Survival of 125iodine-labeled Factor VIII in normals and patients with classic hemophilia. Observations on the heterogeneity of human Factor VIII.

Radiolabeled human Factor VIII was used to study its survival in normals and patients with classic hemophilia, and to study the heterogeneity of Factor VIII; Purified Factor VIII was radiolabeled with 125iodine (125I-VIII) without loss of its structural integrity. The survival of 125I-VIII was studied in six normals and six hemophiliacs of whom four of the hemophiliacs had received transfusions with normal cryoprecipitate before the 125I-VIII infusion. No significant difference was observed between the disappearance of Factor VIII coagulant activity and radioactivity in these hemophiliacs. 125I-VIII in plasma showed a biphasic disappearance with an average t1/2 of 2.9 +/- 0.4 h (SEM) for the first phase and 18.6 +/- 0.7 h (SEM) for the second phase, respectively. The survival of 125I-VIII was similar comparing normals and hemophiliacs. The highest molecular weight forms of Factor VIII disappear more rapidly than the lower molecular weight ones. This was established by analysis of the fractions obtained by gel chromatography of plasma collected at several times after infusion and by analysis of the in vivo disappearance of three subfractions of Factor VIII. The fraction of 125I-VIII binding to platelets in the presence of ristocetin (containing the highest molecular weight forms of Factor VIII including the ristocetin cofactor) represented about 50% of the radioactivity present in plasma after infusion and showed a t 1/2 of 11.7 +/- 0.9 h (SEM) for the second phase. The fraction, which was recovered in cryoprecipitate of the recipient's plasma, represented about 90% of the initial radioactivity and showed a t 1/2 of 16.3 +/- 0.8 h (SEM) for the second phase. The fraction of 125I-VIII remaining in the cryosupernatant plasma (containing low molecular weight forms of Factor (VIII) showed a t 1/2 of 27.2 +/- 1.1 h (SEM). The first phase of the disappearance of 125I-VIII is caused in part by the disappearance of the highest molecular weight forms, which are possibly removed by the reticuloendothelial system.

Human factor VIII: purification from commercial factor VIII concentrate, characterization, identification and radiolabeling.

Human factor VIII was purified from commercial factor VIII concentrate with a 12% yield. The specific coagulant activity of purified factor VIII was 8,000 units/mg. In the presence of SDS the purified factor VIII consisted of a variety of polypeptides on polyacrylamide gels, ranging between Mr 80,000 and Mr 208,000. In the absence of SDS the purified factor VIII showed an apparent molecular weight of 270,000 upon Sephadex G200 gel-filtration. The purified factor VIII could be activated by thrombin, which resulted in the disappearance of Mr 108,000-208,000 polypeptides in favor of an Mr 92,000 polypeptide. Treatment with factor Xa also activated factor VIII, whereas treatment with activated protein C resulted in the inactivation of coagulant activity. Coagulant-active 125I-factor VIII was prepared using a lactoperoxidase radioiodination procedure. This 125I-factor had the same characteristics as unlabeled factor VIII. All polypeptides could be precipitated with monoclonal antibodies directed against factor VIII. With 125I-factor VIII a pIapp of 5.7 was found in the presence of urea.

The effect of thrombin on the complex between factor VIII and von Willebrand factor.

Purified human factor FVIII (FVIII; 6000-8000 U/mg) was radiolabeled and bound to immobilized von Willebrand factor (vWF). The complex was incubated with human thrombin. Thrombin induced a release of 65% of the radioactivity initially bound. Released FVIII fragments and fragments remaining bound during incubation with thrombin were analyzed using gel electrophoresis. This led to the following observations. Released fragments largely consisted of Mr-70000 and Mr-50000 fragments; Mr-90000 and Mr-80000 fragments were only found in the fractions remaining bound to vWF and decreased with time. In contrast to these digestion products of FVIII, the Mr-42000 heavy-chain fragment remained bound to vWF, comprising the larger part of the radioactivity after a 2-h incubation. No thrombin-induced cleavages were observed in vWF. Furthermore, vWF-coated wells preincubated with thrombin were still able to bind 125I-FVIII. These results implicate a new concept for the activation of vWF-bound FVIII. Activation is a multistep process in which several cleavages are necessary to produce and release a coagulant-active FVIII molecule (FVIIIa), which is probably an Mr-50000/70000 heterodimer. Inactivation of FVIIIa is likely to be the result of a nonproteolytic dissociation due to loss of the joining divalent cation(s).

Adhesion of platelets to human artery subendothelium: effect of factor VIII-von Willebrand factor of various multimeric composition.

The relationship between the multimeric size of factor VIII-von Willebrand factor (FVIII-vWF) and the support of platelet adhesion to subendothelium was studied in an annular perfusion chamber, employing human renal and umbilical arteries. Commercial factor VIII concentrates containing multimers of low molecular weight that had been shown not to correct the bleeding time upon infusion into patients with von Willebrand's disease did not support platelet adhesion in the perfusion chamber. Cryoprecipitate and two experimental FVIII-vWF concentrates containing multimers of high molecular weight supported platelet adhesion. Factor VIII-vWF purified from cryoprecipitate was subdivided into three fractions of different molecular weights (6.0-14.0, 4.0-9.0, and 3.0-7.5 X 10(6) dalton). These fractions appeared to bind equally well and to be equally effective in supporting platelet adhesion. Factor VIII-vWF with multimers of low molecular weight (0.5-1.5 X 10(6) dalton) were prepared by partial reduction. Binding of FVIII-vWF to subendothelium was not impaired, and the support of platelet adhesion appeared to be more resistant to the effect of reduction than the ristocetin cofactor activity. At high shear rate (2,500 sec-1), increased platelet adhesion was observed with partially reduced FVIII-vWF. These data indicate that the ability of FVIII-vWF preparations to correct the bleeding time is reflected in enhanced platelet adhesion to subendothelium in a perfusion chamber. These data also emphasize that multimeric size is not the only factor determining whether FVIII-vWF will support platelet adhesion.

Characterization of human factor VIII and interaction with von Willebrand factor. An electron microscopic study.

Blood coagulation factor VIII is a large glycoprotein that circulates in plasma at relative low concentration (0.1 microgram/ml). It consists of a heterogeneous mixture of a series heavy-chain peptides (90-200 kDa), each associated with a light chain of 80 kDa. To gain insight into the physical properties of the protein, we have characterized purified human factor VIII by electron microscopy and rotary shadowing. Electron microscopy of rotary shadowed factor VIII molecules showed predominantly a single globular domain structure, with a somewhat asymmetric shape, while two-domain structures were also encountered. The overall dimensions of the globular domains ranged from 4 x 6 nm to 8 x 12 nm. EDTA treatment of factor VIII reduced the overall dimensions (2.5 x 5 nm to 6 x 10 nm) while treatment with thrombin reduced the dimensions to a small extent. In complexes with von Willebrand factor, factor VIII appeared localized at the globular domains of von Willebrand factor multimers. In addition, incubation of factor VIII with Staphylococcus aureus V8 protease fragments SpII and SpIII revealed only binding to the globular domains of SpIII. In this study, the first morphological characterization of human factor VIII is presented, together with its direct localization on von Willebrand factor multimers.

The effect of von Willebrand factor on activation of factor VIII by factor Xa.

Factor VIII has to be activated before it can serve efficiently as a cofactor in the intrinsic pathway of blood coagulation. This activation occurs through specific proteolytic cleavages in the molecule by either thrombin or factor Xa. In this study, we show that von Willebrand factor inhibits the activation of factor VIII by factor Xa. Incubation of factor VIII (30 U/ml) with 0.1 microgram/ml factor Xa resulted in a 1.6-fold activation followed by a decay of coagulant activity. In the presence of 10 micrograms/ml von Willebrand factor, activation and inactivation of factor VIII was completely inhibited. In contrast, the activation of factor VIII by thrombin was not influenced by von Willebrand factor. At high concentrations of factor Xa (10 micrograms/ml), von-Willebrand-factor-bound factor VIII could be cleaved and activated. The generated proteolytic fragments were identical to the fragments produced in the absence of von Willebrand factor and all fragments were released from von Willebrand factor. The major products were light-chain-derived fragments of molecular mass 66/68 kDa and 60 kDa and heavy-chain-derived fragments of 40 and 42 kDa. Also minor products of 12, 20/21, 23, 27 and 30 kDa were observed, most of which were specific for cleavage of factor VIII by factor Xa.

Factor VIII binds to von Willebrand factor via its Mr-80,000 light chain.

The formation of a complex between factor VIII (FVIII) and von Willebrand factor (vWF) was studied using purified radiolabeled human FVIII and purified human vWF. A binding assay was developed in which vWF was coated on microtiter wells. FVIII was shown to bind specifically and reversibly to the immobilized vWF. At a coating of 70 pg vWF/well, binding was half-maximal at a FVIII concentration of 70 +/- 10 pM. In order to ascertain which part of FVIII interacted with vWF, eight monoclonal antibodies, directed against FVIII, were tested for their ability to inhibit FVIII-vWF interaction. One of the eight antibodies, CLB-CAg:58, inhibited binding completely. This antibody was demonstrated to react with the Mr-80,000 light chain of FVIII. Direct evidence for the involvement of this chain in vWF binding was obtained by studying the binding of isolated, radiolabeled FVIII heavy and light chains. In a typical experiment 23-30% of the radioactivity bound when the FVIII light chain was added and less than 1% when the FVIII heavy chain was added.