Examination of the substrate specificity of heparin and heparan sulfate lyases

High-performance liquid chromatographic analysis of glycosaminoglycan-derived oligosaccharides

High-performance liquid chromatography of glycosaminoglycan (GAG)-derived oligosaccharides has been employed for the structural analysis and measurement of hyaluronan, chondroitin sulphate, dermatan sulphate, keratan sulphate, heparan sulphate and heparin. Recent developments in the separation and detection of unsaturated disaccharides and oligosaccharides derived from GAGs by enzymatic or chemical degradation are reviewed.

Receptors for fibroblast growth factors

The recent discovery of the involvement of heparan sulfate proteoglycans (HSPG) in the activation of fibroblast growth factor receptors (FGFR) has led to an intensification of study of this field. It appears that the HSPG act as low affinity receptors to which the fibroblast growth factors (FGF) must bind in order to successfully activate the high affinity FGFR. Heparan sulfate chains consisting of alternately arranged N-acetylated or N-sulfated glucosamine and uronic acid disaccharide regions, covalently attached to a core protein are found in two major families of cell surface HSPG, the syndecans and glypicans. A high affinity bFGF binding region has been isolated from fibroblast HS. There are four basic members of the FGFR family (FGFR 1-4), as well as a wealth of splice variants. The alternative forms of the basic receptors can have altered ligand binding or signalling qualities, depending on the region of the gene which is spliced. Investigations with null FGFR, incapable of signalling, have demonstrated the requirement for FGF in the organization of mammalian tissues and in embryonic patterning. Mutation of the FGFR genes has been recognized recently in human craniosynostoses where a single base pair mutation in the FGFR gene results in skeletal malformations specific to each syndrome. One suggestion is that the interaction of the mutant FGFR with the HSPG/FGF complex somehow contributes to the disease phenotype.

Structure determination of the octa- and decasaccharide sequences isolated from the carbohydrate-protein linkage region of porcine intestinal heparin

Previously we isolated a tetrasaccharide-serine and a hexasaccharide-serine from the carbohydrate-protein linkage region of porcine intestinal heparin after digestion with a mixture of Flavobacterium heparinase and heparitinases I and II (Sugahara, K., Yamada, S., Yoshida, K., de Waard, P., and Vliegenthart, J.F.G. (1992) J. Biol. Chem. 267, 1528-1533). In this study four longer carbohydrate sequences (I-IV) attached to Ser or a dipeptide (Ser-Gly or Gly-Ser), which accounted for at least 18.2% of the total linkage region, were isolated from the same heparin preparation after digestion with heparinase only. IV was successfully isolated only after subsequent digestion with glycuronate-2-sulfatase. Their structures were determined by chemical and enzymatic analyses and 1H NMR spectroscopy and found to be the following octa- and decasaccharide sequences attached to Ser in a molar ratio of 1.1:2.3:1.0:1.3: delta HexA(2S)alpha 1-4GlcN(NS,6S)alpha 1-4GlcA beta 1-4GlcNAc alpha 1-4- GlcA beta 1-3Gal beta 1-3Gal beta 1-4Xyl beta 1-O-Ser (I), delta HexA(2S)alpha 1- 4GlcN(NS,6S)alpha 1-4IdoA alpha 1-4GlcNAc alpha 1-4GlcA beta 1- 3Gal beta 1-3Gal beta 1-4Xyl beta 1-O-Ser (II), delta HexA(2S)alpha 1- 4GlcN(NS,6S)alpha 1- 4IdoA alpha 1-4GlcNAc alpha 1-4GlcA beta 1-4GlcNAc-alpha 1- 4GlcA beta 1-3Gal beta 1-3Gal beta 1-4Xyl beta 1-O-Ser (III), delta HexA alpha 1-4GlcN(NS,6S)alpha 1-4IdoA alpha 1-4GlcNAc(6S)alpha 1- 4GlcA beta 1-3Gal beta 1-3Gal beta 1-4Xyl beta 1-O-Ser (IV) (delta HexA, GlcA, IdoA, and GlcN represent 4,5-unsaturated hexuronic acid, D-glucuronic acid, L-iduronic acid, and D-glucosamine, whereas 2S, 6S, and NS stand for 2-sulfate, 6-sulfate, and N-sulfate, respectively). I and II contained 1 mol of Gly in addition to Ser. The four structures indicate that sulfation in heparin chains takes place on the monosaccharide residues located in closer vicinity to the core protein than found for heparan sulfate chains and that there exist at least several heparin subclass chains with different linkage region structures. The significance of the isolated structures is discussed in relation to the biological functions and the biosynthetic mechanisms of heparin.

Endothelial heparan sulfate proteoglycans that bind to L-selectin have glucosamine residues with unsubstituted amino groups

We earlier reported calcium-dependent, heparin-like L-selectin ligands in cultured bovine endothelial cells (Norgard-Sumnicht, K. E., Varki, N. M., and Varki, A. (1993) Science 261,480-483). Here we show that these are heparan sulfate proteoglycans (HSPGs) associated either with the cultured cells or secreted into the medium and extracellular matrix. Activation of the endothelial cells with bacterial lipopolysaccharide (LPS) does not markedly alter the amount or distribution of this material. A major portion of the glycosaminoglycan (GAG) chains released from these HSPGs by alkaline beta-elimination rebinds to L-selectin in the presence of calcium, indicating that these saccharides alone can mediate the high affinity recognition. Heparin lyase digestions indicate that these GAG chains are enriched in heparan sulfate, not heparin sequences. Current understanding of the biosynthesis of heparan sulfate chains indicates that all glucosamine amino groups must be either N-acetylated or N-sulfated. However, nitrous acid deamination at pH 4.0 suggests the presence of some unsubstituted amino groups in these L-selectin-binding GAG chains from endothelial cell HSPGs. This is confirmed by chemical N-reacetylation and by reactivity with sulfo-N-hydroxysuccinimide-biotin. These unsubstituted amino groups are also found on HSPGs from human umbilical vein endothelial cells, but are not detected in those from Chinese hamster ovary cells. In both bovine and human endothelial cells, these novel groups are enriched for in the HS-GAG chains which bind to L-selectin. Despite this, studies with N-reacetylation and nitrous acid deamination do not show conclusive evidence for the direct involvement of the unsubstituted amino groups in L-selectin binding. This may be because the chemical reactions used to modify the amino groups do not go to completion. Alternatively, the unsubstituted amino groups may only be indirectly involved in generating binding, by dictating the biosynthesis of another critical group. Regardless, these studies shown that HSPGs from cultured endothelial cells which can bind to L-selectin are enriched with unsubstituted amino groups on their GAG chains. The possible biochemical mechanisms for generation of these novel groups are discussed.

Biosynthesis of heparin/heparan sulfate. The D-glucosaminyl 3-O-sulfotransferase reaction: target and inhibitor saccharides

O-Sulfation at C-3 of N-sulfated GlcN units concludes polymer modification and the formation of antithrombin binding regions in the biosynthesis of heparin/heparan sulfate. The resulting GlcNSO3(3-OSO3) units are largely restricted to heparin chains with high affinity for antithrombin (HA heparin). Low affinity (LA) heparin fails to serve as a substrate in the 3-O-sulfotransferase reaction yet contains potential 3-O-sulfate acceptor sites (Kusche, M., Torri, G., Casu, B., and Lindahl, U. (1990) J. Biol. Chem. 265, 7292-7300), as verified in the present study using a novel sequencing procedure. O-Desulfated, re-N-sulfated LA heparin, as well as an octasaccharide fraction isolated after heparinase I digestion of LA heparin, both yielded labeled HA components following incubation with solubilized mouse mastocytoma microsomal enzymes and [35S]adenosine 3'-phosphate 5'phosphosulfate (PAPS), suggesting that the 3-O-sulfo-transferase may be inhibited by sulfated saccharide sequences outside the 3-O-sulfate acceptor region. Indeed, the addition of LA heparin precluded enzymatic 3-O-sulfation of a synthetic pentasaccharide substrate. The Km for the pentasaccharide was determined to approximately be 6 microM. Incubations of mixed pentasaccharide substrate and saccharide inhibitors revealed Ki values for intact LA heparin and for a heparin octasaccharide fraction of approximately 1.3 and approximately 0.7 microM, respectively. Inhibition experiments with selectively desulfated heparin indicated that both IdoA 2-O-sulfate and GlcN 6-O-sulfate groups contributed to the inhibition of the 3-O-sulfotransferase. By contrast, chondroitin sulfate or dermatan sulfate showed no significant inhibitory activity. It is proposed that the regulation of GlcN 3-O-sulfation during biosynthesis of heparin/heparan sulfate depends on the topological organization of the membrane-bound enzyme machinery in the intact cell.

Molecular structure of heparan sulphate synthesised by bovine aortic endothelial cells

The distribution and structure of heparan sulphate (HS) synthesised by bovine aortic endothelial cells (BAEC) has been studied. Confluent cultures were harvested and analysed as three separate compartments: (a) the culture medium, (b) the detergent-soluble cell-associated material and (c) the detergent-insoluble matrix material extracted with 6 M urea. HS was present in all three of the culture compartments, but the molecular size of the HS proteoglycans (PG) and the free polysaccharide chains varied according to compartment origin. The matrix pool accounted for almost 50% of the total HS which was present as a large HSPG possessing polysaccharide chains of 79 kDa. When studied in more detail, these large HS chains displayed an N-sulphate content and distribution (determined by low pH nitrous acid treatment) similar to that seen in the majority of other mammalian heparan sulphates. Extended iduronate sequences were also identified (i.e., heparitinase-resistant sequences); however, apart from these regions, the degree of O-sulphation was relatively low. In addition, the presence of heparin-like sequences (GlcNSO3(+/- 6S)-IdoA(2S)), characterised by heparinase sensitivity, accounted for only 5% of the disaccharides and such sequences appeared to be located with an ordered distribution, mainly in relatively short sulphated domains within the intact molecule. Given the strategic location of the large matrix-associated HSPG within the BAEC system studied, it is conceivable that the HS structure may be important in a number of functions such as cell attachment processes and/or the binding of growth factors.

Utility of non-covalent complexes in the matrix-assisted laser desorption ionization mass spectrometry of heparin-derived oligosaccharides

Molecular weights of heparin-derived oligosaccharides ranging from disaccharides to hexadecasaccharides have been determined by matrix-assisted laser desorption ionization time-of-flight mass spectrometry. While these compounds ionize poorly or not at all when used as such, a strong signal can be obtained of their ionic complexes formed with a basic peptide or protein. The molecular weight of the sulfated oligosaccharide is determined by subtracting the mass of the basic component from that of the complex. Optimization of the experimental conditions resulted in sub-picomole sensitivity, in the elimination of sulfate loss and of the interference from attachment of inorganic cations. Synthetic peptides (Arg-Gly)10 and (Arg-Gly)15 were specifically designed as complexing agents for synthetic and natural heparin fragments up to decasaccharides. Accurate molecular weight determination on chemically homogeneous oligosaccharides (+/- 0.05%) unambiguously identified the number of saccharide units, and the number of O,N-sulfate and N-acetyl groups. For oligosaccharides larger than decasaccharides, a small basic protein, angiogenin (M(r) = 14,120), was used to form the complex (an inhomogeneous hexadecasaccharide fraction was the largest available for this study). For inhomogeneous samples larger than decasaccharides, the mass accuracy is lower (+/- 0.2-0.3%) but still suffices to determine the number of saccharide units present and to estimate the number of sulfate groups, except it is no longer possible to differentiate one sulfate from two N-acetyl groups (delta = 4 Da). However, taking into account known regularities of sulfation and acetylation, the specificity of heparin lyases and chemical degradation steps, the method promises to contribute significantly to the determination of the primary structure of heparin and other sulfated glycosaminoglycans.

Structural analysis of glycosaminoglycans derived from axonally transported proteoglycans in regenerating goldfish optic nerve

Structural characteristics of glycosaminoglycans (GAGs) derived from axonally transported proteoglycans (PGs) were compared in 21 days regenerating and intact goldfish optic tracts. Twenty one days following unilateral optic nerve crushes, fish received intraocular injections of 35SO4. Eight hours post injection, tracts were removed and the 35SO4-labeled GAGs, chondroitin sulfate (CS) and heparan sulfate (HS), isolated. The HS from regenerating optic tracts had a DEAE elution profile indicative of decreased charge density, while heparitinase treatment of HS followed by Sephadex G50 analysis of the resulting fragments showed a change in the elution pattern, suggesting reduced overall sulfation. HPLC analysis of HS disaccharides revealed a difference in the sulfation pattern of regenerating tract HS, characterized by the reduced presence of tri-sulfated disaccharides. Other structural features, such as the sizes of CS and HS, and the sulfation of CS, showed no changes during regeneration. These results indicate that changes in the structure of axonally transported HS accompany regeneration of goldfish optic axons.

Isolation and characterization of hexasaccharides derived from heparin. Analysis by HPLC and elucidation of structure by 1H NMR

Four hexasaccharides representing major structural sequences of heparin were isolated and characterized after degradation of heparin by heparinase. The structures were determined from two-dimensional 1H NMR spectroscopy including TOCSY (total correlated spectroscopy), COSY (correlated spectroscopy), and ROESY (rotating frame nuclear Overhauser enhancement spectroscopy) methods, providing new data on hexasaccharides. One of the hexasaccharides, the last eluting component from anion exchange chromatography, was derived from the tri-sulfated repeating disaccharide, alpha-L-idopyranosyluronic acid 2-sulfate-(1-->4)-2-amino-2-deoxy-D-glucopyranose 6,N-disulfate, and having the structure delta UAp2S-(1)-->4)-alpha-D-GlcNp2S6S-(1-->4)-alpha-L- IdoAp2S-(1-->4)-alpha-D-GlcNp2S6S-(1-->4)-alpha-L- IdoAp2S-(1-->4)-alpha-D-GlcNp2S6S. The second hexasaccharide contained a nonsulfated D-glucuronic acid unit instead of the L-iduronic acid adjacent to the reducing end, and having the structure delta UAp2S-(1-->4)-alpha-D-GlcNp2S6S-(1-->4)-alpha-L- IdoAp2S-(1-->4)-alpha-D-GlcNp2S6S-(1-->4)-beta-D- GlcAp-(1-->4)-alpha-D-GlcNp2S6S. The last two hexasaccharides were obtained in lower yield and they have not been isolated and characterized before. The structure of the third saccharide corresponded to a trimer of the repeating disaccharide except for the lack of a 6-O-sulfate group at the reducing end glucosamine residue; deltaUAp2S-(1-->4)-alpha-D-Glcnp2S6S-(1-->4)-alpha-L- IdoAp2S-(1-->4)-alpha-D-GlcNp2S6S-(1-->4)-alpha-L-IdoAp2S -(1-->4)-alpha- D-GlcNp2S. The fourth and last hexasaccharide were less sulfated and the following structure was established delta UAp2S-(1-->4)-alpha-D-GlcNp2S6S-(1-->4)-alpha-L- Idop2S-(1-->4)-alpha-D-GlcNp2S6S-(1-->4)-alpha-L- IdoAp-(1-->4)-alpha-D-GlcNpAc6S. Analysis of the ROESY spectra revealed conformational difference of the glucosidic linkage alpha-L-IdoAp-(1-->4)-alpha-D-GlcNp between the hexasaccharides and longer heparin chains.

Enzymatic degradation of glycosaminoglycans

Glycosaminoglycans (GAGs) play an intricate role in the extracellular matrix (ECM), not only as soluble components and polyelectrolytes, but also by specific interactions with growth factors and other transient components of the ECM. Modifications of GAG chains, such as isomerization, sulfation, and acetylation, generate the chemical specificity of GAGs. GAGs can be depolymerized enzymatically either by eliminative cleavage with lyases (EC 4.2.2.-) or by hydrolytic cleavage with hydrolases (EC 3.2.1.-). Often, these enzymes are specific for residues in the polysaccharide chain with certain modifications. As such, the enzymes can serve as tools for studying the physiological effect of residue modifications and as models at the molecular level of protein-GAG recognition. This review examines the structure of the substrates, the properties of enzymatic degradation, and the enzyme substrate-interactions at a molecular level. The primary structure of several GAGs is organized macroscopically by segregation into alternating blocks of specific sulfation patterns and microscopically by formation of oligosaccharide sequences with specific binding functions. Among GAGs, considerable dermatan sulfate, heparin and heparan sulfate show conformational flexibility in solution. They elicit sequence-specific interactions with enzymes that degrade them, as well as with other proteins, however, the effect of conformational flexibility on protein-GAG interactions is not clear. Recent findings have established empirical rules of substrate specificity and elucidated molecular mechanisms of enzyme-substrate interactions for enzymes that degrade GAGs. Here we propose that local formation of polysaccharide secondary structure is determined by the immediate sequence environment within the GAG polymer, and that this secondary structure, in turn, governs the binding and catalytic interactions between proteins and GAGs.

The heparin-binding domain of heparin-binding EGF-like growth factor can target Pseudomonas exotoxin to kill cells exclusively through heparan sulfate proteoglycans

Heparin-binding EGF-like growth factor (HB-EGF) is a smooth muscle cell mitogen composed of both EGF receptor and heparin-binding domains. To better understand the function of its domains, intact HB-EGF or its heparin-binding (HB) domain (amino acids 1-45) were fused to a mutant Pseudomonas exotoxin with an inactivated cell-binding domain. The resulting chimeric toxins, HB-EGF-PE* and HB-PE*, were tested on tumor cells, proliferating smooth muscle cells and a mutant Chinese hamster ovary cell line deficient in heparan sulfate proteoglycans (HSPGs). Two targets were found for HB-EGF-PE*. Cells were killed mainly through EGF receptors, but the HB domain was responsible for killing via HSPGs. HB-PE* did not bind to the EGF receptor and thus was cytotoxic by interacting exclusively with HSPGs. We conclude that the HB domain of HB-EGF is able to mediate internalization through HSPGs, without requiring the EGF receptor.

Mediation of Trypanosoma cruzi invasion by heparan sulfate receptors on host cells and penetrin counter-receptors on the trypanosomes

Trypanosoma cruzi attaches and invades a large variety of mammalian cells by receptor-mediated interactions, one of them involving the binding of parasite trans-sialidase to host sialyl receptors. Three proteoglycan-deficient mutants of Chinese hamster ovary (CHO) cells were used to probe the role of host heparin and heparan sulfate glycosaminoglycans (GAG) in T. cruzi invasion. All three mutants supported adhesion and infection to a much lower extent than the parental CHO cells. One of the mutants, pgsD-677, did not express heparan sulfate while containing three- to four-fold excess chondroitin sulfate, yet the cell line was a poor substrate for T. cruzi adhesion. Proteoglycan-deficient cells obtained by inhibiting GAG synthesis in parental cells with p-nitrophenyl-beta-D-xyloside, were also poor hosts for T. cruzi invasion. Furthermore, digestion of parental cells with heparinase and heparitinase, two lyases that specifically depolymerize heparin and heparan sulfate, reduced the potential of the cells to support T. cruzi adhesion and growth. Lyases that digested chondroitin sulfate and other GAGs did not affect T. cruzi invasion. These results suggest that heparin/heparan sulfate epitopes are receptors for T. cruzi invasion. The corresponding counter-receptor on T. cruzi appears to be penetrin, a heparin-binding protein that promotes trypanosome penetration into cells. Purified penetrin caused agglutination of red blood cells, and the hemagglutination was exquisitely sensitive to heparin and heparan sulfate. However, sialic acid and sialyl compounds did not inhibit penetrin-induced hemagglutination. Recombinant penetrin competitively inhibited T. cruzi invasion of proteoglycan-containing parental cells, but not of proteoglycan-deficient mutants nor of heparitinase-treated cells. Furthermore, consistent with the sugar specificity of penetrin as a hemagglutinin, recombinant penetrin competed for trypanosome invasion of a CHO cell mutant (Lec2) that expresses heparan sulfate but not sialyl residues. Given that the release of sialic acid from the proteoglycan-deficient mutants further reduced T. cruzi invasion, as did the removal of heparan sulfate from the Lec2 mutant, and given that penetrin does not bind to sialic acid with high affinity, the results indicate that the penetrin-heparan sulfate pathway for T. cruzi invasion is distinct from the trans-sialidase-sialic acid route.

Low molecular weight dermatan sulfate as an antithrombotic agent. Structure-activity relationship studies

A structure-activity relationship of low molecular weight dermatan sulfate was undertaken to understand better this new non-heparin, glycosaminoglycan-based antithrombotic agent. A dermatan sulfate prepared from bovine intestinal mucosa [average molecular weight (MWavg) 25,000], and currently in clinical trials as an antithrombotic agent, was used in this study. Dermatan sulfate was partially depolymerized using hydrogen peroxide and copper(II) as catalyst to MWavg 5600 to obtain a low molecular weight dermatan sulfate. This low molecular weight dermatan sulfate was then fractionated by gel permeation chromatography to obtain four subfractions having MWavg 7800, 5500, 4200 and 1950. The dermatan sulfate, low molecular weight dermatan sulfate and its subfractions showed substantially different optical rotations. The 1H-NMR spectroscopic analysis of dermatan sulfate samples showed some differences including increased content of GalpNAc4S6S residues and improved resolution in ring resonances for low molecular weight dermatan sulfate fractions, primarily the result of reduced molecular weight and lowered heterogeneity. Saccharide compositional analysis relied on chondroitin ABC lyase treatment followed by capillary electrophoresis. Polyacrylamide gel-based oligosaccharide mapping was also performed by treating dermatan sulfate samples with chondroitin B, AC and ABC lysases. These analyses showed increased amounts of sulfation as the MWavg decreased. In vitro bioassay showed maximum anti-Xa activity in the 4.2 kDa fraction and maximum heparin cofactor II-mediated anti-IIa activity in the 5.5 kDa fraction. The in vivo antithrombotic activity of these fractions was measured using a modified Wessler stasis thrombosis model. The 4.2 kDa fraction showed greater antithrombotic activity than the other low molecular weight dermatan sulfate fractions, dermatan sulfate, and low molecular weight dermatan sulfate. This enhanced activity may result from several structural features of the 4.2 kDa fraction including: a high content of 4,6- and 2,4-disulfated disaccharide sequences; the requirement of specific chain length; a change in the ratio of iduronic to glucuronic acid; and the presence of chondroitin ABC lyase resistant material.

Molecular weight of low molecular weight heparins by 13C nuclear magnetic resonance spectroscopy

Heparin and low molecular weight heparins are polydisperse polysaccharides with a degree of polymerization ranging from 4 to approximately 40. The determination of their average molecular weights has traditionally relied on size exclusion chromatography involving the use of oligosaccharides of known size and molecular weight as standards. 13C NMR spectroscopy is applied for the first time to obtain the molecular weights of low molecular weight heparins. The signal intensities of the reducing end and internal anomeric carbons, having distinctive chemical shifts in the 13C NMR spectrum, are measured to determine the molecular weight. Compared to techniques utilizing broad band decoupling or selective decoupling of anomeric protons, distortionless enhancement polarization transfer pulse sequence gave better quantitation of signal intensities of anomeric carbons. Molecular weight was calculated from the calibrated ratio of signal intensities of the anomeric carbons of reducing end groups and internal residues, and the disaccharide compositional analysis. The calibrated signal intensity ratio is determined using the T1 relaxation rates of anomeric carbons of model oligosaccharides. The disaccharide composition of low molecular weight-heparins is obtained using capillary electrophoresis. Signal averaging over 40,000-90,000 transients, requiring a total of 12-18 h on a 360-MHz NMR spectrometer was adequate to measure molecular weights in the range of 3000-7000. The measured molecular weights of twelve low molecular weight heparins, analyzed by this 13C NMR spectroscopic technique, correlated well with the number average molecular weights obtained using high performance-gel permeation chromatography and gradient polyacrylamide gel electrophoresis. In addition to establishing the number average molecular weight, the 13C NMR spectra helped distinguish the structural properties of different commercially prepared low molecular weight heparins.

Disaccharide composition of heparan sulfates: brain, nervous tissue storage organelles, kidney, and lung

We have characterized the structural properties of heparan sulfates from brain and other tissues after depolymerization with a mixture of three heparin and heparan sulfate lyases from Flavobacterium heparinum. The resulting disaccharides were separated by HPLC and identified by comparison with authentic standards. In rat, rabbit, and bovine brain, 46-69% of the heparan sulfate disaccharides are N-acetylated and unsulfated, and 17-21% contain a single sulfate residue in the form of a sulfoamino group. In rabbit, bovine, and 1-day postnatal rat brain, disaccharides containing both a sulfated uronic acid and N-sulfate account for an additional 10-14%, together with smaller and approximately equal proportions (5-9%) of mono-, di-, and trisulfated disaccharides having sulfate at the 6-position of the glucosamine residue. Kidney and lung heparan sulfates are distinguished by high concentrations of disaccharides containing 6-sulfated N-acetylglucosamine residues. In chromaffin granules, the catecholamine- and peptide-storing organelles of adrenal medulla, where heparan sulfate accounts for a minor portion (5-10%) of the glycosaminoglycans, we have determined that bovine chromaffin granule membranes contain heparan sulfate in which almost all of the disaccharides are either unsulfated (71%) or monosulfated (18%). In sympathetic nerves, norepinephrine is stored in large dense cored vesicles that in biochemical composition and properties closely resemble adrenal chromaffin granules. However, in contrast to chromaffin granules, heparan sulfate accounts for approximately 75% of the total glycosaminoglycans in large dense-cored vesicles and more closely resembles heparin, insofar as it contains only 21% unsulfated disaccharides, 10% mono- and disulfated disaccharides, and 69% trisulfated disaccharides.(ABSTRACT TRUNCATED AT 250 WORDS)

Heparinase inhibits neovascularization

Neovascularization is associated with the regulation of tissue development, wound healing, and tumor metastasis. A number of studies have focused on the role of heparin-like molecules in neovascularization; however, little is known about the role of heparin-degrading enzymes in neovascularization. We report here that the heparin-degrading enzymes, heparinases I and III, but not heparinase II, inhibited both neovascularization in vivo and proliferation of capillary endothelial cells mediated by basic fibroblast growth factor in vitro. We suggest that the role of heparinases in inhibition of neovascularization is through depletion of heparan sulfate receptors that are critical for growth factor-mediated endothelial cell proliferation and hence neovascularization. The differences in the effects of the three heparinases on neovascularization could be due to different substrate specificities for the enzymes, influencing the availability of specific heparin fragments that modulate heparin-binding cytokines involved in angiogenesis.

Regulation by heparan sulfate in fibroblast growth factor signaling

The integral role of heparan sulfate proteoglycans in FGF signaling provides a potential means of regulating FGF activity. This regulation may be used by the cell, where the modification of heparan sulfate glycosaminoglycans during their synthesis in the Golgi can produce cell type- and potentially ligand-specific sulfation sequences. The description of these sequences will not only provide information on how this regulation is achieved, perhaps lending insight into other heparan sulfate-ligand interactions, but may also discern sulfated mimetics that can be used to disrupt or alter FGF signaling. These mimetics may be useful in the treatment disrupt or alter FGF signaling. These mimetics may be useful in the treatment of disease, or in understanding how FGF signaling via discrete pathways within the cell leads to specific cellular responses, such as activation of mitogenic signaling pathways, calcium fluxes, and cellular differentiation.

Accumulation of heparan sulfate in the culture of human melanoma cells with different metastatic ability

Glycosaminoglycans were metabolically labeled in subconfluent cultures of highly metastatic 7Gp122 and poorly metastatic IC8 variants and of the low metastatic parental M4Be human melanoma cell line. Proteoglycans were separated by DEAE Trisacryl chromatography from the culture medium, from the heparin extract of the cell layer and from the heparin-extracted cell residue lyzed with detergents. Glycosaminoglycans were released from the proteoglycans by reductive alkaline hydrolysis and heparan sulfate (HS) was detected by deaminative cleavage with nitrous acid. Expressed on cell protein basis, the labeled HS content in the medium and in the cell layer decreased with increasing metastatic ability. The extraction of HS with heparin from the 7Gp122 cells indicated that this variant was enriched in (polypeptide bound) HS non inserted into the plasma membrane, compared with the low metastatic IC8 and M4Be cells. The HS fraction in heparin extract and in the heparin-extracted cell residue exhibited molecular mass heterogeneity on gel permeation chromatography and it contained HS fragments. Scission with nitrous acid followed by molecular sieve chromatography of the degradation products indicated that the tetra- and disaccharide repeats separated by the N-sulfated glucosamine residue were present in about equal amounts and constituted 60% of the HS chains in the IC8 and M4Be cells. HS from 7Gp122, IC8 and M4Be cells did not bind antithrombin III with high affinity but it was capable of binding bFGF in in vitro assay.

Specificity studies on the heparin lyases from Flavobacterium heparinum

An understanding of the substrate specificity study of the heparin lyases (heparinase and heparitinases) is crucial for elucidation of the sequence of heparin and heparan sulfate. Four chemically modified heparins have been used to study the substrate specificity of the three heparin lyases. These modified heparins include the N- and O-desulfated and then specifically N-sulfated or N-acetylated derivatives of heparin and a modified heparin containing L-galactopyranosyluronic acid residues. These chemically modified heparins were degraded to various extents by the three heparin lyases. Differences in degree of sulfation have profound impact on the ease of cleavage of glycosidic linkages. Heparin lyase I (EC 4.2.2.7) is selective in cleaving highly sulfated polysaccharide chains containing linkages to 2-O-sulfated alpha-L-idopyranosyluronic acid residues. Heparin lyase III (EC 4.2.2.8) cleaves linkages that have reduced density of sulfation and that contain beta-D-glucopyranosyluronic acid residues. The ability of heparin lyase III to act on linkages to unsulfated alpha-L-idopyranosyluronic acid residues is observed for the first time. Heparin lyase II (no assigned EC number) demonstrates an unparalleled, wide specificity for substrates comprised of linkages containing both alpha-L-idopyranosyluronic and beta-D- glucopyranosyluronic acid residues. Heparin lyase II can also act on substrates containing linkages to unnatural alpha-L-galactopyranosyluronic acid residues. The high level of specificity of heparin lyase I makes it particularly suitable for use in the sequencing of heparin and heparan sulfate, while caution must be exercised in using heparin lyases II and III to sequence heparin and heparan sulfate because of their relatively broad specificity.

Cloning and expression of heparinase I gene from Flavobacterium heparinum

Heparinases, enzymes that cleave heparin and heparin sulfate, are implicated in physiological and pathological functions ranging from wound healing to tumor metastasis and are useful in deheparinization therapies. We report the cloning of the heparinase I (EC 4.2.2.7) gene from Flavobacterium heparinum using PCR. Two degenerate oligonucleotides, based on the amino acid sequences derived from tryptic peptides of purified heparinase, were used to generate a 600-bp probe by PCR amplification using Flavobacterium genomic DNA as the template. This probe was used to screen a Flavobacterium genomic DNA library in pUC18. The open reading frame of heparinase I is 1152 bp in length, encoding a precursor protein of 43.8 kDa. Eleven of the tryptic peptides (approximately 35% of the total amino acids) mapped onto the open reading frame. The amino acid sequence reveals a consensus heparin binding domain and a 21-residue leader peptide with a characteristic Ala-(Xaa)-Ala cleavage site. Recombinant heparinase was expressed in Escherichia coli as a soluble protein, using the T7 polymerase pET expression system. The recombinant heparinase cleavage of heparin was identical to that of native heparinase.

Molecular weight profiling of low molecular weight heparins utilizing a heparinase degraded oligosaccharide mixture as a calibrator

Heparinase degraded heparin fragments (HDHF) are enriched with a UV chromophore and can be utilized as calibrators to determine the molecular weight profile of low molecular weight heparins (LMWH's). In a standard protocol (1), the second to the last peak is assumed to be a hexasaccharide with a molecular weight of 1.8 kDa. All other peak molecular weights in the elution profile are assigned based upon this assumption. In this study, synthetic analogues of heparin with a defined molecular weight have been used to investigate the validity of this assumption. These compounds included a sulfated bis-lactobionic acid amide (2.4 kDa), a pentasaccharide (1.7 kDa), and lactose polysulfate (1.2 kDa). With reference to these internal standards, the second to the last peak of the HDHF mixture was found to elute after the pentasaccharide and close to the lactose polysulfate suggesting that it is a tetrasaccharide. For additional validation, calibration curves were constructed using individual calibrators as the reference method as well as the HDHF method. Several low molecular weight heparins were profiled for their molecular weight using these methods. In comparison to the reference method, the molecular weights obtained with the HDHF method were 25-40% higher. When the results were recalculated assuming the molecular weight of the second to the last peak as 1.2 kDa, the HDHF results compared well with the reference method. Additionally, it is seen that the HDHF method does not identify molecular components greater than 8.0 kDa.

Heparin-like glycosaminoglycans participate in binding of a human trophoblastic cell line (JAR) to a human uterine epithelial cell line (RL95)

In vitro studies in our laboratory have indicated that heparan sulfate proteoglycans (HSPGs) play an important role in murine embryo implantation. In order to investigate the potential function of HSPGs in human implantation, two human cell lines (RL95 and JAR) were used to model uterine epithelium and embryonal trophectoderm, respectively. A heterologous cell-cell adhesion assay was developed to determine if binding of JAR cells to RL95 cells was heparan sulfate-dependent. Labeled, single cell suspensions of JAR cells attached to confluent monolayers of RL95 cells in a dose- and time-dependent manner. Heparin-like glycosaminoglycans and JAR cell proteoglycans competitively inhibited JAR cell adhesion to RL95 cells by 50% or more. A panel of chemically modified heparins were used to demonstrate that O-sulfation and amino group substitution were critical for inhibition of cell-cell adhesion. Treatment with chlorate, an inhibitor of ATP-sulfurylase, resulted in a 56% reduction in cell-cell binding compared to untreated controls. Heparinase and chondroitinase ABC markedly inhibited JAR-RL95 binding, while chondroitinase AC had no significant effect. These observations indicated that HSPGs as well as dermatan sulfate-containing proteoglycans participated in cell-cell binding. Collectively, these results indicate that initial binding interactions between JAR and RL95 cells is mediated by cell surface glycosaminoglycans (GAGs) with heparin-like properties (i.e., heparan sulfate and dermatan sulfate). These observations are consistent with an important role for HS and heparin-like GAGs as well as their corresponding binding sites in early stages of human trophoblast-uterine epithelial cell binding.

Monoclonal antibodies prepared against heparin lyase I and their reactivity toward heparin lyase I, II and III

1. Six different monoclonal IgG mouse antibodies to heparin lyase I from Flavobacterium heparinum were prepared. 2. The monoclonal antibodies were used to detect heparin lyases I, II and III by dot-blotting immunoassay and by Western blotting. 3. Individual antibodies showed different reactivity toward the three heparin lyases. 4. The reactivity of two of the monoclonal antibodies was destroyed by exposing heparin lyases to sodium dodecyl sulfate. 5. The antibodies can be used to rapidly distinguish between the three heparin lyases.

Binding of interferon-gamma to heparan sulfate is restricted to the heparin-like domains and involves carboxylic--but not N-sulfated--groups

Interferon-gamma binds to the glycosaminoglycan part of basement membrane proteoglycan. To obtain a greater insight into this interaction, different glycosaminoglycans and their subfractions were used in various binding assays. High affinity binding occurs with heparin and heparan sulfate only, the latter being the predominant basement membrane glycosaminoglycan. Furthermore, using heparan sulfate and heparin treated with heparinases I and III, we have shown that the interferon-gamma binding sites are localized on the N-sulfated glucosamine rich domains of the molecule. Interestingly, interferon-gamma and fibroblast growth factor compete for the same binding domain on heparan sulfate, although they are unrelated proteins. This last point is discussed in the light of the conformational flexibility of the glycosaminoglycan molecules.

Analysis of glycosaminoglycan chains from different proteoglycan populations in human embryonic skin fibroblasts

1. The structure of chondroitin/dermatan and heparan-sulphate chains from various proteoglycan populations derived from cultured human skin fibroblasts have been examined. Confluent cell cultures were biosynthetically labelled with [3H]-glucosamine and 35SO4(2-), and proteoglycans were purified according to buoyant density, size and charge density [Schmidtchen, A., Carlstedt, I., Malmström, A. & Fransson, L.-A. (1990) Biochem. J. 265, 289-300]. Some proteoglycan fractions were further fractionated according to hydrophobicity on octyl-Sepharose in Triton X-100 gradients. The glycosaminoglycan chains, intact or degraded by chemical or enzymic methods were then analysed by gel chromatography on Sepharose CL-6B, Bio-Gel P-6, ion exchange HPLC and gel electrophoresis. 2. Three types of dermatan-sulphate chains were identified on the basis of disaccharide composition and chain length. They were derived from the large proteoglycan, two small proteoglycans and a cell-associated proteoglycan with core proteins of 90 kDa and 45 kDa. Intracellular, free dermatan-sulphate chains were very similar to those of the small proteoglycans. 3. Heparan-sulphate chains from different proteoglycans had, in spite of small but distinct differences in size, strikingly similar compositional features. They contained similar amounts of D-glucuronate, L-iduronate (with or without sulphate) and N-sulphate groups. They all displayed heparin-lyase-resistant domains with average molecular mass of 10-15 kDa. The heparan-sulphate chains from proteoglycans with 250-kDa and 350-kDa cores were the largest greater than 50 kDa), containing an average of four or five domains, in contrast to heparan-sulphate chains from the small heparan-sulphate proteoglycans which had average molecular mass of 45 kDa and consisted of three or four such domains. Free, cell-associated heparan-sulphate chains were heterogeneous in size (5-45 kDa). 4. These results suggest that the core protein may have important regulatory functions with regard to dermatan-sulphate synthesis. On the other hand, synthesis of heparan sulphate may be largely controlled by the cell that expresses a particular proteoglycan core protein.

Endogenous heparinase-sensitive anticoagulant activity in human plasma

In this paper we show that an anticoagulant activity, which we measure by thrombin time, appears in human plasma after its exhaustive proteolytic digestion. This activity is extremely heat stable, it is resistant to chondroitin ABC lyase (E.C.4.2.2.4) and heparan sulfate lyase (E.C.4.2.2.8), it is sensitive to heparin lyase (E.C.4.2.2.7) and to nitrous acid treatment: we suggest that it can be identified as authentic heparin. The amount present in 1 ml of plasma of healthy subjects corresponds to 0.1-0.2 I.U. of standard heparin (150 I.U./mg). Proteolytically digested human plasma was submitted to ion-exchange chromatography on DEAE-Sephacel and the anticoagulant activity in the fractions eluted at the different molarities of NaCl was measured by thrombin time. This analysis shows that the anticoagulant activity elutes at very low ionic strength. The possibility that interactions of the endogenous heparin with proteins or protein fragments are responsible for the difficulty in isolating heparin from human plasma is discussed.

Mechanism of C. trachomatis attachment to eukaryotic host cells

A novel trimolecular mechanism of microbial attachment to mammalian host cells was characterized for the obligate intracellular pathogen Chlamydia trachomatis. Using purified glycosaminoglycans (GAGs) and specific GAG lyases, we demonstrated that a heparan sulfate-like GAG present on the surface of chlamydia organisms is required for attachment to host cells. These observations were supported by inhibition of attachment following binding of heparan sulfate receptor analogs to chlamydiae and by demonstrating that chlamydiae synthesize a unique heparan sulfate-like GAG. Furthermore, exogenous heparan sulfate, as an adhesin analog, restored attachment and infectivity to organisms that had lost these attributes following treatment with heparan sulfate lyase. These data suggest that a GAG adhesin ligand mediates attachment by bridging mutual GAG receptors on the host cell surface and on the chlamydial outer membrane surface.

A role for proteoglycans in the guidance of a subset of pioneer axons in cultured embryos of the cockroach

Several molecules involved in the development of the nervous system have specific binding sites for the glycosaminoglycan (GAG) side chains of proteoglycans. Exogenous GAGs should bind to these sites, competitively inhibit interactions with proteoglycans, and perturb development. GAGs added to the culture medium perturb the in situ growth of pioneer axons in cultured cockroach embryos by producing axon defasciculation and growth in incorrect directions. The specificity of this phenomenon is evident from the following observations: Of all the GAGs tested only heparin and heparan sulfate produced perturbation; of the six axon tracts being pioneered during the culture period only two of them are perturbed by the GAGs; and similar perturbations are produced when embryos are cultured in the presence of heparinase II and heparitinase.

Patterns of sulphation in heparan sulphate: polymorphism based on a common structural theme

HS appears to be a well-organised molecule with a domain structure that is apparently unique amongst the GAG family (Gallagher, 1989). Further refinements in sequence analysis are needed to corroborate the simplified model proposed in Fig. 4. It is still not clear why evolution has favoured a structural motif of widely spaced sulphated domains. Presumably, some advantages must accrue to the organism from this design, and one idea, that we have discussed previously, is that the polysaccharide functions as a "template" for the organisation of structural proteins in the ECM and for the binding and presentation of growth factors within the matrix polymer network. The sulphated regions are likely to display considerable conformational versatility as a result of the presence of the iduronate residues, and this property may be very important for the protein-binding properties of the polysaccharides (Casu et al., 1988). Sulphation patterns within these regions could favour oligosaccharide conformations necessary for specific protein interactions. An important question in this context is why different cells express on their surfaces HS with subtle differences in sulphation pattern. Perhaps the polymorphic features of HS are involved in higher-order tissue- and organ-specific mechanisms controlling cellular recognition and morphogenesis. The consistency with which aberrant sulphation of HS is detected in malignant disease (Gallagher and Lyon, 1989) in which cellular recognition and differentiation are impaired, adds some substance to this view.