Purification and characterization of an abnormal factor IX (Christmas factor) molecule. Factor IX Chapel Hill

A candidate activation pathway for coagulation factor VII

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.

Kinetics of factor IX activity differ from that of factor IX antigen in patients with haemophilia B receiving high-purity factor IX replacement

Pharmacokinetic studies in haemophilia B have found in vivo recovery of FIX (FIX) to be uniformly lower than the factor VIII recovery in haemophilia A. We hypothesized that this lower recovery could result from rapid binding to high-affinity receptors on platelets and endothelium. To test this hypothesis, we evaluated the kinetics of FIX activity and protein in haemophilia B patients. Twelve patients were enrolled in a double dosing, crossover study with two high-purity FIX concentrates, AlphaNine SD and MonoNine. Subjects were given 40 U kg-1 of FIX concentrate and blood samples were taken at 15, 30, and 60 min. A second infusion of 40 U kg-1 was given after the 60 min blood sample and further blood samples removed at 15, 60, 120, and 360 min after the second dose. Patients were infused with the alternate concentrate at least 7 days later. Plasma samples were assayed for FIX activity by coagulation assay and antigen by RIA. FIX antigen in the infused concentrates was measured and quantified as microg U-1. There was no difference between the two FIX concentrates (AlphaNine vs. MonoNine) in the initial (15 min) activity (57% +/-1 19% vs. 53% +/-1 12%) and antigen (62% +/-1 16% vs. 55% +/-1 19%) recoveries. Recoveries after the second FIX dose were not statistically different than those observed after the first FIX dose. In one patient, a doubling of the initial infusion dose did not increase FIX recovery after the second FIX dose. However, the recovery of FIX antigen was significantly greater than the recovery of FIX activity and the differences became more significant in the post-15 min samples. We calculated a ratio of plasma FIX antigen to FIX activity in microg U-1. Average antigen to activity ratio increased from 5.8 +/-1 1.9 microg U-1 at 15 min to 7.1 +/-1 2.2 microg U-1 at 60 min. At 420 min the ratio increased to 9.3 +/-1 2.4 microg U-1. Although these studies failed to demonstrate a significant FIX receptor pool, they did demonstrate a phenomenon of progressive loss of biologic activity of the FIX protein after infusion of FIX concentrates.

A mutation adjacent to the beta cleavage site of factor IX (valine 182 to leucine) results in mild haemophilia Bm

The genetic basis of a mild form of haemophilia Bm has been investigated. The patient under investigation has a mild bleeding disorder and has never experienced spontaneous bleeds. Factor IX coagulant activity (FIX:C) was 0.15 units/ml and factor IX antigen (FIX:Ag) 1.32 units/ml. The prothrombin time performed with an ox brain thromboplastin was 65 s (normal plasma 31 s). Studies of the abnormal factor IX protein in this patient showed a normal molecular weight and normal calcium binding properties. Activation of the mutant factor IX with factor XIa showed normal proteolytic cleavage. DNA sequence from the eight factor IX exons and flanking introns was amplified from this patient using the polymerase chain reaction. The amplified material was subjected to direct chain termination nucleotide sequencing. The only nucleotide sequence alteration found was a G----C transversion at nucleotide 20,524, changing the amino acid encoded at residue 182 from valine to leucine. This residue is one amino acid removed from the beta cleavage site of factor IX. This residue is highly conserved in other vitamin K dependent serine proteases and we propose that its alteration in this patient is responsible for his mild haemophilic phenotype, and for the abnormal interaction of this factor IX protein with the extrinsic system of coagulation.

Immunoaffinity purification of factor IX (Christmas factor) by using conformation-specific antibodies directed against the factor IX-metal complex

Factor IX is a vitamin K-dependent blood clotting zymogen that is functionally defective or absent in patients with hemophilia B. A method of immunoaffinity chromatography has been developed for a one-step high yield purification of factor IX directly from plasma. The technique utilizes conformation-specific antibodies that bind solely to the metal-stabilized factor IX conformer, but not to the conformer of factor IX found in the absence of metal ions. Anti-factor IX-Ca(II) antibodies were immobilized on an agarose matrix. Human plasma in the presence of 7.5 mM MgCl2 was applied to the antibody-agarose column. The factor IX that binds to these antibodies was specifically eluted by metal chelation with EDTA. This immunopurification resulted in a 10,000-fold one-step purification of the fully functional zymogen. Purified factor IX yielded a single band upon gel electrophoresis in Na-DodSO4 and had a specific activity of 120-150 units/mg. The purified factor IX was separated from other vitamin K-dependent blood clotting proteins and hepatitis virus; no activated factor IX was detected. This method has application for the large scale purification of factor IX for the treatment of hemophilia B.

Activation of normal and abnormal human factor IX with trypsin

Human factor IX is activated to factor IXa beta when factor XIa cleaves two peptide bonds, Arg 145-Ala 146 and Arg 180-Val 181, to release an activation peptide. In factor IX Chapel Hill (IXCH), isolated from a hemophilia B patient with a mild bleeding disorder, the arginine 145 residue has been replaced with a histidine. Thus factor IXCH is activated by factor XIa by cleaving only at the Arg 180-Val 181 bond, leaving the activation peptide attached, and resulting in an activated species, factor IXa alpha CH, that, like normal factor IXa alpha, is only 20% as active as factor IXa beta. It is reported that both factor IX and factor IXCH could be activated by trypsin to forms of factor IXa beta and factor IXa beta CH that had clotting activities identical to factor XIa-activated factor IX. Amino-terminal amino acid sequence analysis showed that trypsin cleaved factor IX at the same bonds as did factor XIa; factor IXCH was cleaved at the Arg 180-Val 181 bond, as normal, and was cleaved near the histidine 145, at the Lys 142-Leu 143 bond, releasing a slightly larger activation peptide than from normal factor IXa beta. Metal ions had no effect on the rate of activation of factor IX by trypsin; however, metal ions had a profound effect on the rate at which further incubation with trypsin inactivated factor IXa. Calcium and manganese protected factor IXa from inactivation by trypsin more effectively than magnesium, which was more effective than no metal ion. It is concluded that trypsin can activate normal factor IX and factor IXCH to fully active IXa beta forms.

Characterization of three abnormal factor IX variants (Bm Lake Elsinore, Long Beach, and Los Angeles) of hemophilia-B. Evidence for defects affecting the latent catalytic site

Abnormal factor IX variant proteins were isolated from the plasmas of three unrelated severe hemophilia-B families that had been previously shown to contain functionally impaired molecules immunologically similar to normal factor IX. The families studied were: (1) a patient with markedly prolonged ox brain prothrombin time, designated factor IX Bm Lake Elsinore (IXBmLE); (b) three patients (brothers) with moderately prolonged ox brain prothrombin time, designated factor IX Long Beach (IXLB); and (c) a patient with normal ox brain prothrombin time designated factor IX Los Angeles (IXLA). Each variant molecule comigrates with normal factor IX (IXN) both in the sodium dodecyl sulfate and in the nondenaturing alkaline gel electrophoresis. All three variant proteins are indistinguishable from IXN in their amino acid compositions, isoelectric points, carbohydrate distributions and number of gamma-carboxyglutamic acid residues. Each variant protein undergoes a similar pattern of cleavage by factor XIa/Ca2+ and by factor VIIa/Ca2+/tissue factor, and is activated at a rate similar to that observed for IXN. All of the three variant proteins also react with an anti-IXN monoclonal antibody that interferes with the binding of activated IXN(IXaN) to thrombin-treated factor VIIIC. However, in contrast to IXaN, the cleaved IXBmLE has negligible activity (approximately 0.2%), and cleaved forms of IXLA and IXLB have significantly reduced activity (approximately 5-6%) in binding to antithrombin-III/heparin, and in activating factor VII (plus Ca2+ and phospholipid) or factor X (plus Ca2+ and phospholipid) +/- factor VIII. These data, taken together, strongly indicate that the defect in these three variant proteins resides near or within the latent catalytic site. This results in virtually a complete loss of catalytic activity of the cleaved IXBmLE molecule and approximately 95% loss of catalytic activity of the cleaved IXLA and IXLB molecules.

Characterization of the clotting activities of structurally different forms of activated factor IX. Enzymatic properties of normal human factor IXa alpha, factor IXa beta, and activated factor IX Chapel Hill

Two structurally different forms of activated human Factor IX (Factor IXa alpha and IXa beta) have been previously reported to have essentially identical clotting activity in vitro. Although it has been shown that activated Factor IX Chapel Hill, an abnormal Factor IX isolated from the plasma of a patient with mild hemophilia B, and normal Factor IXa alpha are structurally very similar, the clotting activity of activated Factor IX Chapel Hill is much lower (approximately fivefold) than that of normal Factor IXa beta. In the present study we have prepared activated Factor IX by incubating human Factor IX with calcium and Russell's viper venom covalently bound to agarose. Fractionation of the activated Factor IX by high-performance liquid chromatography demonstrated the presence of both Factors IXa alpha and IXa beta. On the basis of active site concentration, determined by titration with antithrombin III, the clotting activities of activated Factor IX Chapel Hill and IXa alpha were similar, but both activities were less than 20% of the clotting activity of Factor IXa beta. Activated Factor IX activity was also measured in the absence of calcium, phospholipid, and Factor VIII, by determination of the rate of Factor X activation in the presence of polylysine. In the presence of polylysine, the rates of Factor X activation by activated Factor IX Chapel Hill, Factor IXa alpha, and Factor IXa beta were essentially identical. We conclude that the clotting activity of activated Factor IX Chapel Hill is reduced when compared with that of Factor IXa beta but essentially normal when compared with that of Factor IXa alpha.

Regulation of factor IXa in vitro in human and mouse plasma and in vivo in the mouse. Role of the endothelium and the plasma proteinase inhibitors

The regulation of human Factor IXa was studied in vitro in human and mouse plasma and in vivo in the mouse. In human plasma, approximately 60% of the 125I-Factor IXa was bound to antithrombin III (ATIII) by 2 h, with no binding to alpha 2-macroglobulin or alpha 1-proteinase inhibitor, as assessed by gel electrophoresis and IgG- antiproteinase inhibitor-Sepharose beads. In the presence of heparin, virtually 100% of the 125I-Factor IXa was bound to ATIII by 1 min. The distribution of 125I-Factor IXa in mouse plasma was similar. The clearance of 125I-Factor IXa was rapid (50% clearance in 2 min) and biphasic and was inhibited by large molar excesses of ATIII-thrombin and alpha 1-proteinase inhibitor-trypsin, but not alpha 2-macro-globulin-trypsin; it was also inhibited by large molar excesses of diisopropylphosphoryl - (DIP-) Factor Xa, DIP-thrombin, and Factor IX, but not by prothrombin or Factor X. The clearance of Factor IX was also rapid (50% clearance in 2.5 min) and was inhibited by a large molar excess of Factor IX, but not by large molar excesses of Factor X, prothrombin, DIP-Factor Xa, or DIP-thrombin. Electrophoresis and IgG- antiproteinase inhibitor-Sepharose bead studies confirmed that by 2 min after injection into the murine circulation, 60% of the 125I-Factor IXa was bound to ATIII. Organ distribution studies with 125I-Factor IXa demonstrated that most of the radioactivity was in the liver. These studies suggest that Factor IXa binds to at least two classes of binding sites on endothelial cells. One site apparently recognizes both Factors IX and IXa, but not Factor X, Factor Xa, prothrombin, or thrombin. The other site recognizes thrombin, Factor Xa, and Factor IXa, but not the zymogen forms of these clotting factors. After this binding, Factor IXa is bound to ATIII and the complex is cleared from the circulation by hepatocytes.

Identification of the molecular defect in factor IX Chapel Hill: substitution of histidine for arginine at position 145

Hemophilia B Chapel Hill is a mild hereditary hemorrhagic disorder in which the factor IX antigen is present in normal amounts but factor IX biological activity is markedly reduced. Previous studies have demonstrated that purified factor IX Chapel Hill has 8% of the activity of normal human factor IX and that the activation of factor IX Chapel Hill is defective in that only one of the two peptide bonds hydrolyzed during activation of normal factor IX is cleaved. The tryptic peptides from normal human factor IX and factor IX Chapel Hill were subjected to analysis by high-performance liquid chromatography. Comparison of the elution profile of the peptides obtained from factor IX Chapel Hill and normal factor IX demonstrated that the tripeptide Leu-Thr-Arg, which is derived from the normal molecule (positions 143-145) immediately amino-terminal from the Arg-Ala peptide bond at 145-146 that is cleaved during the activation of factor IX with factor XIa, was absent in the digest obtained from factor factor IX Chapel Hill. The elongated "activation peptide" from factor factor IX Chapel Hill was obtained by further high-performance liquid chromatographic fractionation and subjected to primary structure analysis. The following sequence, corresponding to positions 143-147, was obtained: Leu-Thr-His-Ala-Glu. Thus, the primary molecular defect in factor factor IX Chapel Hill is the substitution of histidine for arginine at position 145. This substitution precludes cleavage by factor XIa at this peptide bond, and the activation peptide region remains associated with the light chain of factor IXa Chapel Hill.

Measurement of human factor IXa activity in an isolated factor X activation system

To determine the functional properties of factor IX isolated from the plasma of CRM+ hemophilia B patients, an assay system using proteins isolated from human plasma had to be developed which would be amenable to kinetic studies under a variety of experimental conditions. The present study describes the activation of factor X by factor IXa, isolated from normal human plasma, in an assay system which allows manipulation of calcium, phospholipid and factor VIIIa concentrations. Initial rate measurements with factor VIIIa present in the system were made by incubating factor VIII with factor Xa immediately before factor IXa assay. With this approach, the initial rate of factor X activation was constant, with little evidence for a lag period. Within the framework of the assay system described in the present study, it should be possible to examine not only genetic variants of factor IX, but also variants of factor VIII, as well as providing a means of routine factor IXa and factor VIII(a) assays.

Characterization of the defect in activation of factor IX Chapel Hill by human factor XIa

Factor IXChapel Hill (Factor IXCH), an abnormal Factor IX molecule isolated from the plasma of a patient with mild hemophilia B, has previously been shown to exhibit delayed activation by Factor XIa and calcium. In this study, we have found that Factor IXCH is cleaved upon incubation with human Factor XIa and calcium; however, cleavage of this protein is not observed by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis under nonreducing conditions. Under reducing conditions, the rate of disappearance of the zymogen parallels both the appearance of the heavy chain and the generation of clotting activity. In addition, a protein band that migrates with an apparent molecular weight of 45,000 also increases in parallel with clotting activity. Factor IXCH and normal Factor IX (Factor IXN), after incubation with Factor XIa and calcium, were subjected to amino terminal sequence analysis. Activated Factor IXN is cleaved at an arginine-alanine (Arg-Ala) bond and an arginine-valine (Arg-Val) bond as demonstrated by formation of the three amino terminal sequences corresponding to the amino terminal of the light chain, heavy chain, and activation peptide. However, activated Factor IXCH has only two amino terminal sequences, corresponding to the original amino terminal sequence and the heavy chain (formed by cleavage at the Arg-Val bond). It is concluded that the major defect in Factor IXCH is the inability of Factor XIa to cleave the Arg-Ala bond at a significant rate. The rate of formation of clotting activity of Factor IXCH is approximately 60% of the rate of formation of clotting activity of Factor IXN. The specific clotting activity of activated Factor IXCH is between 20 and 33% of activated Factor IXN.

New methods in coagulation

Recent advances in the elucidation of the molecular biochemistry of the coagulation proteins have provided the foundation for the development of synthetic substrates. These substrates are oligopeptide with either a chromophore or fluorophore group attached to the C-terminal end. They may be used in the laboratory to assay for a number of the serine proteases involved in either coagulation or fibrinolysis. Also, by suitably modifying the assay system, the various inhibitors can be quantitated. These substrates promise to revolutionize the coagulation laboratory allowing for more precise quantitation of trace enzymes and also improved standardization and precision of coagulation assays. In addition to these substrates, the introduction of a number of immunologic procedures into the diagnostic laboratory have been of major importance in elucidating the heterogeneity of hereditary coagulation defects. By correlating the immunologic assays, coagulation assays and clinical picture, a number of subgroups of hereditary deficiencies have been identified. Also, the immunologic assays have provided a means for identifying the carrier state of hemophilia A and have significantly contributed to the improved diagnosis of von Willebrand's disease. The use of ristocetin cofactor assays, when used in conjunction with the Factor VIII antigens, have enable the laboratory to more accurately diagnose the majority of patients with von Willebrand's disease. Ristocetin cofactor may be assayed utilizing either formalin fixed or washed platelets and recently a snake venom has been introduced to assay for this particular aspect of the Factor VIII complex. Platelet specific proteins (i.e., platelet factor 4 and beta-thromboglobulin) may be assayed utilizing either radioimmunoassays or in the case of platelet factor 4 modified coagulation assays. These proteins provide evidence of in vivo platelet activation and hopefully may, in the future, be correlated with platelet kinetics.

Characterization of a variant prothrombin in a patient congenitally deficient in factors II, VII, IX and X

An 18-month-old child, who had no evidence of liver disease, malabsorption, or chronic ingestion of coumarin compounds, was found to have plasma deficiencies of factors II, VII, IX and X. Assays for factor II and X by immunological techniques (antibody neutralization and immunoelectrophoresis) revealed normal or elevated antigenic activity of these factors, suggesting the presence of abnormal protein variants in the patient's plasma. On two-dimensional immunoelectrophoresis of the patient's plasma in calcium, a normal and an abnormal population of prothrombin were seen. The abnormal prothrombin had a mobility more anodal than that of normal prothrombin, but less anodal than that of acarboxyprothrombin. The abnormal prothrombin, in contrast to acarboxyprothrombin, adsorbed readily to both aluminum hydroxide and barium citrate, and could be identified by two-dimensional immunoelectrophoresis of a barium citrate eluate. We suspect that the abnormal variant represents a partially carboxylated prothrombin.

An agarose plate method for detecting alloantisera to coagulant factor IX and factor IX antigen

An agarose plate method for detecting human alloantibodies (inhibitors) to coagulant factor IX has been developed. The assay is based on the ability of such antisera to inhibit the coagulation of a mixture of haemophilia B plasma, normal plasma and platelet subsitute in an agarose matrix. The agarose plate method was also adopted to measure levels of FIX antigen (IX:Ag) in plasma. Using this technique, 12 of 17 obligate carriers of haemophilia B demonstrated reduced levels of IX:Ag. Three of the five carriers with normal IX:Ag levels were members of kindred in which affected individuals had normal or near normal levels of IX:Ag.