Kinetics of activation and autoactivation of human factor XII

The kinetics of the enzymic reactions that participate in the contact activation system of human plasma were examined. These reactions are potentiated by dextran sulfate, a negatively charged solute that mimics many of the effects of glass or kaolin on this system. The reactions of reciprocal activation, consisting of activation of factor XII by kallikrein and of prekallikrein by activated factor XII, follow Michaelis-Menten kinetics; values of kcat and Km for each of these reactions were determined in the presence of dextran sulfate and in its absence. In the presence of dextran sulfate, the catalytic efficiency for factor XII activation was increased 11 000-fold, and that for prekallikrein was increased 70-fold. Autoactivation of factor XII in the presence of dextran sulfate also follows Michaelis-Menten kinetics with kcat = 0.033 s-1 and Km = 7.5 microM. This finding supports the concept that autoactivation is an enzymic process, initiated by traces of activated factor XII which are invariably present in factor XII preparations. At prekallikrein and factor XII levels equal to those in plasma, reciprocal activation is approximately 2000-fold more rapid than autoactivation. Thus, reciprocal activation is the predominant mode of factor XII activation in normal plasma.     

Activation of human blood coagulation factor XI independent of factor XII. Factor XI is activated by thrombin and factor XIa in the presence of negatively charged surfaces

Human blood coagulation factor XI was activated by either autoactivation or thrombin. These reactions occurred only in the presence of negatively charged materials, such as dextran sulfate (approximately Mr 500,000), sulfatide, and heparin. During the activation, factor XI was cleaved at a single Arg-Ile bond by thrombin or factor XIa to produce an amino-terminal 50-kDa heavy chain and a carboxyl-terminal 35-kDa light chain. This activation pattern is identical to that produced by factor XIIa. The addition of a small amount of thrombin and sulfatide to factor XII-deficient plasma produced shorter clotting times than when these agents were added to factor XI/factor XII combined-deficient plasma. These results suggest that the activation of factor XI by thrombin and possibly the autoactivation of factor XI proceed in plasma to lead fibrin clot formation. These reactions may have a role on an appropriate negatively charged surface in normal hemostasis.     

Possible basis for the apparent surface selectivity of the contact activation of human blood coagulation factor XII

The activation of factor XII by the proteases factor XIIa and kallikrein is known to be greatly enhanced by certain negatively charged surfaces. Studies that compared factor XII surface binding to factor XII activation found that binding alone was insufficient to account for surface enhancement of the activation rate. The temperature dependence of the reaction showed unusual behavior that may be related to the conformational change of factor XII following binding; the rate of factor XII activation had a relatively low temperature optimum (0-47 degrees C) that was sensitive to choice of surface and salt concentration. In temperature studies, below 47 degrees C, the decrease in the activation rate was not related to the thermal denaturation of enzyme or substrate, nor to the choice of activator enzyme (factor XIIa or kallikrein), nor to the species of factor XII (human or bovine) but to a behavior, designated a thermal transition, associated with the surface or the protein-surface interaction. The previously reported surface selectivity of contact activation is possible due to the temperature characteristics and other properties of the thermal transition; a surface that has a low-temperature thermal transition and that is highly sensitive to salt will be a "poor" contact surface under the usual choice of reaction conditions (approximately 150 mM ionic strength and 37 degrees C). However, solution conditions were identified that allowed the following negatively charged surfaces to function, in nearly equal potency, in the activation of factor XII: phosphatidylserine, phosphatidylglycerol, phosphatidic acid, phosphatidylinositol 4-phosphate, heparin, and 5-kDa dextran sulfate, as well as the previously characterized sulfatide and 500-kDa dextran sulfate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acceleration of surface-dependent autocatalytic activation of blood coagulation factor XII by divalent metal ions

The effect of divalent metal ions on the rate of dextran sulfate dependent autocatalytic activation of human blood coagulation factor XII was studied at pH 7.4 and 25 degrees C. Zn2+ and Cu2+, but not Co2+, increased the rate of factor XII activation induced by dextran sulfate with optimum effects at approximately 5 and 1 microM, respectively, while Ca2+ acceleration required much higher concentrations (millimolar). Further investigation of the effect of Zn2+ on factor XII activation demonstrated a complete dependence on the presence of dextran sulfate, lack of inhibition by soybean trypsin inhibitor, the appearance of alpha-XIIa as the primary reaction product, and reaction kinetics characteristic of an autocatalytic process. These results were consistent with Zn2+ affecting only the rate of surface-mediated factor XII autoactivation. The initial turnover velocity of dextran sulfate induced factor XII autoactivation increased linearly with factor XII concentration in the absence of Zn2+ up to 0.9 microM factor XII but showed saturation behavior over this same concentration range in the presence of 5 microM Zn2+, indicating that Zn2+ increased the reaction rate primarily by lowering the apparent Km. Comparison of the kinetics of autoactivation at mu = 0.15 and 0.24 revealed that the enhancement in the apparent kcat/Km brought about by Zn2+ increased from 19-fold to 520-fold, respectively, due to a differential dependence of the Zn2+-stimulated and unstimulated reactions on ionic strength.(ABSTRACT TRUNCATED AT 250 WORDS)     

The autoactivation of factor XII (Hageman factor) induced by low-Mr heparin and dextran sulphate. The effect of the Mr of the activating polyanion.

Human Factor XII is known to undergo autoactivation in the presence of dextran sulphate of Mr 500,000. We have now studied the dependence of this reaction on the Mr of the dextran sulphate by using fractions resolved by gel filtration. We have found that autoactivation can be induced by dextran sulphate fractions with Mr as low as 3000, and there is a marked dependence of the rate constant of autoactivation on the Mr value. Fractions with Mr below 8000 gave very low rates of autoactivation; there was a sharp increase in the rate obtained when the Mr of the dextran sulphate was greater than 10,000. Various preparations of heparin were also able to support the autoactivation of Factor XII and gave a very similar relationship between molecular size and reaction rate. The data provide support for the hypothesis that the mechanism by which the 'surface' acts in contact activation involves the presence, on the same particle, of multiple binding sites for the proteins.     

Activation of the contact system of coagulation by a monoclonal antibody directed against a neodeterminant in the heavy chain region of human coagulation factor XII (Hageman factor)

We studied the characteristics of two monoclonal antibodies (mAbs), F1 and F3, against human coagulation factor XII (Hageman factor). Experiments with trypsin-digested 125I-factor XII revealed that the epitope for mAb F1 is located in the NH2-terminal Mr 40,100 portion of factor XII, whereas that for mAb F3 resides in the COOH-terminal Mr 30,000 portion of this protein. Factor XII in fresh plasma (single-chain factor XII) bound approximately 190 times less to mAb F1 than factor XII in dextran sulfate-activated plasma (cleaved factor XII). However, no difference in accessibility of the epitope for mAb F1 was observed between cleaved and single-chain factor XII when bound to glass. mAb F3 appeared to bind to both single-chain and cleaved factor XII in plasma as well as when bound to glass. Neither mAb F1, nor F3 affected the amidolytic activity of factor XIIa, whereas both mAb F1 and F3 inhibited factor XII-coagulant activity to about 15 and 70%, respectively, at a molar ratio of mAb to factor XII of 20 to 1. mAb F1, as well as F(ab')2 and F(ab') fragments of this antibody induced activation of the contact system in plasma, as reflected by the generation of factor XIIa. C1 inhibitor and kallikrein. C1 inhibitor complexes. Activation was induced neither upon incubation with mAb F3, nor with that of control mAbs. mAb F1-induced contact activation required the presence of factor XII, prekallikrein, and high molecular weight kininogen and, in contrast to activation by negatively charged surfaces, was not inhibited by the presence of Polybrene. Based on these results we propose that a conformational change in factor XII is a key event in the activation process of this molecule. This conformational change can be induced by binding of factor XII to a surface as well as by proteolytic cleavage. As mAb F1 can also induce this conformational change, this antibody may provide a unique tool in studies of the activation of factor XII.     

Binding and activation properties of human factor XII, prekallikrein, and derived peptides with acidic lipid vesicles

The binding of human factor XII and prekallikrein to vesicles of various compositions and the relationship to activation of factor XII were studied. Factor XII, factor XIIa, and the 40-kilodalton binding fragment of factor XII bound tightly to all of the negatively charged lipids investigated, including sulfatide, phosphatidylserine, and phosphatidylethanolamine, but not to the neutral lipid phosphatidylcholine. Binding could be reversed by high salt, and the dissociation constant for binding to sulfatide vesicles was in the nanomolar range at an ionic strength of 0.15 M. Prekallikrein did not bind significantly to either sulfatide or phosphatidylethanolamine vesicles under the conditions used. Stopped-flow studies showed that the association rate for the factor XII-sulfatide interaction was biphasic and very rapid; the faster rate corresponded to about 30% collisional efficiency. The kinetics of activation of factor XII was investigated and was in agreement with previous studies; sulfatide promoted activation but phosphatidylserine, phosphatidylethanolamine, and phosphatidylcholine did not. Autoactivation rates correlated closely with the packing density of factor XII and factor XIIa on the vesicle surface. In contrast, kallikrein activation of factor XII correlated with the amount of sulfatide-bound factor XII and was relatively insensitive to the density of factor XII on the vesicle surface. When the concentration of factor XII was reduced to only several molecules per vesicle, the autoactivation rate dropped very low whereas kallikrein activation held relatively constant. These results indicated that the autoactivation and the kallikrein activation of factor XII were dependent on different properties of the surface component.     

Apolipoprotein B-100 of plasma low density lipoproteins undergoes proteolysis by contact activation factors when plasma is treated with dextran sulfate-500-MgCl2

Human plasma low density lipoproteins (LDL) isolated by ultracentrifugation showed a single band corresponding to apolipoprotein B-100 (apoB-100) by SDS-gradient gel electrophoresis (GGE). In turn, apoB-100 of LDL precipitated from plasma by dextran sulfate-500 (DS)-MgCl2 exhibited several bands indicative of a degradative process. The degradation was more extensive at 0 degrees C than at either 23 degrees C or 37 degrees C, and appeared to be related to a protease activity that cleaved both the synthetic peptide, Z-Phe-Arg-7-amido-4-methylcoumarin (Z-Phe-Arg-AMC) and apoB-100. Proteolysis was proportional to the DS added to the plasma, was prevented by the kallikrein inhibitor, D-Phe-L-Phe-L-Arg-CHCl2, and was significantly decreased in plasma specimens of patients with either factor XII or prekalikrein deficiency. LDL pre-purified by ultracentrifugation and then precipitated by DS in the absence of plasma exhibited no proteolysis. However, proteolysis was observed when LDL interacted with kallikrein. The two main apolipoproteins of HDL3, apoA-I and apoA-II, were not affected by this proteolytic process. We interpret the results to indicate that the negatively charged surface provided by DS accelerates in plasma the autoactivation of factor XII and the activation of prekallikrein, resulting in an increase of the effective concentration of kallikrein and possibly other proteases and proteolysis of LDL-apoB-100. The higher degree of the DS-induced proteolysis of apoB-100 at 0 degrees C than at 23 degrees C is likely the consequence of enhanced autoactivation of factor XII and a decreased efficiency of plasma inhibitors, such as C1-inhibitor. We speculate that the proteolysis of apoB-100 induced by DS is not limited to this polyanion, but may also be the property of other negatively charged agents, particularly at cold temperatures.     

Human factor XII binding to the glycoprotein Ib-IX-V complex inhibits thrombin-induced platelet aggregation

Factor XII deficiency has been postulated to be a risk factor for thrombosis suggesting that factor XII is an antithrombotic protein. The biochemical mechanism leading to this clinical observation is unknown. We have previously reported high molecular weight kininogen (HK) inhibition of thrombin-induced platelet aggregation by binding to the platelet glycoprotein (GP) Ib-IX-V complex. Although factor XII will bind to the intact platelet through GP Ibalpha (glycocalicin) without activation, we now report that factor XIIa (0. 37 microm), but not factor XII zymogen, is required for the inhibition of thrombin-induced platelet aggregation. Factor XIIa had no significant effect on SFLLRN-induced platelet aggregation. Moreover, an antibody to the thrombin site on protease-activated receptor-1 failed to block factor XII binding to platelets. Inhibition of thrombin-induced platelet aggregation was demonstrated with factor XIIa but not with factor XII zymogen or factor XIIf, indicating that the conformational exposure of the heavy chain following proteolytic activation is required for inhibition. However, inactivation of the catalytic activity of factor XIIa did not affect the inhibition of thrombin-induced platelet aggregation. Factor XII showed displacement of biotin-labeled HK (30 nm) binding to gel-filtered platelets and, at concentrations of 50 nm, was able to block 50% of the HK binding, suggesting involvement of the GP Ib complex. Antibodies to GP Ib and GP IX, which inhibited HK binding to platelets, did not block factor XII binding. However, using a biosensor, which monitors protein-protein interactions, both HK and factor XII bind to GP Ibalpha. Factor XII may serve to regulate thrombin binding to the GP Ib receptor by co-localizing with HK, to control the extent of platelet aggregation in vivo.     

Inhibition of factor VIII-associated platelet aggregation by heparin and dextran sulfate, and its mechanism.

Both ristocetin-induced aggregation in the presence of human factor VIII and bovine factor VIII-induced aggregation of washed normal human platelets were inhibited or reversed by the addition of heparin or dextran sulfate. These actions of dextran sulfate were stronger than those of heparin, and dependent on the sulfur content of dextran sulfate. In order to study the mechanism of actions of dextran sulfate and heparin, the affinity chromatographic experiment of factor VIII in human and bovine plasma, respectively, was carried out by using a dextran sulfate- and a heparin-Agarose column. Both human and bovine factor VIII have a strong affinity for dextran sulfate with high sulfur content and a weak affinity for heparin, but no affinity for dextran sulfate with low sulfur content. From these results, it is suggested that dextran sulfate or heparin binds directly the human and bovine factor VIII, which is an essential factor for the maintenance of the weak interplatelet bonds, and either inhibits or reverses the platelet aggregation.     

Inhibition of factor VIII-associated platelet aggregation by heparin and dextran sulfate,and its mechanism

Both ristocetin-induced aggregation in the presence of human factor VIII and bovine factor VII-induced aggregation of washed normal human platelets were inhibited or reversed by the addition of heparin or dextran sulfate. These actions of dextran sulfate were stronger than those of heparin, and dependent on the sulfur content sulfate. In order to study the mechanism of actions of dextran sulfate and heparin, the affinity chromatographic experiment of factor VIII in human and bovine plasma, respectively, was carried out by using a dextran sulfate- and a heparin-Agarose column. Both human and bovine factor VIII have a strong affinity for dextran sulfate with high sulfur content and a weak affinity for heparin, but no affinity for dextran sulfate with low sulfur content. From these results, it is suggested that dextran sulfate or heparin binds directly the human and bovine factor VIII, which is an essential factor for the maintenance of the weak interplatelet bonds, and either inhibits or reverses the platelet aggregation.     

Factor H is a dermatan sulfate-binding protein: identification of a dermatan sulfate-mediated protease that cleaves factor H

Dermatan sulfate mediates the blood coagulation cascade by binding to heparin cofactor II and potentiating the antithrombin activity. In order to explore another function of dermatan sulfate, a dermatan sulfate affinity column was prepared from biotinylated dermatan sulfate and Streptavidin Sepharose. When human plasma was applied on the dermatan sulfate column, factor H was bound and cleaved. The cleavage products, a 30-kDa N-terminal fragment and a 120-kDa fragment, were eluted from the column with 500 mM NaCl and detected after Western blotting with anti-factor H. The bond between the tandem arginine residues in the sixth domain of factor H was cleaved. When purified factor H was applied on the column, the factor H was not cleaved and was recovered from the column as an intact 150-kDa fraction. The finding that dermatan sulfate-mediated cleavage of factor H was inhibited by (p-amidinophenyl) methanesulfonyl fluoride, but not N-ethylmaleimide or EDTA, indicates that a serine protease in the plasma was activated on the dermatan sulfate column and factor H was cleaved without intervention of the plasma protease inhibitors. Amidase activity was detected in the effluent from the dermatan sulfate column but was abolished by pretreatment of the plasma with dermatan sulfate. Therefore, dermatan sulfate participates in the activation of a protease as well as having the protease inhibitory action.     

A mosquito salivary protein inhibits activation of the plasma contact system by binding to factor XII and high molecular weight kininogen

The salivary glands of female mosquitoes contain a variety of bioactive substances that assist their blood-feeding behavior. Here, we report a salivary protein of the malarial vector mosquito, Anopheles stephensi, that inhibits activation of the plasma contact system. This factor, named hamadarin, is a 16-kDa protein and a major component of the saliva of this mosquito. Assays using human plasma showed that hamadarin dose-dependently inhibits activation of the plasma contact system and subsequent release of bradykinin, a primary mediator of inflammatory reactions. Reconstitution experiments showed that hamadarin inhibits activation of the plasma contact system by inhibition of the reciprocal activation of factor XII and kallikrein. Direct binding assays demonstrated that this inhibitory effect is due to hamadarin binding to both factor XII and high molecular weight kininogen and interference in their association with the activating surface. The assays also showed that hamadarin binding to these proteins depends on Zn(2+) ions, suggesting that hamadarin binds to these contact factors by recognizing their conformational change induced by Zn(2+) binding. We propose that hamadarin may attenuate the host's acute inflammatory responses to the mosquito's bites by inhibition of bradykinin release and thus enable mosquitoes to take a blood meal efficiently and safely.     

Ca2+-mediated interaction between dextran sulfate and dimyristoyl-sn-glycero-3-phosphocholine surfaces studied by 2H nuclear magnetic resonance.

The binding of dextran sulfates (DSs) with varying chain lengths to phosphatidylcholine multilamellar vesicles was investigated as a function of polyelectrolyte, NaCl, and Ca2+ concentration. Attractive forces between negatively charged polyelectrolytes and zwitterionic phospholipids arise from the assembly of calcium bridges. The formation of calcium bridges between the sulfate groups on the dextran sulfate and the phosphate group of the lipid results in increased calcium binding in mixtures of DS and 1, 2-dimyristoyl-sn-glycero-3-phosphocholine (DMPC). At high NaCl concentration, the plateau adsorption of DS 500 is increased. The strength of dextran sulfate binding to DMPC is reflected in the changes of the 2H NMR quadrupolar splittings of the headgroup methylenes. Association forces increase with the number of calcium bridges formed. Low-molecular-weight DS does not bind to DMPC surfaces whereas longer-chain DSs strongly influence headgroup structure as a result of strong association. DS binding increases with increasing concentration; however, further association of the polyelectrolyte can be promoted only if negative charges are sufficiently screened. DS binding to lipid bilayers is a complicated balance of calcium bridging and charge screening. From our data we postulate that the structure of the adsorbed layer resembles a lattice of DS strands sandwiched between the bilayer lamellae.     

Highly sulfated glycosaminoglycans augment the cross-linking of vitronectin by guinea pig liver transglutaminase. Functional studies of the cross-linked vitronectin multimers.

Vitronectin (VN) is an adhesive glycoprotein with roles in the complement, coagulation, and immune systems. Many of the functions of VN are mediated by a glycosaminoglycan binding site, near its carboxyl-terminal end. In this paper, we show that the highly sulfated glycosaminoglycans (GAGs), dextran sulfate, pentosan polysulfate, and fucoidan effectively augment [14C]putrescine incorporation into VN and cross-linking of VN into high molecular multimers by guinea pig liver transglutaminase (TG). Other GAGs including heparin, low molecular weight heparin, dermatan sulfate, keratan sulfate, and the nonsulfated dextrans were ineffective in accelerating these reactions. Dextran sulfate of average molecular mass 500 kDa was more effective than dextran sulfate of average molecular mass 5 kDa, supporting a template mechanism of action of the GAGs, in which VN molecules align on the GAG in a conformation suitable for cross-linking. The VN multimers catalyzed by TG retained functional activity in binding [3H]heparin, platelets, and plasminogen activator inhibitor type-1 (PAI-1). [3H]Heparin bound selectively to the 65-kDa monomeric band of VN and to the multimers derived from this band. PAI-1, however, bound equally to both the 75- and 65-kDa monomeric forms of VN, suggesting that the PAI-1 binding site on VN is distinct from the GAG binding site. The interaction of GAGs with the TG-catalyzed cross-linking of VN may facilitate studies of VN structure-function relationships.     

A role for sulfated polysaccharide recognition in sponge cell aggregation

Molecules binding sulfated polysaccharides were detected as lectins in cholate lysates of cells from twelve sponge species. Each species exhibited a unique binding profile. The pattern of binding indicated that the specificity was most probably determined by the orientation of the sulfate groups on the polysaccharide chains. Cells from each of the three species examined in more detail were found to express sulfated polysaccharide-binding molecules at their surface and at least one of the polysaccharides recognized was found to inhibit the reaggregation of cells from each species. Moreover, in all but one instance, lectins for the inhibitory polysaccharide were both detected in cell lysates and shown to be expressed at the cell surface. Sulfated polysaccharides, therefore, appeared to be involved in cell interaction events in the Porifera. This conclusion was confirmed by the isolation via ion exchange chromatography of an endogenous polysaccharide from an O. tenuis cell extract. This molecule contained uronic acid and hexose units in a ratio of 2:1, 11.9% sulfur and less than 0.5% protein. It inhibited the aggregation of O. tenuis cells and the agglutination of dextran-sulfate- and polyvinyl-sulfate-coupled erythrocytes by O. tenuis cell lysates. O. tenuis cell aggregation was also inhibited by polyvinyl sulfate and dextran sulfate and molecules binding these compounds were expressed on the surface of O. tenuis cells. Thus, is was probable that the cell surface receptor for polyvinyl sulfate and dextran sulfate and isolated sponge sulfated polysaccharide are one and the same. Finally, using a dextran sulfate affinity procedure, a 35 kD dextran-sulfate-binding protein was isolated from the surface of O. tenuis cells. The possibility that the polysaccharide isolated from O. tenuis cell extracts in the absence of calcium is the monomeric form of a cell aggregation-enhancing factor is discussed.     

Human high molecular weight kininogen. Studies of structure-function relationships and of proteolysis of the molecule occurring during contact activation of plasma.

Human high Mr kininogen was purified from normal plasma in 35% yield. The purified high Mr kininogen appeared homogeneous on polyacrylamide gels in the presence of sodium dodecyl sulfate and mercaptoethanol and gave a single protein band with an apparent Mr = 110,000. Using sedimentation equilibrium techniques, the observed Mr was 108,000 +/- 2,000. Human plasma kallikrein cleaves high Mr kininogen to liberate kinin and give a kinin-free, two-chain, disulfide-linked molecule containing a heavy chain of apparent Mr = 65,000 and a light chain of apparent Mr = 44,000. The light chain is histidine-rich and exhibits a high affinity for negatively charged materials. The isolated alkylated light chain quantitatively retains the procoagulant activity of the single-chain parent molecule. 125I-Human high Mr kininogen undergoes cleavage in plasma during contact activation initiated by addition of kaolin. This cleavage, which liberates kinin and gives a two-chain, disulfide-linked molecule, is dependent upon the presence of prekallikrein and Factor XII (Hageman factor) in plasma. Addition of purified plasma kallikrein to normal plasma or to plasmas deficient in prekallikrein or Factor XII in the presence or absence of kaolin results in cleavage of high Mr kininogen and kinin formation.     

A monoclonal antibody recognizing an icosapeptide sequence in the heavy chain of human factor XII inhibits surface-catalyzed activation

A monoclonal antibody (mAb B7C9) to human factor XII was raised in murine somatic cell using purified factor XII antigen. The purified antibody was subtyped IgG1 kappa and had a KD of 9.8 nM for antigen factor XII. Functional studies indicated that mAb B7C9 blocks surface-mediated coagulant activity of factor XII but not the amidolytic activity of factor XIIa against the small substrate H-D-Pro-Phe-Arg-p-nitroanilide (S-2302), suggesting that the mAb B7C9 epitope is located at or near the surface binding domain of the heavy chain region of factor XII. Western blot analysis indicated that the antibody reacts with factor XII and the heavy chain of factor XIIa. Affinity isolation of factor XII peptides, produced after cleavage by kallikrein, resulted in three factor XII heavy chain domain segments that were identified in the known factor XII sequence by limited N-terminal analysis. The epitope was located to a 20-amino acid sequence of 2.5 kDa in the heavy chain of factor XII which is the putative surface binding region of factor XII. The 2.5-kDa peptide was synthesized and demonstrated to react with mAb B7C9. mAb B7C9 was immobilized on an affinity resin and was successfully utilized to purify functionally active factor XII from plasma.     

Priming effect of dextran sulphates on lipopolysaccharide-induced tumour necrosis factor production in mice

Abstract Dextran sulphate (DS) 500 (M.W. 500 000) is commonly used as a reticuloendothelial (RE) blocker. We found that lipopolysaccharide (LPS)-induced tumour necrosis factor (TNF) production in sera was enhanced when mice were pretreated with DS500. When mice were pretreated with DS1000 (M.W. 1 000 000), TNF activity in sera was also significantly enhanced by the LPS injection in comparison with the saline-treated group, but not by the pretreatment with the low molecular weight of DS5 (M.W. 5 000), neutral dextran (Dex) 500, or positively-charged diethylaminoethyl dextran (DEAE-Dex) 500. The enhancement of LPS-induced TNF production occurred from 2 h after DS500 pretreatment. Pretreatment with DS500 or DS1000 significantly suppressed the carbon clearance from the blood in mice from 2 h after DS injection, but this suppression was not detected by the pretreatment with DS5, Dex500, or DEAE-Dex500. We suggest that negative-charge and high molecular weight are essential for dextran derivatives to enhance LPS-induced TNF production, and that the enhancing effect of DS is closely related to the suppression of the RE function.     

Stabilization of basic fibroblast growth factor with dextran sulfate.

Dextran sulfate protected bFGF from heat and acid inactivation and from proteolytic degradation. The protective effect was stronger than that of heparin which is known as a stabilizer of bFGF. Dextran sulfate and bFGF formed a high molecular weight complex via ionic interaction when mixed together in aqueous solution. The complex was dissociated when the ionic strength was increased and the protective effect was completely abolished. Successive digestion of bFGF with Staphylococcus aureus V8 protease and pepsin followed by affinity chromatography on an immobilized dextran sulfate column and reversed-phase high performance liquid chromatography yielded three positively charged fragment peptides, Tyr24-Phe30, Tyr106-Trp114 and Tyr124-Leu138. These results suggest that dextran sulfate stabilizes bFGF by binding close to the putative heparin binding sites of the bFGF molecule.