducing ends of the above tetrasaccharide sequences. Alternatively, 3-O-sulfation may be restricted by other, as yet unidentified, inhibitory structural elements that are preferentially expressed in polysaccharide sequences selected for the generation of LA heparin.     

The molecular-weight dependence of the rate-enhancing effect of heparin on the inhibition of thrombin, factor Xa, factor IXa, factor XIa, factor XIIa and kallikrein by antithrombin.

Heparin fractions of different molecular weight and with high affinity for antithrombin were studied with respect to their ability to potentiate the inhibition of activated clotting factors by antithrombin. Inhibition of thrombin, Factor IXa and Factor XIa showed similarities in the dependence on the molecular weight of heparin and was found to decrease with decreasing molecular weight. Inactivation of Factor Xa, Factor XIIa and kallikrein was, however, less dependent on the size of the polysaccharide and, to a great extent, was potentiated even by low-molecular-weight heparin fractions that had virtually no effect on the inhibition of thrombin, Factor IXa and Factor XIa.     

Apolipoprotein E mediates binding of normal very low density lipoprotein to heparin but is not required for high affinity receptor binding

The relationship between the cholesteryl ester content of normal human very low density lipoprotein (VLDL) and its ability to bind to apolipoprotein E (apoE), heparin, and the low density lipoprotein (LDL) receptor have been compared. Plasma VLDL were separated by heparin affinity chromatography into two fractions: one with apoE and one without. Both fractions had the same cholesteryl ester content relative to apolipoprotein B (apoB). LDL, on the other hand, had a greater cholesteryl ester content. VLDL were modified by lipolysis to express the ability to bind apoE (Ishikawa, Y., Fielding, C. J., and Fielding, P. E. (1988) J. Biol. Chem. 263, 2744-2749). Lipolyzed VLDL with or without apoE were compared for their ability to bind to heparin or the up-regulated fibroblast LDL receptor. Lipolyzed VLDL bound with the same affinity to the receptor whether or not the particles contained apoE. ApoB, not apoE, appears then to be the important ligand for normal VLDL. On the other hand, modified VLDL without apoE, even though binding to the LDL receptor, did not bind to heparin. These data suggest that apoE mediates heparin binding in normal VLDL, that apoB mediates receptor binding, and that the cholesteryl ester content of VLDL is not a factor in the induction of the ability to bind apoE.     

Effect of heparin chain length on the interaction with tissue factor pathway inhibitor (TFPI)

Tissue factor pathway inhibitor (TFPI) is a heparin-binding protein involved in the extrinsic blood coagulation system. In order to elucidate the minimal size of heparin chain required for the interaction with TFPI, we prepared a series of heparin-derived oligosaccharides with tailored chain length ranged from disaccharide to eicosasaccharide after the successive treatments of heparin, including partial N-desulphation, deaminative cleavage with nitrous acid and gel-filtration. Affinity chromatography study of each oligosaccharide fraction using TFPI as the ligand indicated that increasing the degree of polymerisation causes increased affinity, and that a remarkable change in the affinity occurs between the decamers and dodecamers. Measurement of factor Xa inhibitory activity of TFPI in the presence of each oligosaccharide fraction indicated that the fractions shorter than dodecamers only slightly enhanced the TFPI activity for factor Xa inhibition, while the fractions larger than octadecamers had an effect comparable to full-length heparin. These were compatible to the results from the kinetic analyses of the interaction between TFPI and heparin-derived oligosaccharide with an evanescent wave-based biosensor system, IAsys, using a TFPI C-terminal peptide as the ligand.