Initiation of contact system activation in plasma is dependent on factor XII autoactivation and not on enhanced susceptibility of factor XII for kallikrein cleavage

Various mechanisms have been hypothesized to explain the initiation of contact system activation in plasma. We investigated the capability of dextran sulphate (DS) of different molecular weights to initiate contact system activation in normal human plasma, and compared this with their capability to support factor XII autoactivation and to enhance factor XII susceptibility for cleavage by kallikrein.
Dextran sulphate of M_r 500 000 (DS500) and 50 000 (DS50) was able to initiate contact system activation in plasma (determined by measuring the amount of factor XIIa–C1-inhibitor, kallikrein–C1-inhibitor and factor XIa–C1-inhibitor complexes generated) as well as to support factor XII autoactivation and to enhance factor XII susceptibility for cleavage by kallikrein (as measured with amidolytic assays using purified proteins). In contrast, dextran sulphate of M_r 15 000 (DS15) and 5000 (DS5) neither induced contact system activation in plasma, nor supported autoactivation of factor XII, although both of these DS species enhanced the rate of activation of factor XII by kallikrein in the purified system. Based on these properties (i.e. binding of factor XII without inducing autoactivation), DS15 and DS5 were predicted to be inhibitors of contact system activation induced in plasma by DS500, which indeed was observed.
We conclude that enhanced factor XII susceptibility for kallikrein activation and factor XII autoactivation are distinct phenomena, the latter being necessary to support activation of the contact system in plasma.     

Role of high-molecular-weight kininogen in surface-binding and activation of coagulation Factor XI and prekallikrein.

In the contact phase of activation of the kinin-forming, intrinsic clotting, and fibrinolytic systems, high-molecular-weight kininogen acts as a cofactor for the activation of Factor XI, prekallikrein, and Hageman factor. One mechanism by which high-molecular-weight kininogen acts as a cofactor has been studied by using 125I-labeled Factor XI and prekallikrein in kaolin-activated normal human plasma and plasmas deficient in high-molecular-weight kininogen and Hageman factor. High-molecular-weight kininogen was found to be essential for normal binding and cleavage of both Factor XI and prekallikrein on the kaolin surface. Hageman factor was essential for cleavage but not for binding of Factor XI and prekallikrein to kaolin. In normal plasma 80% of the activated Factor XI remained surface-bound, whereas 80% of the kallikrein was not surface-bound. These findings are consistent with the hypothesis that, in the initial phase of contact activation, high-molecular-weight kininogen links both Factor XI and prekallikrein to the exposed surface where they are activated by surface-bound activated Hageman factor. Once activated, the Factor XI molecules remain localized at the site of activation, in contrast to the kallikrein molecules which are found largely in the surrounding plasma.     

Preparation, Characterization, and Activation of a Highly Purified Factor XI: Evidence that a Hitherto Unrecognized Plasma Activity Participates in the Interaction of Factors XI and XII

S ummary . Highly purified native factor XI has been prepared from normal plasma using a five step purification scheme. Purified factor XI is essentially free of factors II, V, VII, VIII, IX, X, XII, and Fletcher factor. No plasminogen-plasmin could be detected. Purified factor XI decays rapidly but can be stabilized with human serum albumin. Factor XI migrates between the β and γ globulins on starch block electrophoresis. It has an apparent molecular weight on gel filtration of 210 000. Purified factor XI is activated by weak trypsin. No detectable BAEe esterase activity accompanies this activation. Neither factor XII adsorbed to kaolin nor activated factor XII in solution could activate purified factor XI; both reagents activate factor XI in dilute factor XII deficient plasma. Hence, plasma appears to supply a third activity which facilitates the interaction of factors XI and XII. This activity is shown to be distinct from Fletcher factor.     

Pseudo-factor-XI deficiency: effect of an inhibitor of factor XI adsorption to surface

Recently we have described a normal plasma activity that modulates contact activation by inhibiting adsorption of factor XI to activating surfaces. Here we report the first identified case in which a patient has abnormal clotting tests due to an excess of a similar activity. The patient's plasma had a prolonged partial thromboplastin time and low apparent factor XI assay. His plasma prolonged the partial thromboplastin time of normal plasma and partially neutralized normal factor XI activity in vivo and in vitro. Analysis in dilute plasma revealed normal amounts of factor XI activity and antigen. Factor XI adsorption from plasma to activating surfaces was tested by adding a small amount of 125I-labeled purified factor XI to plasma, exposing the mixture to a glass tube or kaolin, and determining the amount of factor XI adsorbed to the surface. Whereas normal plasma and plasmas deficient in factor XII, factor XI, or Fletcher factor yielded about 4% adsorption to glass, factor XI adsorption from patient's plasma was less than 1%, indicating the presence of an adsorption inhibitor. This inhibitor did not affect factor XI activation or the activity of preformed factor XIa. It was not adsorbed by AI(OH)3 and was present in serum and the macroglobulin peak on gel filtration of the plasma through Sephadex G-200. The patient's history does not allow a definitive conclusion as to whether this inhibitor was associated with abnormal bleeding.     

Molecular assembly in the contact phase of the Hageman factor system.

Data obtained in the past few years have defined the molecular mechanisms of contact activation of the Hageman factor pathways of plasma, i.e., the kinin-forming, intrinsic clotting and fibrinolytic systems. Involved are four molecules: Hageman factor, high molecular weight (MW) kininogen, prekallikrein and factor XI. High MW kininogen serves as a surface cofactor to assemble prekallikrein or factor XI in proximity to surface-bound Hageman factor. Reciprocal proteolytic activation of Hageman factor and prekallikrein represents an essential step in the rapid activation of the contact phase. Although Hageman factor does undergo cleavage and activation in the absence of prekallikrein or high MW kininogen, the rate is approximately 50 and 100 times slower than when these molecules are present. Once Hageman factor is activated on the surface, it cleaves and activates clotting factor XI. Activated Hageman factor (HFa) exhibits two molecular forms. One of these, alpha HFa, activates prekallikrein and factor XI, and the intrinsic clotting system on the surface. alpha HFa and clotting factor XI remain surface bound. The other form of activated Hageman factor, beta HFa, leaves the surface, going into solution where it readily activates additional prekallikrein but not factor XI. Of perhaps even greater importance, kallikrein rapidly dissociates from the surface. Thus the formation of bradykinin and fibrinolysis is disseminated whereas clotting via the intrinsic system remains localized. Reviewed here is the molecular mechanism of contact activation of the Hageman factor pathways and discussed in the interaction of Hageman factor with the negatively charged surface, prekallikrein, factor XI and high MW kininogen. The multiple forms of activated Hageman factor and their potential biologic significance are also discussed.     

Abnormal factor VIII Hiroshima: defect in crucial proteolytic cleavage by thrombin at Arg1689 detected by a novel ELISA

We have established an ELISA for detecting thrombin cleavage of the FVIII light chain at Arg¹⁶⁸⁹. The method used a coating alloantibody which recognized amino acid residues 2248–2312 in the C2 domain, together with a second monoclonal antibody, NMC-VIII/10, which recognized residues 1675–1684 in the amino-terminal region of the light chain. FVIII antigen (FVIII:Ag) was measured after treatment of plasma with various concentrations of thrombin. The FVIII:Ag of normal plasma was reduced in a dose-dependent manner by the thrombin, falling to 28% in the presence of 100 U/ml enzyme. The concentration of thrombin that achieved 50% reduction (IC₅₀) was approximately 1·0 U/ml. The plasma of four haemophilia A positive (A⁺) and two haemophilia A reduced (A^R) patients were analysed. The IC₅₀ of all patients was more than 1·0 U/ml, indicating that thrombin cleavage of the FVIII light chain was defective. One haemophilia A⁺ plasma did not respond to thrombin in this ELISA system. The patient (TI) was a haemophiliac with FVIII coagulant activity of 0·04 U/ml and FVIII:Ag of 1·78 U/ml. In addition, immunoblotting of the purified FVIII from TI showed that thrombin cleavage of the 80 kilodalton (kD) light chain was impaired. The patient's DNA was amplified using the polymerase chain reaction with a set of synthetic oligonucleotide primers spanning amino acid residues 1646–1714. Sequence analysis of the amplified DNA fragments revealed a cytosine to thymine transition, converting an arginine 1689 to cysteine. This abnormal FVIII was designated as FVIII Hiroshima. Our ELISA system is a simple and useful method of evaluating the proteolytic cleavage by thrombin at Arg¹⁶⁸⁹.     

Activating point mutations in the βC chain of the GM-CSF, IL-3 and IL-5 receptors are not a major contributory factor in the pathogenesis of acute myeloid leukaemia

A number of mutant growth factor receptors have been described which are constitutively activated and confer factor independence on growth factor dependent cells, possibly through constitutive dimerization in the absence of ligand or induction of a conformational change. Mutations in receptor chains may therefore contribute to the pathogenesis of haemopoietic malignancies, for example by causing constitutive receptor activation or uncontrolled downstream signalling. Since most of the activated mutants reported for the β_C chain of the GM-CSF/IL-3/IL-5 receptor involve point mutations or truncations of the extracellular domain, we have analysed the coding sequence of this region using RT-PCR-SSCP of RNA from blast cells of 31 patients with acute myeloid leukaemia (AML). Two point mutations detected were silent, C³⁰¹ → T (Cys91) and C¹³⁰⁶ → T (Ser426). The latter had previously been identified with an allele frequency of 0.13 in the general population. Two further point mutations detected led to amino acid substitutions, G⁷⁷³ → C (Glu249Gln), which is equivalent to the mouse sequences, and G⁹⁶² → A (Asp312Asn), both of which were found at similar frequencies in normal controls. Activating mutations of the β_C chain which might contribute to the pathogenesis of the disease are therefore rare in AML.     

Activation of bovine factor VII by hageman factor fragments

During the early events of coagulation of human blood by the intrinsic pathway, factor XII is activated to a form which can activate factor XI, and is proteolytically fragmented to smaller species (30,000 daltons and 70,000 daltons) which have lost most of the ability to activate factor XI but which can activate prekallikrein rapidly. The effect of these fragments on factor VII was studied. It was found that these Hageman factor fragments promoted rapid proteolysis of one-chain factor VII to a more active two-chain form. The amino-terminal sequences of the chains of activated factor VII were found to be Ala- Asx-Gly- and Ile-Val-Gly-, the same as were earlier observed after activation of factor VII by activated factor X. This finding indicates that initiation of coagulation by the intrinsic pathway also primes the extrinsic pathway.     

Activation of factor XI in plasma is dependent on factor XII [see comments]

The activation of factor XI initiates the intrinsic coagulation pathway. Until recently it was believed that the main activator of factor XI is factor XIIa in conjunction with the cofactor high molecular weight kininogen on a negatively charged surface. Two recent reports have presented evidence that in a purified system factor XI is activatable by thrombin together with the soluble polyanion dextran sulfate. To assess the physiological relevance of these findings we studied the activation of factor XI in normal and factor XII-deficient plasma. We used either kaolin/cephalin or dextran sulfate as a surface for the intrinsic coagulation pathway, tissue factor to generate thrombin via the extrinsic pathway, or the addition of alpha-thrombin directly. 125I-factor XI, added to factor XI-deficient plasma at physiologic concentrations (35 nmol/L), is rapidly cleaved on incubation with kaolin. The kinetics appear to be exponential with half the maximum cleavage at 5 minutes. Similar kinetics of factor XI cleavage are seen when 40 nmol/L factor XIIa (equal to 10% of factor XII activation) is added to factor XII-deficient plasma if an activating surface is provided. Tissue factor (1:500) added to plasma did not induce cleavage of factor XI during a 90-minute incubation, although fibrin formation within 30 seconds indicated that thrombin was generated via the extrinsic pathway. Adding 1 mumol/L alpha-thrombin (equivalent to 50% prothrombin activation) directly to factor XII deficient or normal plasma (with or without kaolin/cephalin/Ca2+ or dextran sulfate) led to instantaneous fibrinogen cleavage, but again no cleavage of factor XI was observable. We conclude that in plasma surroundings factor XI is not activated by thrombin, and that proposals of thrombin initiation of the intrinsic coagulation cascade are not supportable.     

Mechanisms for the involvement of high molecular weight kininogen in surface-dependent reactions of Hageman factor.

The mechanisms by which human high molecular weight kininogen (HMKrK) contributes to the surface-dependent activation of the Hageman factor systems have been studied. The ability of various mixtures of purified human Hageman factor (coagulation factor XII), HMrK, prekallikrein, and kaolin to activate coagulation factor XI was determined with factor XIa (activated factor XI) clotting assays. Hageman factor, HMrK and prekallikrein were required for maximal rates of activation of factor XI. A certain optimal mixture of purified Hageman factor, HMrK, prekallikrein, and kaolin gave the same rapid initial rate of activation of purified factor XI as an equivalent aliquot of factor XI-deficient plasma. This suggests that potent, surface-mediated activation of factor XI in plasma is explicable in terms of Hageman factor, HMrK, and prekallikrein. By studying separately some of the surface-dependent reactions involving Hageman factor, it was found that HMrK accelerated by at least an order of magnitude the following reactions: (i) the activation of factor XI by activated Hageman factor; (ii) the activation of prekallikrein by activated Hageman factor; and (iii) the activation of Hageman factor by kallikrein. Stoichiometric rather than catalytic amounts of HMrK gave optimal activation of factor XI. These results are consistent with the hypothesis that HMrK and Hageman factor form a complex on kaolin which renders Hageman factor more susceptible to proteolytic activation by kallikrein and which facilitates the action of activated Hageman factor on its substrate proteins, factor XI and prekallikrein.     

The Relation of 'Fletcher Factor' to Factors XI and XII

S ummary . Further evidence is presented for the existence of a new coagulation factor which is closely related to Hageman factor (XII) and plasma thromboplastin antecedent, PTA (XI). This factor has been tentatively designated 'Fletcher factor'. Coagulant activity of Fletcher factor was separated from the clotting activity of factors XI and XII by C-M Sephadex column chromatography of intact normal plasma. Other studies showed that the prolonged partial thromboplastin time or plasma recalcification time of Fletcher-deficient plasma could be 'corrected' by prolonged contact with celite, glass, kaolin, or ellagic acid; all are known activators of factor XII. Cytochrome c, known to inhibit the contact activation of factor XII, completely abolished this contact 'correction' of Fletcher-deficient plasma. Thus, the clotting times of plasmas deficient in Fletcher factor (presently found in seven individuals from four unrelated families) are readily corrected by activated factors XII and XI. None of these individuals has any bleeding tendencies.
Fletcher factor activity is deficient in the plasma of newborn infants; the factor is probably produced in the liver and not dependent on vitamin K for its synthesis.     

Activated factor V is a cofactor for the activation of factor XI by thrombin in plasma

The mechanism by which the intrinsic pathway of coagulation contributes to physiological hemostasis is enigmatic. Thrombin activates factor XI, a key zymogen in this pathway, which leads to increased thrombin generation. As thrombin-dependent activation of factor XI in vitro is relatively inefficient, we hypothesized that a physiological cofactor supports this reaction in a plasma environment. We therefore investigated whether the cofactors of coagulation, activated factor V, activated factor VIII, high-molecular weight kininogen, or protein S, influenced activation of factor XI by thrombin. Only activated factor V stimulated activation of factor XI by thrombin in a purified system. Binding studies demonstrated that factor XI specifically interacts with both factor V and factor Va through multiple binding sites. We further investigated this cofactor function of activated factor V in plasma. Depletion of factor V, or the addition of activated protein C, decreased the activation of the intrinsic pathway by thrombin in plasma. However, activated protein C did not exert this effect in the plasma of a homozygous carrier of the prothrombotic factor V Leiden mutation. In conclusion, we propose a role for (activated) factor V as a cofactor in the activation of factor XI by thrombin. These findings offer insights into the coagulation system in both health and disease.     

Haemoglobin F Texas II (α2γ26 Glu→Lys), the Second of the Haemoglobin F Texas Variants

S ummary A survey of 13 ,000 cord bloods in Great Britain yielded an electrophoretically abnormal variant of Haemoglobin F which resembled Haemoglobin F Texas. Haemoglobin F Texas might be either α₂γ₂^5G1u→Lys or α₂γ₂^6Glu→Lys. The first has been described and was named Haemoglobin F Texas I. The present variant has the same substitution in the sixth residue of the γ chain and is designated as Haenioglobin F Texas II.     

Spectrin-haemoglobin crosslinkages associated with in vitro oxidant hypersensitivity in pathologic and artificially dehydrated red cells

S ummary . Protein crosslinkages are apparent at 215000–250000 daltons in electrophoregrams of membranes from hydrogen peroxide treated erythrocytes (British Journal of Haematology , 48 ,435, 1981). Hydrogen peroxide is also capable of inducing crosslinkages of identical molecular weights in stage I and II (red) ghosts and in a mixture of purified spectrin and haemoglobin, but not in white ghosts or in either spectrin or haemoglobin alone. Autoradiographic studies using ¹⁴C-methae-moglobin and ³²P-spectrin confirm the involvement of spectrin and haemoglobin in this reaction. The alpha chains of both proteins are more reactive than the corresponding beta chains: 3 times more reactive in the case of spectrin and 10 times more reactive in haemoglobin. The reaction is almost totally inhibited by NaCN and partially inhibited by N-ethylmaleimide. Direct addition of malondialdehyde to a spectrin-haemoglobin mixture does not result in protein crosslinkage. Metabolic depletion (40 h), in vivo ageing and sucrose dehydration of fresh, normal cells enhance the reaction considerably, whereas in vitro rehydration of xerocytes normalizes their H₂O₂ sensitivity.     

Amidolytic assay of human factor XI in plasma: comparison with a coagulant assay and a new rapid radioimmunoassay

The traditional coagulant assay for plasma factor XI suffers from a relatively high coefficient of variation, the need for rare congenitally deficient plasma, and a poor correlation between precision and sensitivity. We have developed a simple functional amidolytic assay for factor XI in plasma using the chromogenic substrate PyrGlu-Pro-Arg- p-nitroanilide (S-2366). After inactivation of alpha 1-antitrypsin, CI inhibitor, and other plasma protease inhibitors with CHCI3, plasma was incubated with kaolin, in the absence of added calcium, which limited the enzymes formed to those dependent on contact activation. Soybean trypsin inhibitor was used to minimize the action of kallikrein on the substrate. Once the reaction was complete, corn trypsin inhibitor was used to inactive factor XIIa, the enzyme generated by exposure of plasma to negatively charged surfaces, which had activated the factor XI. The assay is highly specific for factor XI, since plasma totally deficient in that zymogen yielded only 1%-3% of the enzymatic activity in normal plasma under identical conditions. The requirements for complete conversion of factor XI to XIa in plasma within 60 min were, respectively, factor XII, 0.6 U/ml, and high molecular weight kininogen, 0.2 U/ml. Prekallikrein was not an absolute requirement for complete activation but did accelerate the reaction. The intraassay coefficient of variation was 3.4%, and the mean of 35 normal plasmas was 1.00 U +/- 0.24 SD. In addition, a new rapid radioimmunoassay was devised using staphylococcal protein A as the precipitating agent for a complex of factor XI antigen with monospecific rabbit antibody. The mean was 1.01 U +/- 0.30 SD. The correlation coefficients for amidolytic versus coagulant and amidolytic versus radioimmunoassay were r = 0.95 for the former and 0.96 for the latter. Thus, a simple, accurate amidolytic assay and a radioimmunoassay have been devised for measuring factor XI in plasma that correlate well with the coagulant activity of factor XI, as determined in our laboratory.     

Detection of glycoprotein IIb and IIIa by monoclonal antibodies

Murine monoclonal antibodies were produced against human platelet membranes and screened on platelets by a ¹²⁵I protein A radioimmunoassay. Several clones produced platelet specific antibodies as they showed no reaction with peripheral blood lymphocytes, neutrophils, bone marrow (excluding megakaryocytes) or several cell lines. Two antibodies (designated anti-HuPl-mla and anti-HuPl-mlb) were of particular interest in that although platelet specific they were non-reactive with platelets from a thrombasthenic patient. In functional assays these two antibodies could specifically inhibit ADP and collagen induced aggregation of platelets and release of ATP, retard platelet aggregation and ATP release induced by epinephrine, and inhibit ADP induced platelet fibrinogen binding. These two antibodies appear to recognize glycoproteins IIb and IIIa as analysis by SDS-PAGE using radiolabelled membranes revealed a two chain structure of molecular weight 112 000 and 122 000 daltons when run after reduction and 87 000 and 140 000 daltons non-reduced.     

Identification of calcium-dependent, phospholipid- and calmodulin-activated protein kinases in rat small intestinal epithelium

The mechanisms by which increases in cytosolic calcium promote ion-secretion in the intestinal epithelium may involve the phosphorylation of key transport proteins in the microvillus membrane. Using both direct and indirect methods evidence has been provided for two distinct calcium-regulated protein kinase activities in rat small intestinal epithelium — one activated by phosphatidylserine (C-kinase), the other by calmodulin (CDR-kinase).
C-kinase activity was identified in cytosolic and particulate fractions including purified brush border membranes using a specific histone substrate. In the presence of phosphatidylserine and diacylglycerol, calcium markedly stimulated enzyme activity, half-maximal effects occurring at 2.8X10^-7 mol/1 free calcium. Phorbol esters, known activators of C-kinase, were also shown to stimulate the phosphorylation of an endogenous peptide (Mr = 94 000) in cell homogenates.
The addition of exogenous calmodulin (10–100 μg/ml) stimulated a 50–75% increase in the labelling of peptide (Mr = 50 000–55 000). Trifluoperazine (0.1–10 μmol/l) inhibited basal phosphorylation of this and other peptides suggesting the likely involvement of a protein kinase activated by endogenous levels of calmodulin. Cytosolic fractions were also able to phosphorylate purified myosin light chains, a known substrate for CDR-kinase, in the presence of submicromolar concentrations of free calcium (ED₅₀= 2.4X10^-7 mol/l) although no direct stimulation of this activity by calmodulin could be demonstrated. MLC-phosphorylated activity was not identified in particulate fractions.     

Fibrinogen blocks the autoactivation and thrombin-mediated activation of factor XI on dextran sulfate.

The intrinsic pathway of blood coagulation is activated when factor XIa, one of the three contact-system enzymes, is generated and then activates factor IX. Factor XI has been shown to be efficiently activated in vitro by surface-bound factor XIIa after factor XI is transported to the surface by its cofactor, high molecular weight kininogen (HK). However, individuals lacking any of the three contact-system proteins--namely, factor XII, prekallikrein, and HK--do not suffer from bleeding abnormalities. This mystery has led several investigators to search for an "alternate" activation pathway for factor XI. Recently, factor XI has been reported to be autoactivated on the soluble "surface" dextran sulfate, and thrombin was shown to accelerate the autoactivation. However, it was also reported that HK, the cofactor for factor XIIa-mediated activation of factor XI, actually diminishes the thrombin-catalyzed activation rate of factor XI. Nonetheless, it was suggested that thrombin was a more efficient activator than factor XIIa. In this report we investigated the effect of fibrinogen, the major coagulation protein in plasma, on the activation rate of factor XI. Fibrinogen, the preferred substrate for thrombin in plasma, virtually prevented autoactivation of factor XI as well as the thrombin-mediated activation of factor XI, while having no effect on factor XIIa-catalyzed activation. HK dramatically curtailed the autoactivation of factor XI in addition to the thrombin-mediated activation. These data indicate that factor XI would not be autoactivated in a plasma environment, and thrombin would, therefore, be unlikely to potentiate the activation. We believe that the "missing pathway" for factor XI activation remains an enigma that warrants further investigation.     

Factor XI antigen and activity in human platelets

Washed platelets, contaminated with less than 0.20% plasma factor XI, were examined for the presence of factor XI antigen and activity. These platelets contained a factor-XI-like coagulant activity (0.67 +/- 0.11 U/10(11) platelets) that remained constant after successive washes. By means of indirect immunofluorescence, a monospecific antibody to factor XI showed specific staining of both normal platelets and platelets from patients deficient in plasma factor XI. Radiolabeled Triton extracts of washed platelets and labeled purified factor XI solutions were analyzed for factor XI antigen by Staph A immunoprecipitation analysis using antibody to purified plasma factor XI followed by SDS gel electrophoresis. On unreduced gels, the platelet material ran as a single band having an apparent molecular weight of 220,000 daltons, whereas purified plasma factor XI gave a single band at 160,000 daltons. On reduced gels, the platelet material analyzed as a single band at 52,000 daltons, whereas purified factor XI gave a single band of 80,000 daltons. Analysis of a partially purified factor XI preparation from platelets by immunoelectrophoresis revealed that the platelet preparation displayed a slightly lower cathodal electrophoretic mobility at pH 8.6 than did plasma factor XI and yet appeared to possess complete antigenic identity with plasma factor XI. These results indicate that platelets possess a form of factor XI that exists as a disulfide-linked 52,000-dalton tetramer in contrast to the plasma form that circulates as a 80,000-dalton disulfide-linked dimer.     

The Effect of Calcium Ions on the Properties of Factor IX and its Activated Form

S ummary . The activation of bovine plasma factor IX requires activated factor XI and calcium ions, but not phospholipids. It results in an apparent reduction in molecular size or shape as shown by gel filtration on Sephadex G-200 and sucrose gradient ultracentrifugation. DEAE chromatography reveals that the surface charge may be altered upon activation. In the presence of calcium ions, both the precursor and activated form of factor IX showed reduction in sizes. Calcium ions also promote the adsorption of factor IXa on a glass surface. The significance of the change of size and surface charge in the interaction of factor IX and phospholipids is discussed.