Electron microscopic study of the depolymerization process on unstabilized fibrin as affected by urea or monochloracetic acid

With the help of the electronmicroscopic method the non-stabilized fibrin depolymerization has been studied. It has been established that under the action of urea or monochloridacetic acid the gradual transition of fibril clot's structure in globular fibrinolike material takes place. These globules have morphological likeness with the fibrin-monomer molecules and have analogy of the morphological properties to the non-stabilized fibrin dissolution products by complex compounds of heparin. The elimination of urea or monochloridacetic acid from media gives possibility to reconstruct the fibrillar fibrin structure.     

Electron microscopic study of the products from dissolving unstabilized fibrin with complex heparin compounds

Effects of some heparin complex compounds (heparin-urea, adrenaline-heparin, fibrinogen-heparin complexes and secondary complex adrenalin-heparin-fibrinogen) on factor XIIIa unstabilized fibrin were studied using electron microscopy. Fibrillar network of unstabilized fibrin destroys with the formation of globular molecular particles similar to fibrinogen molecule or fibrin monomer ultrastructure. A mechanism of fibrinolytic action of all the complexes mentioned is probably the same, since under dissolving of unstabilized fibrin, structures are found, which are similar to those forming under dissolving of unstabilized fibrin with urea.     

Pharmacologic influence on secondary generalized fibrinolysis

Secondary generalized hyperfibrinolysis was induced by thrombin infusion or batroxobin injection in rats. To follow intravascular fibrinolysis quantitatively, an electroimmuno-assay was used for determination of the fibrin degradation products formed. Anticoagulants (heparin, hirudin), antifibrinolytics (EACA, PAMBA, AMCA), and synthetic (APPA) and naturally occurring (aprotinin) protease inhibitors were studied with regard to their influence on secondary fibrinolysis. The potency and duration of action of the antifibrinolytics tested correspond to their antifibrinolytic activity measured in vitro and to their pharmacokinetics. Formation of degradation products is initiated after the appearance of fibrin monomer or fibrin, respectively. Due to their antithrombin action heparin, hirudin, and APPA prevent the thrombin-induced fibrin formation and thus the induction of secondary fibrinolysis. In contrast, formation of fibrin monomers caused by batroxobin is not influenced by thrombin inhibitors so that in this case formation of degradation products is not prevented.     

Molecular basis for the susceptibility of fibrin-bound thrombin to inactivation by heparin cofactor ii in the presence of dermatan sulfate but not heparin

Although fibrin-bound thrombin is resistant to inactivation by heparin.antithrombin and heparin.heparin cofactor II complexes, indirect studies in plasma systems suggest that the dermatan sulfate.heparin cofactor II complex can inhibit fibrin-bound thrombin. Herein we demonstrate that fibrin monomer produces a 240-fold decrease in the heparin-catalyzed rate of thrombin inhibition by heparin cofactor II but reduces the dermatan sulfate-catalyzed rate only 3-fold. The protection of fibrin-bound thrombin from inhibition by heparin.heparin cofactor II reflects heparin-mediated bridging of thrombin to fibrin that results in the formation of a ternary heparin.thrombin.fibrin complex. This complex, formed as a result of three binary interactions (thrombin.fibrin, thrombin.heparin, and heparin.fibrin), limits accessibility of heparin-catalyzed inhibitors to thrombin and induces conformational changes at the active site of the enzyme. In contrast, dermatan sulfate binds to thrombin but does not bind to fibrin. Although a ternary dermatan sulfate. thrombin.fibrin complex forms, without dermatan sulfate-mediated bridging of thrombin to fibrin, only two binary interactions exist (thrombin.fibrin and thrombin. dermatan sulfate). Consequently, thrombin remains susceptible to inactivation by heparin cofactor II. This study explains why fibrin-bound thrombin is susceptible to inactivation by heparin cofactor II in the presence of dermatan sulfate but not heparin.     

Process of fibrin depolymerization and non-enzymatic fibrinolysis in rabbits receiving atherogenic rations with addition of antioxidants

The rabbits were kept on atherogenic ration for 2 months. This diet contained 0.3 mg/kg of cholesterol. In blood plasma of animals the authors observed a sharply reduced non-enzymatic fibrinolysis and depolymerization activity of non-stabilized fibrin. The addition of antioxidants and alpha-tocopherol (10 + 10 mg/kg) for 1 month to the atherogenic ration protected from the disturbance of the system hemostasis and normalized the depolymerization of non-stabilized fibrin.     

Interaction of fibrin(ogen) with heparin: further characterization and localization of the heparin-binding site

The beta chain 15-42 sequence of the fibrin(ogen) E region was implicated in heparin binding [Odrljin et al. (1996) Blood 88, 2050-2061]; whether heparin binds to other fibrin(ogen) regions remains to be clarified. To address this question, we studied the interaction of heparin with fibrinogen, fibrin, and their major fragments D(1), D-D, E(1), E(3), and alphaC, which together cover the entire structure of the molecule, by ligand blotting, surface plasmon resonance, and fluorescence. All three techniques revealed that at physiological ionic conditions only fibrin(ogen) and the E(1) fragment bind heparin, indicating that the only physiologically relevant heparin-binding site of fibrin(ogen) is located in its E region. To test whether the beta15-42 sequence is sufficient to form this site or some additional sequences are also involved, we tested the interaction of heparin with a number of beta15-42-containing fragments. The synthetic beta15-42 peptide bound heparin weakly (K(d) = 44.5 microM) while the recombinant beta15-57 and beta15-64 fragments exhibited almost 7-fold higher affinity (K(d) = 6.4 and 7.1 microM, respectively), indicating that the beta43-57 region is also important for heparin binding. At the same time the recombinant dimeric disulfide-linked (beta15-66)(2) fragment which mimics the dimeric arrangement of the beta chains in fibrin bound heparin with high affinity (K(d) = 66 nM), almost 100-fold higher than that for the monomeric fragments. This affinity was similar to those determined for fibrin and the E(1) fragment (K(d) = 72 and 70 nM, respectively) suggesting that (beta15-66)(2) mimics well the heparin-binding properties of the latter two. Altogether, these results indicate that the only heparin-binding site in fibrin(ogen) is formed by NH(2)-terminal portions of the beta chains, including residues beta15-57, and that dimerization is essential for high-affinity binding.     

Inhibition of fibrin-bound thrombin by a covalent antithrombin-heparin complex

Numerous studies have shown that fibrin-bound thrombin (IIa) is protected from inhibition by antithrombin (AT) + heparin (H) due to the formation of a ternary fibrin.IIa.H complex. We investigated factors affecting the inhibition of fibrin.IIa by a covalent complex of AT and H (ATH). The rate of IIa reaction with ATH was decreased 2-3-fold by fibrin monomer as compared to 57-fold for AT + heparin with high AT affinity. Furthermore, although the reaction of AT + H with a IIa mutant with decreased H binding (RA-IIa) was inhibited 2-3-fold in the presence of fibrin, reaction rates of ATH + RA-IIa were not reduced by fibrin. The relative difference in the effect of fibrin on the ATH reaction with RA-IIa compared to that for reactions of AT + H with RA-IIa is consistent with the fact that, in the absence of fibrin, the rate of the ATH reaction with RA-IIa relative to IIa was much less reduced (8-fold) compared to the corresponding reactions of AT + H (decreased 306 fold). Similarly, the addition of excess H in the absence of fibrin gave only a small decrease in rate of ATH + IIa reaction. However, in the presence of fibrin, the addition of 40-fold excess H decreased the rate of ATH inhibition of IIa by 1 order of magnitude. Experiments with ATH containing low molecular weight heparin chains with low AT affinity showed that IIa inhibition requires ATH with long chains that activate the AT moiety. Finally, electrophoresis of fibrin +/- ((125)I-)IIa +/- ((125)I-)ATH on native and denaturing gels showed that ATH forms ATH-IIa complexes that remain bound to fibrin through the ATH component. Thus, ATH is a potent inhibitor of fibrin-bound IIa, likely due to the formation of fibrin.ATH-IIa as opposed to fibrin.IIa.H ternary complexes.     

Analysis of soluble fibrin complexes by agarose gel chromatography and protamine sulfate gelation.

The molecular makeup of soluble fibrin complexes was studied by gel exclusion chromatography using radio-labelling to characterize individual components in protein mixtures. Products of limited plasmin degradation of fibrinogen and mixtures of fibrinogen and "early" fibrinogen digests formed high molecular weight soluble fibrin complexes upon incubation with thrombin. Purified, nonclottable fragment Y did not incorporate into soluble fibrin complexes, nor could we demonstrate incorporation of fragments D and E as previously described from our laboratory. Thus, under the conditions of these experiments, soluble fibrin complexes have two identifiable components, fibrin monomer and clottable fragment X monomer, although incorporation of native fibrinogen or fragment X unreacted by thrombin into soluble fibrin complexes cannot be excluded. Individual fractions of thrombin-treated early fibrinogen digests isolated by agarose gel chromatography were treated with protamine sulfate at 37 degrees C resulting in precipitation-gelation of greater than 90 per cent of high molecular weight soluble fibrin complexes; whereas, less than 10 per cent of lower molecular weight fibrinogen degradation products precipitated by protamine sulfate. These findings do not support the widely held concept that soluble fibrin complexes incorporate nonclottable degradation products of fibrinogen proteolysis, nor do they support the notion that the so-called paracoagulation reaction induced by protamine sulfate results from the splitting of complexes between fibrin monomer and nonclottable fibrinogen degradation products.     

The effect of heparin on the proteolytic and fibrinolytic activity on plasmin(ogen) and fibrin clot lysis

The effect of heparin on the proteolytic and fibrinolytic activities of plasmin and plasminogen was studied. Heparin at a concentration of 6.3.10(-6) M did not change the caseinolytic activity of plasmin and plasminogen stimulated by streptokinase but suppressed their fibrinolytic activity. At concentrations from 2.10(-8) to 0.5.10(-6) M heparin increased, whereas at 1.10(-6)-4.10(-6) M reduced the time of desAAfibrin clot half-lysis by plasmin. Within the concentration range of 2.10(-8) to 4.10(-6) M heparin did not change the time of the clot half-lysis by glu-plasminogen and slightly decreased the time of fibrin clot half-lysis by lys-plasminogen in the presence of the tissue activator. It was supposed that heparin inhibits the fibrinolytic effect of plasmin by way of formation of complexes with plasmin and reduction of plasmin specificity to the solid phase substrate, i. e., polymeric fibrin.     

Fibroblast growth factor (FGF)-2 mediates cell attachment through interactions with two FGF receptor-1 isoforms and extracellular matrix or cell-associated heparan sulfate proteoglycans

In the presence of FGF-2, cells in suspension expressing FGF receptor-1 will attach to monolayers of cells expressing heparan sulfates. This attachment provides physical evidence for the formation of a trimolecular complex between FGF-2, heparan sulfate, and FGF receptors. We have used this system to determine if receptor isoforms containing or lacking the first of three immunoglobulin-like domains are equally able to form complexes with FGF-2 and heparan sulfates. In the presence of FGF-2, cells expressing either isoform of the receptor were able to attach to monolayers of CHO cells expressing heparan sulfates. No attachment was observed in the absence of FGF-2 or if heparin was included in the incubation medium. Attachment of cells expressing the two receptor isoforms occurred at similar concentrations of FGF-2, and similar concentrations of heparin were required to disrupt the interactions. Thus, there appeared to be little difference between these receptor isoforms in their ability to form trimolecular complexes with FGF-2 and cell-associated heparan sulfates. We also found that, in the presence of FGF-2, cells expressing FGF receptor-1 are able to form complexes with both extracellular matrix and cell-surface heparan sulfates.     

Detection of soluble fibrin monomer complexes. Comparison of a haemagglutination assay with the ethanol gelation test

Hypercoagulability and disseminated intravascular coagulation (DIC) are characterized by the presence of circulating fibrin monomer complexes in plasma. In 342 patients with possible DIC fibrin monomers, fibrinogen, Reptilase Time, antithrombin III and other coagulation parameters were determined at frequent intervals. Testing of soluble fibrin monomer complexes was performed using a sensitive and reliable hemagglutation assay with red cells sensitized by fibrin monomers (FM-Test) and the ethanol gelation test (EGT). Method comparison regarding the influence of fibrinogen levels and fibrin degradation products shows that high fibrinogen levels lead to false-positive results with EGT. The same effect is observed for fibrin degradation products and EGT whereas no influence of fibrinogen level and fibrin degradation products on the FM-Test occurs. It is well-known that during DIC AT III level decreases caused by proteolytic activity. In this study it could be shown that fibrin monomer increases parallel to the decrease of AT III. The same effect does not occur due to fibrin degradation products.     

The ultrastructure of fibrinogen-420 and the fibrin-420 clot

Fibrinogen-420 is a minor subclass of human fibrinogen that is so named because of its higher molecular weight compared to fibrinogen-340, the predominant form of circulating fibrinogen. Each of the two Aalpha chains of fibrinogen-340 is replaced in fibrinogen-420 by an Aalpha isoform termed alphaE. Such chains contain a globular C-terminal extension, alphaEC, that is homologous with the C-terminal regions of Bbeta and gamma chains in the fibrin D domain. The alphaEC domain lacks a functional fibrin polymerization pocket like those found in the D domain, but it does contain a binding site for beta2 integrins. Electron microscopy of fibrinogen-340 molecules showed the major core fibrinogen domains, D-E-D, plus globular portions of the C-terminal alphaC domains. Fibrinogen-420 molecules had two additional globular domains that were attributable to alphaEC. Turbidity measurements of thrombin-cleaved fibrinogen-420 revealed a reduced rate of fibrin polymerization and a lower maximum turbidity. Thromboelastographic measurements also showed a reduced rate of fibrin-420 polymerization (amplitude development) compared with fibrin-340. Nevertheless, the final amplitude (MA) and the calculated elastic modulus (G) for fibrin-420 were greater than those for fibrin-340. These results suggested a greater degree of fibrin-420 branching and thinner matrix fibers, and such structures were found in SEM images. In addition, fibrin-420 fibers were irregular and often showed nodular structures protruding from the fiber surface. These nodularities represented alphaEC domains, and possibly alphaC domains as well. TEM images of negatively shadowed fibrin-420 networks showed irregular fiber borders, but the fibers possessed the same 22.5-nm periodicity that characterizes all fibrin fibers. From this result, we conclude that fibrin-420 fiber assembly occurs through the same D-E interactions that drive the assembly of all fibrin fibrils, and therefore that the staggered overlapping molecular packing arrangement is the same in both types of fibrin. The alphaEC domains are arrayed on fiber surfaces, and in this location, they would very likely slow lateral fibril association, causing thinner, more branched fibers to form. However, their location on the fiber surface would facilitate cellular interactions through the integrin receptor binding site.     

Kinetic studies on the effect of heparin and fibrin on plasminogen activators.

1. Possible interactions between fibrin(ogen) and heparin in the control of plasminogen activation were studied in model systems using the thrombolytic agents tissue-type plasminogen activator (t-PA), urokinase and streptokinase.plasminogen activator complex and the substrates Glu- and Lys-plasminogen. 2. Both t-PA and urokinase activities were promoted by heparin and by pentosan polysulphate, but not by chondroitin sulphate or hyaluronic acid. The effect was on Km. 3. In the presence of soluble fibrin (and its mimic, CNBr-digested fibrinogen) the effect of heparin on t-PA was attenuated, although not abolished. In studies using a monoclonal antibody and 6-aminohexanoic acid, it was found that heparin and fibrin did not seem to share a binding site on t-PA. 4. The activity of t-PA B-chain was unaffected by heparin, so the binding site is located on the A-chain of t-PA (and urokinase). 5. Fibrin potentiated the activity of heparin on urokinase. The activity of streptokinase.plasminogen was unaffected by heparin whether or not fibrin was present. 6. If these influences of heparin and fibrin also occur in vivo, then, in the presence of heparin, the relative fibrin enhancement of t-PA will be diminished and the likelihood of systemic activation by t-PA is increased.     

Heparin promotes the binding of thrombin to fibrin polymer. Quantitative characterization of a thrombin-fibrin polymer-heparin ternary complex

The binding of human alpha-thrombin (IIa) to fibrin polymer (FnIIp) was studied in the presence and absence of a high affinity 20,300 Mr heparin (H) at pH 7.4, I 0.15, and 23 degrees C. In the absence of heparin, thrombin interacts with a high affinity class of binding sites on fibrin polymer with a dissociation constant of 301 +/- 36 nM in a manner which is independent of the enzyme active site. Studies of thrombin binding as a function of heparin and fibrin polymer concentrations imply that a ternary thrombin-fibrin polymer-heparin complex (IIa.FnIIp.H) is formed. Assembly of the ternary complex occurs randomly through the interactions of all three possible intermediate binary complexes; IIa.H, IIa.FnIIp, and FnIIp.H. Using an independently determined value of 280 +/- 35 nM for the FnIIp.H dissociation constant, global fits of the binding data yield a dissociation constant of 15 +/- 6 nM for the IIa.H interaction and 47 +/- 9 nM for the IIa.H intermediate binary complex interaction with FnIIp. These studies indicate that heparin enhances the binding of thrombin to fibrin polymer 6.4-fold with an overall dissociation constant for ternary complex formation of 705 nM2. The effect of heparin molecular weight on ternary complex formation has also been investigated. Heparins of molecular weights 11,200-20,300 behave similarly with respect to their influence on ternary complex formation, whereas heparins of lower molecular weight are less effective in promoting thrombin binding to fibrin polymer. This effect of heparin is also independent of whether it has high or low affinity for antithrombin III. The demonstration of the formation of a ternary IIa.FnIIp.H complex complements kinetic evidence indicating the formation of an analogous ternary complex with fibrin II monomer (Hogg, P. J., and Jackson, C. M. (1989) Proc. Natl. Acad. Sci. U. S. A. 86, 3619-3623). The possible implications of these findings for the in vivo distribution and actions of thrombin and the clinical efficacy of heparin are also discussed.     

Exosites 1 and 2 are essential for protection of fibrin-bound thrombin from heparin-catalyzed inhibition by antithrombin and heparin cofactor II

Assembly of ternary thrombin-heparin-fibrin complexes, formed when fibrin binds to exosite 1 on thrombin and fibrin-bound heparin binds to exosite 2, produces a 58- and 247-fold reduction in the heparin-catalyzed rate of thrombin inhibition by antithrombin and heparin cofactor II, respectively. The greater reduction for heparin cofactor II reflects its requirement for access to exosite 1 during the inhibitory process. Protection from inhibition by antithrombin and heparin cofactor II requires ligation of both exosites 1 and 2 because minimal protection is seen when exosite 1 variants (gamma-thrombin and thrombin Quick 1) or an exosite 2 variant (Arg93 --> Ala, Arg97 --> Ala, and Arg101 --> Ala thrombin) is substituted for thrombin. Likewise, the rate of thrombin inhibition by the heparin-independent inhibitor, alpha1-antitrypsin Met358 --> Arg, is decreased less than 2-fold in the presence of soluble fibrin and heparin. In contrast, thrombin is protected from inhibition by a covalent antithrombin-heparin complex, suggesting that access of heparin to exosite 2 of thrombin is hampered when ternary complex formation occurs. These results reveal the importance of exosites 1 and 2 of thrombin in assembly of the ternary complex and the subsequent protection of thrombin from inhibition by heparin-catalyzed inhibitors.     

Purification of a form of protease nexin 1 that binds heparin with a low affinity

A form of protease nexin 1 (PN-1) that binds heparin with a low affinity (L-PN-1) was purified and studies since altered interactions with glycosaminoglycans could affect its inhibition of certain serine proteases. Purification of L-PN-1 and PN-1 was achieved by fractionating serum-free conditioned culture medium from human fibroblasts over dextran sulfate-Sepharose followed by immunoaffinity fractionation over a PN-1 monoclonal antibody-Sepharose column. The first step separated L-PN-1 from PN-1, and the second step resulted in apparently homogeneous L-PN-1 and PN-1. Comparisons of the two proteins showed that they could not be distinguished by the following properties: (a) molecular weight; (b) proteases complexed; (c) molecular weights of protease-L-PN-1 and protease-PN-1 complexes; (d) CNBr peptide maps; and (e) immunological cross-reactivity. Studies on activities that depend on the heparin binding domain revealed that heparin equally accelerated the rate of formation of 125I-thrombin-L-PN-1 and 125I-thrombin-PN-1 complexes even when the ratio of heparin to L-PN-1 or PN-1 was varied from 0.01 to 100. A functional difference, however, between L-PN-1 and PN-1 was observed in studies on the ability of the fibroblast surface to accelerate their reactions. Fixed fibroblasts accelerated the formation of 125I-thrombin-L-PN-1 complexes 2-fold, whereas they accelerated the formation of 125I-thrombin-PN-1 complexes 5-fold. The availability of purified L-PN-1 will permit studies on its functional relationship to PN-1.     

Heparin and heparan sulfate increase the radius of diffusion and action of basic fibroblast growth factor

The radius of diffusion of basic FGF (bFGF) in the presence and in the absence of the glycosaminoglycans heparin and heparan sulfate was measured. Iodinated 125I-bFGF diffuses further in agarose, fibrin, and on a monolayer of bovine aortic endothelial (BAE) cells in the presence of heparin than in its absence. Heparan sulfates affected the diffusion of 125I-bFGF in a manner similar to, though less pronounced than, heparin. When applied at the center of a monolayer of BAE cells, bFGF plus heparin stimulated morphological changes at a 10-fold greater radius than bFGF alone. These results suggest that bFGF-heparin and/or heparan sulfate complexes may be more effective than bFGF alone in stimulating cells located away from the bFGF source because the bFGF-glycosaminoglycan complex partitions into the soluble phase rather than binding to insoluble glycosaminoglycans in the extracellular matrix. Thus, the complex of bFGF and glycosaminoglycan may represent one of the active forms of bFGF in vivo.     

Basement-membrane heparan sulfate proteoglycan binds to laminin by its heparan sulfate chains and to nidogen by sites in the protein core.

A large, low-density form of heparan sulfate proteoglycan was isolated from the Engelbreth-Holm-Swarm (EHS) tumor and demonstrated to bind in immobilized-ligand assays to laminin fragment E3, collagen type IV, fibronectin and nidogen. The first three ligands mainly recognize the heparan sulfate chains, as shown by inhibition with heparin and heparan sulfate and by the failure to bind to the proteoglycan protein core. Nidogen, obtained from the EHS tumor or in recombinant form, binds exclusively to the protein core in a heparin-insensitive manner. Studies with other laminin fragments indicate that the fragment E3 possesses a unique binding site of laminin for the proteoglycan. A major binding site of nidogen was localized to its central globular domain G2 by using overlapping fragments. This allows for the formation of ternary complexes between laminin, nidogen and proteoglycan, suggesting a key role for nidogen in basement-membrane assembly. Evidence is provided for a second proteoglycan-binding site in the C-terminal globule G3 of nidogen, but this interaction prevents the formation of such ternary complexes. Therefore, the G3-mediated nidogen binding to laminin and proteoglycan are mutually exclusive.     

Mast cell restricted mouse and human tryptase·heparin complexes hinder thrombin-induced coagulation of plasma and the generation of fibrin by proteolytically destroying fibrinogen

The mouse and human TPSB2 and TPSAB1 genes encode tetramer-forming tryptases stored in the secretory granules of mast cells (MCs) ionically bound to heparin-containing serglycin proteoglycans. In mice these genes encode mouse MC protease-6 (mMCP-6) and mMCP-7. The corresponding human genes encode a family of serine proteases that collectively are called hTryptase-β. We previously showed that the α chain of fibrinogen is a preferred substrate of mMCP-7. We now show that this plasma protein also is highly susceptible to degradation by hTryptase-β· and mMCP-6·heparin complexes and that Lys(575) is a preferred cleavage site in the protein α chain. Because cutaneous mouse MCs store substantial amounts of mMCP-6·heparin complexes in their secretory granules, the passive cutaneous anaphylaxis reaction was induced in the skin of mMCP-6(+)/mMCP-7(-) and mMCP-6(-)/mMCP-7(-) C57BL/6 mice. In support of the in vitro data, fibrin deposits were markedly increased in the skin of the double-deficient mice 6 h after IgE-sensitized animals were given the relevant antigen. Fibrinogen is a major constituent of the edema fluid that accumulates in tissues when MCs degranulate. Our discovery that mouse and human tetramer-forming tryptases destroy fibrinogen before this circulating protein can be converted to fibrin changes the paradigm of how MCs hinder fibrin deposition and blood coagulation internally. Because of the adverse consequences of fibrin deposits in tissues, our data explain why mice and humans lack a circulating protease inhibitor that rapidly inactivates MC tryptases and why mammals have two genes that encode tetramer-forming serine proteases that preferentially degrade fibrinogen.     

Size-exclusion chromatography of heparin oligosaccharides at high and low pressure

Recent findings on specific and non-specific interactions of glycosaminoglycans (GAGs) accentuate their pivotal role in biology and the call for improved sequencing tools. The present study evaluates size-exclusion chromatography (SEC) of heparin oligosaccharides at high and low pressure, requiring amounts as low as 0.2 microgram, using conventional UV detection after depolymerization with heparin lyases. Because of their high charge at physiological pH, SEC elution volumes of heparin oligosaccharides depend on both molecular size and charge repulsion from the matrix. As a consequence, SEC elution volumes of GAGs are smaller than those of globular proteins of similar molecular weight, and this might be exploited. Accordingly, larger heparin oligosaccharides are best separated according to their size at high ionic strength of the mobile phase (>30 mM); in contrast, disaccharides are best separated according to their charge at low ionic strength, compatible with on-line coupling to mass spectrometry. Optimized SEC affords separation of characteristic heparin trisaccharides that contain uronic acid at the reducing end and suggest cellular storage of heparin as a free glycan.