scholarly journals Hyperactivity of factor IX Padua (R338L) depends on factor VIIIa cofactor activity

JCI Insight ◽  
2019 ◽  
Vol 4 (14) ◽  
Author(s):  
Benjamin J. Samelson-Jones ◽  
Jonathan D. Finn ◽  
Lindsey A. George ◽  
Rodney M. Camire ◽  
Valder R. Arruda
Keyword(s):  
Factor Ix ◽  
Factor Viiia ◽  
Cofactor Activity

scholarly journals The role of the second growth-factor domain of human factor IXa in binding to platelets and in factor-X activation

1995 ◽  
Vol 310 (2) ◽  
pp. 427-431 ◽  
Author(s):  
S S Ahmad ◽  
R Rawala ◽  
W F Cheung ◽  
D W Stafford ◽  
P N Walsh
Keyword(s):  
Growth Factor ◽  
Human Factor ◽  
Factor Ix ◽  
Factor X ◽  
Binding Studies ◽  
Factor Ixa ◽  
Equilibrium Binding ◽  
Activated Platelets ◽  
Factor Viiia ◽  
Factor X Activation

To study the structural requirements for factor IXa binding to platelets, we have carried out equilibrium binding studies with human factor IXa after replacing the second epidermal growth factor (EGF) domain by the corresponding polypeptide region of factor X. The chimeric protein, factor IX(Xegf2), and the wild-type, factor IXwt, produced in embryonic kidney cells 293 were radiolabelled with 125I and activated with factor XIa. Direct binding studies with thrombin-activated platelets showed normal stoichiometry and affinity of binding of factor IXawt in the presence of factor VIIIa (2 units/ml) and factor X (1.5 microM). However, under similar experimental conditions, factor IXa(Xegf2) was bound to a smaller number of sites (396 sites/platelet) with decreased affinity, i.e. a dissociation constant (Kd) of 1.4 nM, compared with normal factor IXa, factor IXaN (558 sites/platelet; Kd 0.67 nM), or factor IXawt (590 sites/platelet; Kd 0.61 nM). The concentrations of factor IXaN and factor IXawt required for half-maximal rates of factor-X activation were 0.63 nM and 0.7 nM, indicating a close correspondence of the Kd, app. for binding of factor IXawt to the factor-X activating complex on activated platelets to the Kd obtained in equilibrium binding studies. In contrast, kinetic parameters for factor-X activation by factor IXa(Xegf2) showed a decreased affinity (Kd 1.5 nM), in agreement with results of binding studies. These studies with factor IX(Xegf2) suggest that the EGF-2 domain may be important for specific high-affinity factor IXa binding to platelets in the presence of factor VIIIa and factor X.

Releasing the brakes in coagulation Factor IXa by co-operative maturation of the substrate-binding site

2016 ◽  
Vol 473 (15) ◽  
pp. 2395-2411 ◽  
Author(s):  
Line Hyltoft Kristensen ◽  
Ole H. Olsen ◽  
Grant E. Blouse ◽  
Hans Brandstetter
Keyword(s):  
Coagulation Factor ◽  
Factor Ix ◽  
Fine Tuning ◽  
Structural Basis ◽  
Factor X ◽  
Multifaceted Approach ◽  
Factor Ixa ◽  
Activated Platelets ◽  
Factor Viiia ◽  
Multiple Regions

Coagulation Factor IX is positioned at the merging point of the intrinsic and extrinsic blood coagulation cascades. Factor IXa (activated Factor IX) serves as the trigger for amplification of coagulation through formation of the so-called Xase complex, which is a ternary complex of Factor IXa, its substrate Factor X and the cofactor Factor VIIIa on the surface of activated platelets. Within the Xase complex the substrate turnover by Factor IXa is enhanced 200000-fold; however, the mechanistic and structural basis for this dramatic enhancement remains only partly understood. A multifaceted approach using enzymatic, biophysical and crystallographic methods to evaluate a key set of activity-enhanced Factor IXa variants has demonstrated a delicately balanced bidirectional network. Essential molecular interactions across multiple regions of the Factor IXa molecule co-operate in the maturation of the active site. This maturation is specifically facilitated by long-range communication through the Ile212–Ile213 motif unique to Factor IXa and a flexibility of the 170-loop that is further dependent on the conformation in the Cys168–Cys182 disulfide bond. Ultimately, the network consists of compensatory brakes (Val16 and Ile213) and accelerators (Tyr99 and Phe174) that together allow for a subtle fine-tuning of enzymatic activity.

scholarly journals Regions 301–303 and 333–339 in the catalytic domain of blood coagulation Factor IX are Factor VIII-interactive sites involved in stimulation of enzyme activity

1999 ◽  
Vol 339 (2) ◽  
pp. 217-221 ◽  
Author(s):  
Joost A. KOLKMAN ◽  
Peter J. LENTING ◽  
Koen MERTENS
Keyword(s):  
Catalytic Domain ◽  
Coagulation Factor ◽  
Factor Ix ◽  
Factor X ◽  
Factor Ixa ◽  
Factor Viiia ◽  
Α Helix ◽  
Factor X Activation ◽  
Affinity Interaction ◽  
Stimulation Of

The contribution of the Factor IX catalytic domain to Factor VIIIa binding has been evaluated by functional analysis of Factor IX variants with substitutions in α-helix region 333–339 and region 301–303. These regions were found to play a prominent role in Factor VIIIa-dependent stimulation of Factor X activation, but do not contribute to the high-affinity interaction with Factor VIIIa light chain. We propose that complex assembly between Factor IXa and Factor VIIIa involves multiple interactive sites that are located on different domains of these proteins.

scholarly journals A candidate activation pathway for coagulation factor VII

2019 ◽  
Vol 476 (19) ◽  
pp. 2909-2926
Author(s):  
Tina M. Misenheimer ◽  
Kraig T. Kumfer ◽  
Barbara E. Bates ◽  
Emily R. Nettesheim ◽  
Bradford S. Schwartz
Keyword(s):  
Tissue Factor ◽  
Blood Coagulation ◽  
Factor Viia ◽  
Coagulation Factor ◽  
Factor Ix ◽  
Factor Vii ◽  
Factor X ◽  
Contact Activation ◽  
Coagulation Factor Vii ◽  
Factor Viiia

Abstract The mechanism of generation of factor VIIa, considered the initiating protease in the tissue factor-initiated extrinsic limb of blood coagulation, is obscure. Decreased levels of plasma VIIa in individuals with congenital factor IX deficiency suggest that generation of VIIa is dependent on an activation product of factor IX. Factor VIIa activates IX to IXa by a two-step removal of the activation peptide with cleavages occurring after R191 and R226. Factor IXaα, however, is IX cleaved only after R226, and not after R191. We tested the hypothesis that IXaα activates VII with mutant IX that could be cleaved only at R226 and thus generate only IXaα upon activation. Factor IXaα demonstrated 1.6% the coagulant activity of IXa in a contact activation-based assay of the intrinsic activation limb and was less efficient than IXa at activating factor X in the presence of factor VIIIa. However, IXaα and IXa had indistinguishable amidolytic activity, and, strikingly, both catalyzed the cleavage required to convert VII to VIIa with indistinguishable kinetic parameters that were augmented by phospholipids, but not by factor VIIIa or tissue factor. We propose that IXa and IXaα participate in a pathway of reciprocal activation of VII and IX that does not require a protein cofactor. Since both VIIa and activated IX are equally plausible as the initiating protease for the extrinsic limb of blood coagulation, it might be appropriate to illustrate this key step of hemostasis as currently being unknown.

scholarly journals Factor-mimetic and rebalancing therapies in hemophilia A and B: the end of factor concentrates?

Hematology ◽  
2021 ◽  
Vol 2021 (1) ◽  
pp. 219-225
Author(s):  
Patrick Ellsworth ◽  
Alice Ma
Keyword(s):  
Hemophilia A ◽  
Treatment Options ◽  
Standard Of Care ◽  
Factor Ix ◽  
Coagulation Cascade ◽  
Coagulation System ◽  
Current Standard ◽  
Factor Viiia ◽  
Hemorrhagic Tendency ◽  
The Many

Abstract Hemophilia A (HA) and B are inherited bleeding disorders caused by a deficiency of factor VIII or factor IX, respectively. The current standard of care is the administration of recombinant or purified factor. However, this treatment strategy still results in a high economic and personal burden to patients, which is further exacerbated by the development of inhibitors—alloantibodies to factor. The treatment landscape is changing, with nonfactor therapeutics playing an increasing role in what we consider to be the standard of care. Emicizumab, a bispecific antibody that mimics the function of factor VIIIa, is the first such nonfactor therapy to gain US Food and Drug Administration approval and is rapidly changing the paradigm for HA treatment. Other therapies on the horizon seek to target anticoagulant proteins in the coagulation cascade, thus “rebalancing” a hemorrhagic tendency by introducing a thrombotic tendency. This intricate hemostatic balancing act promises great things for patients in need of more treatment options, but are these other therapies going to replace factor therapy? In light of the many challenges facing these therapies, should they be viewed as a replacement of our current standard of care? This review discusses the background, rationale, and potential of nonfactor therapies as well as the anticipated pitfalls and limitations. This is done in the context of a review of our current understanding of the many aspects of the coagulation system.

scholarly journals Role of gamma-carboxyglutamic acid residues in the binding of factor IXa to platelets and in factor-X activation

Blood ◽  
1992 ◽  
Vol 79 (2) ◽  
pp. 398-405 ◽  
Author(s):  
R Rawala-Sheikh ◽  
SS Ahmad ◽  
DM Monroe ◽  
HR Roberts ◽  
PN Walsh
Keyword(s):  
Binding Sites ◽  
Factor Xa ◽  
Catalytic Efficiency ◽  
Factor Ix ◽  
Factor X ◽  
Apparent Dissociation Constant ◽  
Factor Ixa ◽  
Factor Viiia ◽  
Carboxyglutamic Acid ◽  
Factor X Activation

To study the requirements for factor-IXa binding to platelets and factor-X activation, we examined the consequences of chemical modification (factor IXMOD) or enzymatic removal (factor IXDES) of gamma-carboxyglutamic acid (Gla) residues. In the presence of factor VIIIa and factor X, there were 344 (+/- 52) binding sites/platelet for factor IXaMOD (apparent dissociation constant [kdapp] = 4.5 +/- 0.9 nmol/L) and 275 (+/- 35) sites/platelet for factor IXaDES (kdapp = 5.0 +/- 0.8 nmol/L) compared with 580 (+/-65) sites/platelet for normal factor IXa (factor IXaN) (kdapp = 0.61 +/- 0.1 nmol/L) and 300 (+/-62) sites/platelet for factor IX (kdapp = 2.9 +/- 0.29 nmol/L). The concentrations of factor IXaN, factor IXaMOD and factor IXaDES required for half-maximal rates of factor-Xa formation were 0.67 nmol/L, 3.5 nmol/L, and 6.7 nmol/L. Whereas maximal velocities (Vmax) of factor Xa formation by factor IXaMOD (approximately 0.8 nmol/L.min-1) and factor IXaN (approximately 10.5 nmol/L.min-1), turnover numbers (kcat expressed as moles of factor Xa formed per minute per mole of factor IXa bound), and values of catalytic efficiency (kcat/Km) were normal, indicating that the decreased rates of factor X activation observed with factor IXaMOD and factor IXaDES are solely a consequence of the abnormal binding of these proteins to thrombin-activated platelets in the presence of factor VIIIa and factor X. Thus, factor IXa binding to platelets is mediated in part, but not exclusively, by high-affinity Ca2+ binding sites in the Gla domain of factor IX.

Hemophilia B with Mutations at Glycine-48 of Factor IX Exhibited Delayed Activation by the Factor VIIa-tissue Factor Complex

2000 ◽  
Vol 84 (10) ◽  
pp. 626-634 ◽  
Author(s):  
Pai-Chih Wu ◽  
N. Hamaguchi ◽  
Yi-Shing Yu ◽  
Ming-Ching Shen ◽  
Shu-Wha Lin
Keyword(s):  
Calcium Ions ◽  
Factor Viia ◽  
Factor Ix ◽  
Hemophilia B ◽  
Factor X ◽  
Extrinsic Pathway ◽  
Catalytic Function ◽  
Factor Ixa ◽  
Factor Viiia ◽  
Human Factor Ix

SummaryGly-48 is in the conserved DGDQC sequence (residues 47-51 of human factor IX) of the first EGF (EGF-1)-like domain of factor IX. The importance of the Gly-48 is manifested by two hemophilia B patients; factor IXTainan and factor IX>Malmö27, with Gly-48 replaced by arginine (designated IXG48R) and valine (IXG48V), respectively. Both patients were CRM+ exhibiting mild hemophilic episodes with 25% (former) and 19% (latter) normal clotting activities. We characterize both factor IX variants to show the roles of Gly-48 and the conservation of the DGDQC sequence in factor IX. Purified plasma and recombinant factor IX variants exhibited approximately 26%–27% normal factor IX’s clotting activities with G48R or G48V mutation. Both variants depicted normal quenching of the intrinsic fluorescence by increasing concentrations of calcium ions and Tb3+, indicating that arginine and valine substitution for Gly-48 did not perturb the calcium site in the EGF-1 domain. Activation of both mutants by factor XIa appeared normal. The reduced clotting activity of factors IXG48R and IXG48V was attributed to the failure of both mutants to cleavage factor X; in the presence of only phospholipids and calcium ions, both mutants showed a 4∼7-fold elevation in K m, and by adding factor VIIIa to the system, although factor VIIIa potentiated the activation of factor X by the mutants factor IXaG48R and factor IXaG48V, a 2∼3-fold decrease in the catalytic function was observed with the mutant factor IXa’s, despite that they bound factor VIIIa on the phospholipid vesicles with only slightly reduced affinity when compared to wild-type factor IXa. The apparent K d for factor VIIIa binding was 0.83 nM for normal factor IXa, 1.74 nM for IXaG48R and 1.4 nM for IXaG48V. Strikingly, when interaction with the factor VIIa-TF complex was examined, both mutations were barely activated by the VIIa-TF complex and they also showed abnormal interaction with VIIa-TF in bovine thromboplastinbased PT assays. Taken together, our results suggest that mutations at Gly-48 altered the interaction of factor IX with its extrinsic pathway activator (VIIa-TF complex), its macromolecular substrate (factor X), and its cofactor (factor VIIIa).

Factor VIII-Factor IX Interactions: Molecular Sites Involved in Enzyme-Cofactor Complex Assembly

1999 ◽  
Vol 82 (08) ◽  
pp. 209-217 ◽  
Author(s):  
Patrick Celie ◽  
Joost Kolkman ◽  
Peter Lenting ◽  
Koen Mertens
Keyword(s):  
Factor Viii ◽  
Tissue Factor ◽  
Factor Viia ◽  
Three Dimensional ◽  
Factor Ix ◽  
Coagulation Cascade ◽  
Factor X ◽  
Factor Ixa ◽  
Factor Viiia ◽  
Factor X Activation

IntroductionThe activation of factor X is one of the steps in the coagulation cascade that is driven by the assembly of an activated serine protease with a membrane-bound cofactor. In the initial phase of coagulation, factor X is activated by the complex of activated factor VII (factor VIIa) and tissue factor. Subsequently, during the so-called propagation phase, factor X activation is catalyzed by the complex of activated factor IX (factor IXa) and activated factor VIII (factor VIIIa). In these complexes, factor VIIa and factor IXa are the factor X-activating enzymes, whereas tissue factor and factor VIIIa serve as non-enzymatic cofactors.1 Factors VIIa and IXa are highly homologous to other cofactor-dependent enzymes, such as activated factor X (factor Xa) and activated protein C, both in amino acid sequence, domain organization, and three-dimensional structure.2 Factor VIIa and IXa further share low or negligible activity towards their natural substrate factor X, unless in complex with their physiological cofactors.Although tissue factor and factor VIIIa serve similar roles as biological amplifiers, they are structurally different. Tissue factor is a small, transmembrane protein with an extracellular part comprising 219 amino acids. Factor VIII is much larger (2,332 amino acids), circulates in plasma, and requires proteolytic processing to exert its biological activity.3 When cofactors are assembled with their respective enzymes, a dramatic increase in enzymatic activity occurs. The underlying molecular mechanism, however, remains poorly understood.During the past few years, remarkable progress has been made in understanding the molecular details of enzyme-cofactor assembly within the coagulation cascade. Crystallography has provided high-resolution structures of tissue factor4 and the various cofactor-dependent coagulation enzymes.2 Moreover, the crystal structure of the factor VIIa—tissue factor complex has been resolved and has allowed the identification of the molecular sites involved in enzyme-cofactor interaction.5,6 Such details are still lacking, however, for the factor IXa—factor VIIIa complex. Current views are derived from three-dimensional models generated by homology modeling based on structurally-related proteins, such as nitrite reductase,7 ceruloplasmin,8 and galactose oxidase.9 Despite their inherent limitations, these models greatly facilitate the interpretation of previous functional studies on factor X activation. As such, the availability of molecular models may be considered an important step toward resolving the structure of the factor IXa—factor VIIIa complex and understanding the role of complex assembly and defects thereof. This chapter provides an overview of the current developments in this field.

Antibody to C1 Domain of Factor VIII Alters Interaction of Factor Xase Complex with Factor X.

Blood ◽  
2004 ◽  
Vol 104 (11) ◽  
pp. 1738-1738
Author(s):  
Gary E. Gilbert ◽  
Anu Bhimavarapu ◽  
Patricia Price ◽  
Marc Jacquemin
Keyword(s):  
Factor Viii ◽  
Factor Ix ◽  
Phospholipid Bilayer ◽  
Phospholipid Vesicles ◽  
Factor X ◽  
Apparent Affinity ◽  
Factor Ixa ◽  
Factor Viiia ◽  
C1 Domain ◽  
Gla Domain

Abstract The role of the C1 domain in function of factor VIII has not been clearly defined. In contrast, functional interactions have been identified for the three A domains and the C2 domain. We hypothesized that the C1 domain of factor VIII participates in both phospholipid binding and interaction with factor X and/or factor IXa. We evaluated inhibition of the factor Xase complex by LE2E9, a human inhibitor IgG4k mAb against C1. We utilized altered catalytic activity of the factor Xase complex in a defined assay to report the inhibition by LE2E9. Inhibition by LE2E9 was also evaluated when soluble phosphatidylserine replaced vesicles to support the factor Xase complex and when Gla-domainless factor X was the substrate. The deglycosylated form of LE2E9 was also evaluated to better define the mechanism through which LE2E9 exerts its effect. We found that LE2E9 bound to factor VIIIa with an apparent KD of 0.5 nM. The apparent affinity of factor VIIIa for sonicated phospholipid vesicles of phosphatidylserine:phosphatidylethanolamine:phosphatidylcholine 4:20:76 increased 3-fold in the presence of LE2E9. The apparent affinity of factor VIIIa for factor IXa was not significantly changed. The KM of the factor VIIIa-factor IXa complex was 20 ± 2 nM with LE2E9 vs. 40 ± 2 nM without. LE2E9 decreased the Vmax by 77 ± 6% indicating that the affinity of factor X for the factor Xase complex is increased while the rate of cleavage is decreased. When Gla-domainless factor X was used as the substrate for the factor Xase complex, LE2E9 did not inhibit activity indicating that inhibition occurs via an interaction that involves the factor X Gla domain. When the factor VIIIa-factor IX complex was supported by dihexanoyl phosphatidylserine rather than phospholipid vesicles the inhibition of Vmax was 47% indicating that the inhibitory effect does not require a phospholipid bilayer. Deglycosylated LE2E9 did not significantly change the KM but decreased the Vmax by 22% while both antibodies bound to factor VIII with the same affinity. These results suggest that LE2E9 inhibition relates largely to interaction of a carbohydrate moiety with factor VIII or factor X rather than binding the core C1 epitope. We conclude that LE2E9 decreases the KM, and the Vmax for the factor VIIIa-factor IXa complex, but only when the factor X Gla domain is present. These results suggest that in the factor Xase complex the C1 domain of factor VIII is intimately associated with the Gla domain of factor X and that interaction between these domains enhances the kcat for the factor VIIIa-factor IXa complex.

Depolymerized Holothurian Glycosaminoglycan Inhibits Plasma Thrombin Generation Via Interaction with the Factor IXa Heparin-Binding Exosite

Blood ◽  
2008 ◽  
Vol 112 (11) ◽  
pp. 3081-3081
Author(s):  
Buyue Yang ◽  
John P. Sheehan
Keyword(s):  
Factor Viii ◽  
Thrombin Generation ◽  
Fold Increase ◽  
Factor Ix ◽  
Heparin Binding ◽  
Thrombin Inhibition ◽  
Factor Ixa ◽  
Factor Viiia ◽  
Recombinant Factor Ix ◽  
Inhibition Of Thrombin

Abstract Depolymerized holothurian glycosaminoglycan (DHG) is a fucosylated chrondroitin sulfate that possesses antithrombin-independent antithrombotic properties in rodent thrombosis and dog hemodialysis models. DHG demonstrates significantly less bleeding in template or tail transection assays than therapeutically equivalent doses of heparins. Several potential in vitro mechanisms have been described for DHG, including acceleration of thrombin inhibition by heparin cofactor II (HCII), inhibition of factor VIII activation by thrombin, and inhibition of factor X activation by the intrinsic tenase complex (factor IXa-factor VIIIa). The relevant mechanism(s) for inhibition of tissue factor (TF) induced plasma thrombin generation by DHG were examined in HCII or mock-immunodepleted, and factor-deficient human plasmas, using selected recombinant factor IX(a) with mutations in the heparin-binding exosite. Plasma thrombin generation was detected by fluorogenic substrate cleavage in the presence of corn trypin inhibitor to block contact activation, and compared to a standard curve generated with α2-macroglobulin-thrombin complex. The dose-dependent decrease in velocity index, a parameter reflecting the rate of thrombin generation between lag phase and peak thrombin concentration, was used to compare DHG potency. When triggered by 0.2 pM TF, the EC50 for inhibition of thrombin generation by DHG was 0.16 ± 0.01 μM in both HCII-depleted and mock-depleted plasma, suggesting that DHG acts independently of HCII. When triggered by excess (4 pM) TF, plasma thrombin generation was independent of factors VIII and IX. Under these conditions, the EC50 for DHG inhibition of thrombin generation was increased 13-fold in mock-depleted plasma (2.02 ± 0.09 μM) and 28-fold in HCII-depleted plasma (4.31 ± 0.23 μM). These results suggest that components of the intrinsic tenase complex contribute to inhibition of plasma thrombin generation by DHG, and HCII contributes only at high tissue factor concentrations. In the presence of 0.2 pM TF, Western blotting under nonreducing conditions showed preservation of the prothrombin/meizothrombin band and delayed/reduced thrombin generation in the presence of 0.5 μM DHG, confirming that the inhibition involves reduced prothrombin activation rather than accelerated thrombin inhibition. When triggered by 0.2 pM TF in factor VIII-deficient plasma supplemented with 700 pM factor VIII or thrombin-activated factor VIIIa, the EC50 for inhibition by DHG was 0.41 ± 0.02 μM and 0.44 ± 0.05 μM, respectively. Similarly, the EC50 for DHG inhibition of thrombin generation in factor IX deficient plasma supplemented with 0.2 pM TF and 100% plasma-derived factor IX (90 nM), or 100 pM plasma-derived factor IXa alone, was 0.36 ± 0.01 μM and 0.34 ± 0.02 μM, respectively. Thus, activation of factors VIII and IX do not contribute significantly to the inhibition mechanism for DHG. The contribution of intrinsic tenase activity to DHG inhibition of plasma thrombin generation was assessed using recombinant factor IX(a) mutants with moderate (R170A) or marked (R233A) reductions in heparin affinity. Factor IX deficient plasma was supplemented with 0.2 pM TF and 100% recombinant factor IX, or 100 pM factor IXa, with increasing concentrations of DHG. Similar to plasma-derived factor IX(a), DHG demonstrated an EC50 of 0.38 ± 0.01 μM for inhibition of thrombin generation in the presence of factor IX(a) wild type (WT) zymogen or protease. In the presence of factor IX(a) R170A, the EC50 for DHG was 0.86 ± 0.06 μM and 1.02 ± 0.02 μM, respectively, a 2–3 fold increase relative to WT (P ≤ 0.01). For factor IX(a) R233A, the EC50 for DHG was 3.55 ± 0.47 μM for zymogen and 2.98 ± 0.64 μM for protease, an 8–9 fold increase relative to WT (P ≤ 0.01). Thus, mutations in the factor IXa heparin-binding exosite induced resistance to DHG inhibition of thrombin generation as follows: factor IX(a) R233A> R170A> WT. These findings are consistent with the common mechanism for intrinsic tenase inhibition demonstrated for heparin and DHG in purified systems, and establish the factor IXa heparin-binding exosite as the relevant molecular target for inhibition of plasma thrombin generation by DHG. This antithrombin-independent mechanism likely mediates the antithrombotic efficacy of DHG and related glycosaminoglycans, and may represent a novel therapeutic target with lower bleeding risk.

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