Synthesis and Release of Factor VIII by Cultured Human Endothelial Cells

Endothelial cells (ECs) derived from human umbilical veins were cultured in order to study the physiological control of factor VIII synthesis and release. The culture media were studied from multiple replicate cultures at confluence. Factor VIII related antigen (VIIIR:Ag) and factor VIII coagulant antigen (VIII:CAg) were measured by sensitive immunoradiometric assays. De novo synthesis of factor VIII related protein (VIII:R) was quantitated by incorporation of labelled amino acids into specific protein subunits. The following agents were added to the culture medium in a range of concentrations from physiological to pharmacological: adrenaline, 5 hydroxytryptamine, 2,3-DPG, cyclic AMP, thyroxine, hydrocortisone, and human growth hormone. None of them had any effect at any concentration on the rate of accumulation of VIIIR:Ag in the culture medium. Addition of exogenous factor VIII had no effect on do novo synthesis of VIII:R. VIII:CAg was found to be stable under the conditions of culture but none was released from the ECs. Long-term monocyte cultures also failed to release VIII:CAg. It appears that VIII:R is a constitutive gene product of umbilical vein endothelial cells and that VIII:CAg is not made by these cells.     

Simplified immunoradiometric assay for factor VIII coagulant antigen

A simplified, non-competitive, solid phase immunoradiometric assay has been developed for the quantitation of factor VIII coagulant antigen (VIII:CAg)--the antigenic counterpart of FVIII coagulant activity (VIII:C). Both homologous and heterologous antibodies to human factor VIII (FVIII) were used in this assay. Initially, FVIII in a test sample was attached to immobilized, human IgG obtained from a polytransfused haemophilia A patient with a high titre antibody to VIII:C. The bound FVIII was then detected using rabbit 125I-IgG specific for human FVIII. The concentration of VIII:CAg correlated well with VIII:C levels in the plasma from normal donors (r = 0.84, n - 15). Homozygote von Willebrand's disease patients had undetectable levels of VIII:CAg in their plasma. Patients with severe haemophilia A (VIII:C less than 0.01 u/ml) could be divided into groups on the basis of the VIII:CAg levels, i.e. those having undetectable VIII:CAg and other with measurable VIII:CAg. VIII:CAg detected in normal serum was less than 0.002 u/ml. In this assay the use of human antibody to FVIII is considerably decreased compared to other methods for VIII:CAg, and the time-consuming steps to immunopurify human anti-FVIII antibody are eliminated.     

Absence of anamnestic response after transfusion of washed red blood cells in haemophilia A patients with antibody to factor VIII

Washed red blood cells (WRC) have been used for replacing the blood loss in haemophilia A patients with antibody to Factor VIII. Levels of VIII coagulant activity (VIII:C), VIII coagulant antigen (VIII:CAg) and VIII related antigen (VIIIR:Ag) have been measured during the different steps of the preparation of WRC. The amount of VIII:CAg decreases very rapidly after washing and both are undetectable in the final product. These results were correlated with the absence of anamnestic response in 10 haemophilia A patients with inhibitor known as high responders.     

Heterogeneity of autoantibodies to factor VIII: differences in specificity for apparently distinct antigenic determinants of factor VIII coagulant protein

The interference of antibodies to factor VIII coagulant protein (VIII:C) of 9 nonhemophilic patients with the binding to factor VIII coagulant antigen (VIII:CAg) of a reference hemophilic 125I-Fab' reagent, used in a liquid phase VIII:CAg assay, was studied. The binding competition was estimated from immunoradiometric assay (IRMA) dose-response slope of VIII:CAg present in patient plasma, interference of antibodies with the 125I-Fab' binding to VIII:CAg in normal plasma, and the displacement of antibody from the complexes with VIII:CAg by the 125I Fab'. Antibody populations from three patients were studied in detail; in the VIII:CAg assay, two of them interfered with the 125I- Fab' binding, and one did not (patient 1). The formation of stable complexes between antibodies of each patient and VIII:CAg was demonstrated by protein-A-Sepharose adsorption. The 125I-Fab' binding to VIII:CAg-anti-VIII:CAg IgG complexes indicated that patient 1 antibodies and the 125I-Fab' recognized different antigenic determinants, whereas the other two patient antibodies and 125I-Fab' recognized closely related or identical VIII:CAg determinants. These results demonstrate an apparently selective recognition of at least two distinct VIII:CAg determinants by naturally occurring antibodies, suggesting a possibility of a wider use of these antibodies in studies of the structure and function of factor VIII.     

The role of the spleen in regulating the plasma levels of factor VIII-- von Willebrand's factor after DDAVP

Organ transplantation and perfusion studied indicate that the spleen plays an important role in the regulation of plasma levels of factor VIII-von Willebrand's factor (FVIII-vWF). To better understand the mechanisms that regulate the FVIII-vWF increases after infusion of 1- deamino-8-D-arginine vasopressin (DDAVP), we have measured factor VIII coagulant activity (FVIII:C) and antigen (FVIII:CAg) and von Willebrand's factor antigen (vWF:Ag) and ristocetin cofactor (vWF:RCof) in 9 asplenic subjects with normal baseline concentrations, in 7 asplenic subjects with high concentrations, and in 14 normal controls with intact spleens. In "normal" aasplenics, all the FVIII-vWF-related measurements increased significantly over baseline values, indicating that responsiveness to DDAVP is not abolished by splenectomy. The maximal vWF:Ag and vWF:RCof responses were no different from those of normal controls, suggesting that DDAVP releases vWF from storage sites other than the spleen. The FVIII:C response was significantly lower than in normal controls, but FVIII:CAg did not differ, making FVIII:CAg higher than FVIII:CAg in "normal" asplenics. These findings suggest that the spleen, rather than being a storage site for FVIII, is the organ in which a partially inactive form of FVIII acquires full coagulant activity. In "high" asplenics, all the FVIII-vWF-related measurements increased less than in "normal" splenics, indicating that long-term elevations of plasma concentrations of FVIII-vWF are accompanied by decreased release from those storage pool(s) mobilized by DDAVP.     

Response to infusions of polyelectrolyte fractionated human factor VIII concentrate in human haemophilia A and von Willebrand's disease

S ummary . Factor VIII was purified from cryoprecipitate by ion exchange chromatography on solid phase polyelectrolyte E-5 (PE-E5). The product was highly purified (3.5 u VIII: C/mg protein) compared to conventional concentrate (0.3 u VIII: C/mg protein) with low fibrinogen, low isoagglutinin titre, and a ratio of factor VIII coagulant activity (VIII: C) to factor VIII related antigen (VIIIR: Ag) of 16:1.
Trial infusions of this material (PE VIII) were given to three patients with severe haemophilia A and one patient with homozygous von Willebrand's disease. These patients also each received separate infusions of intermediate purity concentrate (IPC) for comparison. There were no adverse effects. The mean half life of VIII: C after PE VIII infusion in the haemophiliacs was 10.9 h and after IPC was 12.1 h, a statistically insignificant difference. The survival of factor VIII coagulant antigen (VIII:CAg) was similar to that of VIII:C. In contrast, the half life of VIII:C and of VIII:CAg was very short after infusion of PE VIII in the patient with von Willebrand's disease (2.4 h). IPC when infused in this patient produced a typical secondary rise of VIII:C. Two bleeding episodes in severe haemophiliacs were satisfactorily treated with PE VIII. PE-E5 deserves further study as a means of preparing clinical concentrates of factor VIII.     

Distribution of plasma fibronectin (cold-insoluble globulin) and components of the factor VIII complex after heparin-induced precipitation of plasma

Factor VIII procoagulant (VIII:C) activity, factor VIII coagulant antigen (VIII:CAg), von Willebrand ristocetin cofactor (VIIIR:RC) activity, factor VIII-related antigen (VIIIR:Ag), and plasma fibronectin (CIg; cold-insoluble globulin) were measured in the heparin precipitable fraction (HPF) and heparin supernatant fraction (HS) of normal human plasma. Following heparin induced precipitation, most measurable VIII:C activity (77% +/- 24%) was recovered in the HS. Although there was little VIII:C activity (less than 1%) in the HPF, 20% +/- 6.5% VIII:CAg was present as well as CIg (81% +/- 5.6%). VIIIR:RC activity (72% +/- 12%), and VIIIR:Ag (34 +/- 5.2%). As assessed by Na dodecyl SO4 glyoxyl agarose electrophoresis, the multimeric forms of plasma VIIIR:Ag could be resolved into a series of bands. Larger multimers tended to precipitate with the HPF whereas the smaller multimers tended to remain supernatant. Plasma from a subject with congenital afibrinogenemia was also studied. Although the afibrinogenemic HPF contained CIg, neither VIIIR:RC activity nor VIIIR:Ag was precipitated. However, both were present in the HPF from afibrinogenemic plasma to which fibrinogen had been added, suggesting that they are incorporated in this precipitate because of an affinity for fibrinogen. The ability of heparin to induce precipitation of CIg while leaving most VIII:C activity in the supernatant plasma may be useful in the preparation of procoagulant-rich plasma subfractions, since VIII:C can subsequently be recovered in good yield by cryoprecipitation.     

Effects of growth hormone on the factor VIII complex in patients with growth hormone deficiency

Factor VIII activity (VIII C), factor VIII coagulant antigen (VIII C:Ag), factor VIII-related antigen (VIII R:Ag), Ristocetin cofactor (R:Cof), and growth hormone were studied in eight children with growth hormone deficiency prior to, and 60, 120, and 180 minutes after administration of human growth hormone (Crescormone, Kabi), 4 U/m2. Growth hormone has been administered for 1.0 to 6.8 years but was stopped one week prior to this investigation. Basal levels of VIII C, VIII C:Ag, VIII R:Ag, and R:Cof were within the normal limits. After administration of human growth hormone, VIII C, VIII C:Ag, VIII R:Ag, and R:Cof showed a significant rise. Our study shows that growth hormone is not necessary to maintain the basal levels of the factor VIII complex within the normal limits. However, out data suggest that growth hormone has some influences on the levels of the factor VIII complex. The mechanisms for the rise of the factor VIII complex--whether this is a direct effect of growth hormone or not--are not clear at this point.     

Human factor VIII: a calcium-linked protein complex

The possible role of Ca2+ as an essential constituent part of the human factor VIII complex has been investigated by stability studies, metal determinations, and gel filtration experiments. In citrated plasma, the factor VIII coagulant activity (VIII:C) deteriorated during storage in a biphasic manner. Collection of blood in heparin, instead of chelating anticoagulants, or neutralization of citrate by addition of CaCl2 to heparinized citrate phosphate dextrose (CPD) plasma rendered VIII:C noticeably stable. At physiologic levels of ionized calcium, VIII:C was almost completely stable during incubation of plasma for 6 hr at 37 degrees C. The influence of other divalent ions was also studied. Highly purified factor VIII complex was subjected to atomic absorption spectrophotometric analysis and found to contain about 1.0 mole calcium per 220,000 daltons. This intrinsic calcium could be readily removed by EDTA. When heparin plasma and CPD plasma were chromatographed on Sepharose CL-6B at 37 degrees C, all the factor-VIII-related activities eluted together as large protein complexes. In contrast, factor VIII coagulant antigen (VIII:CAg) and factor-VIII-related antigen (VIIIR:Ag) were completely dissociated upon exposure to EDTA. From these observations it is concluded that human factor VIII circulates in normal plasma as a calcium-linked protein complex.     

Coagulation Factors in the Human Fetus of about 20 Weeks of Gestational Age

S ummary In plasma samples of 11 fetuses of about 20 weeks of gestational age the following coagulation factors have been determined (mean values found are given in parentheses): fibrinogen (0·30 U/ml), prothrombin (±0·17 U/ml), factor V (0·28 U/ml), factor VII (0·21 U/ml), factor VIII coagulant activity (factor VIII:C) (0·12 U/ml), factor VIII-related antigen (factor VIIIR:Ag) (1·04 U/ml), coagulant factor VIII-related antigen (factor VIII:CAg) (0·19 U/ml), factor IX coagulant activity (0·05 U/ml), factor IX antigen (≤0·03 U/ml), factor X (0·19 U/ml) and antithrombin III (AT-III) (0·23 U/ml).
Our data support the evidence that prenatal diagnosis of haemophilia A is at present possible; less optimism is warranted where haemophilia B is concerned. The number of samples is sufficient to establish normal values for the age group.
Means of quality control of the sample—which is often difficult to obtain—are discussed.     

The Release of Plasminogen Activator and Factor VIII after Injection of DDAVP in Healthy Volunteers and in Patients with von Willebrand's Disease

Increases in plasma concentrations of VIII:C, VIII:CAg, VIIIR:Ag and plasminogen activator (PA) were observed in 50 healthy volunteers given i.v. injections of DDAVP (desaminocys¹-8-D-arg-vasopressin). The PA activity reached its maximum immediately after the injection, VIII:C, VIII:CAg and VIIIR:Ag after 3040 min. However, a positive correlation was found when the PA and VIII:C responses in each of the normals were analysed. DDAVP was also administered to 3 patients with severe von Willebrand's disease. 2 of the patients displayed no changes in VIII:C, VIII:CAg, VIIIR:Ag or VIIIR:RCF and there was no increase in PA. The third patient responded with an increase in VIII:C and to a minor degree in VIII:CAg. This patient developed fibrinolytic activity, but in the lower normal range. In 3 other patients with mild von Willebrand's disease DDAVP caused increases in VIII:C, VIII:CAg, VIIIR:Ag and PA. We feel that the combined data may support the concept that one and the same target cell is involved in the DDAVP mediated release of factor VIII related activities and PA.     

Changes in coagulation parameters with exercise in patients with classic hemophilia

Vigorous exercise is known to increase VIII:C and VIIIR:Ag levels transiently in normal individuals. Although exercise programs are frequently advocated in the management of hemophilia, the effects of exercise on coagulation parameters in these patients have not been well studied. Eleven hemophiliacs were exercised on a bicycle ergometer to maximum voluntary effort as evidenced by an increase in pulse, blood pressure, and plasma catecholamine (norepinephrine and epinephrine) levels. The effects of this exercise on coagulation parameters, including functional and antigenic components of the factor VIII molecule, were determined. The entire group demonstrated a decrease in mean prothrombin time (11.7 to 11.2 sec). Four mild hemophiliacs demonstrated an increase in mean VIII:C (14.5% to 17.3%), and VIII:CAg (12% to 17.8%). Changes in VIII:C and VIII:CAg were not noted in the seven severe hemophiliacs. Both severe and mild patients demonstrated significant changes in fibrinogen, factor II, and factor VII after exercise. This study indicates that submaximal exercise modifies coagulation parameters in patients with hemophilia.     

Studies on the stability of factor VIII coagulant antigen (VIII: CAg) in the presence of VIII: C antibodies

S ummary . The stability of factor VIII coagulant antigens (VIII:CAg) at 56°C was investigated using an immunoradiometric assay for VIII: CAg. In normal or CRM⁺ haemophilic plasmas VIII: CAg was rapidly inactivated at 56°C. VIII: CAg in spontaneous VIII: C inhibitor plasmas and in post-treatment samples from haemophiliacs with VIII: C inhibitor was resistant to inactivation at 56°C, indicating the presence of heat stable VIII: CAg-anti VIII: CAg complexes.
In vitro VIII: CAg-anti VIII: CAg complexes were formed by incubation of diluted VIII: C antibodies and normal plasma and the stability of these complexes at 56°C was studied. Haemophilic VIII: CAg antibodies formed heat stable immune complexes over a narrow range of inhibitor dilutions whilst some spontaneous VIII: CAg antibodies formed these stable complexes over a much wider range of dilutions emphasizing the difference in the properties of these antibodies.     

The effect of liver disease on factors V, VIII and protein C

The components of the factor VIII complex were estimated by immuno- and bioassays in 85 patients with liver disease. The plasma concentrations of the antigens were elevated in 65% (VIII:CAg) and in 76% (VIIIR:Ag) of patients while the biological activities were elevated in only 14% (VIII:C) and 15% (VIII:RiCof). There was no correlation with C-reactive protein, used as a measure of an acute phase reaction (X2 = 0.7; P = 0.1); or with severity of liver disease as judged by prothrombin ratio (P = 1.0) but highest values were observed in patients with cholestatic liver disease. Following parenteral vitamin K there was a significant fall in both the biological activity of VIIIC (36%) and of VIII:CAg (38%) in 13 vitamin K deficient patients (P less than 0.001) but no change in 23 vitamin K replete patients or in the VIIIR:Ag levels in either group. Factor V levels were lower in patients with parenchymal liver disease (0.54 +/- 0.1 units/ml, mean +/- SEM, n = 12; normal range 0.5-1.5 units/ml) than in patients with extrahepatic cholestasis who were vitamin K deficient (1.2 +/- 0.1 units/ml, P less than 0.0001). The levels of protein C antigen, the vitamin K dependent protease which inactivates factors VIII:C and V, was at the lower end of the range in both groups (0.7 +/- 0.1, mean +/- SEM, n = 18, normal range 0.74-1.4 units/ml). There was no significant change in either protein C antigen or factor V following vitamin K. The discrepancy between the biological activity of factor VIII and the antigen levels could represent accumulation of partially degraded factor VIII or production of a hypoactive form. There is no evidence that the reduction in VIIIC and VIII:CAg following vitamin K was mediated by protein C.     

The Effect of Storage of Whole Blood on the Association of Factor VIII-Related Antigen and Factor VIII-Coagulant Antigen

To evaluate the extent of denaturation of factor VIII-coagulant activity (VIII:C) during production of factor VIII concentrates, the factor VIII-coagulant antigen (VIII:CAg)/VIII:C ratio was measured in plasma, cryoprecipitate and cryosupernatant from fresh and stored blood. This ratio was close to unity for both cryoprecipitate and other concentrates, suggesting that VIII:CAg is lost concurrently with VIII:C during cryoprecipitation and further fractionation. Storage of blood (18 h, 22°C) before processing resulted in a 30% loss of VIII:C from the separated plasma; however, VIII:CAg was not affected. In cryoprecipitate prepared from this plasma, VIII:C and VIII:CAg both were 30% lower than when prepared from fresh plasma. In the corresponding cryosupernatant, however, more VIII:CAg but less VIII:C was present compared with fresh material. Gel chromatography revealed that the rise of VIII:CAg in cryosupernatant prepared from stored blood, was due to an increased amount of VIII:CAg of low molecular weight, not being associated with factor VIII-related antigen. Such an increase in dissociated VIII:CAg was not detected in the plasma prior to cryoprecipitation. It is concluded that during storage of blood, molecular changes are induced in the factor VIII-VWF complex, possibly by limited proteolysis, which make the complex more liable to dissociation during subsequent cryoprecipitation.     

The combined use of monoclonal antibody- based enzyme-linked immunosorbent assays (ELISA) for factor VIII antigen (VIII: Ag) and von Willebrand factor antigen (vWF: Ag) for the detection of carriers of haemophilia A

Enzyme-linked immunosorbent assays (ELISA) for factor VIII antigen (VIII: Ag) and von Willebrand factor antigen (vWF: Ag) have been developed, each employing monoclonal antibodies. In the majority of severe haernophilic plasmas tested, VIII: Ag was undetectable by ELISA and also by immunoradiometric assay (IRMA) using haemophilic VIII:C antibodies. In haemophilic plasmas with mild/moderate deficiency of coagulant factor VIII (VIII: C), there was no significant difference between the two immunoassays although there was a general trend for ELISA VIII: Ag results to be higher. Assay of von Willebrand's disease (vWd) plasmas with the ELISA for vWF: Ag demonstrated reduced levels of this antigen in type I vWd, normal levels in type IIA, and a severe reduction of vWF:Ag in type III vWd. The discrimination of obligate carriers of haemophilia from normal was determined using ratios of factor VIII/vWF. Factor VIII antigen/von Willebrand factor antigen measured by IRMA and Laurell immunoelectrophoresis respectively, gave a superior discriminant to that of VIII: C/vWF: Ag (Laurell), but optimal discrimination was obtained with the combination of ELISAs for VIII: Ag and vWF: Ag.     

Characteristics of the Factor VIII Protein and Factor XIII in Various Factor VIII Concentrates

The in vitro properties of 5 factor VIII preparations (AHF-Kabi, Hemofil Hyland, AHF-Profilate Abbott, Kryobulin Immuno and Factorate High Purity Armour) and an ordinary cryoprecipitate were studied with reference to factor VIII clotting activity (VIII:C), factor VIII clotting antigen (VIILCAg), factor VIII related antigen (VIIIR:Ag) (EI, IRMA, CIE), ristocetin cofactor activity (VIIIR:RCF), fibrinogen and factor XIII. All the preparations with the exception of Factorate had higher levels of VIII:CAg than VIII:C indicating inactivation of the biological activity of VIII:C during the procedure. AHF-Kabi (fraction I-0) and the cryoprecipitate, the only preparations capable of normalising the defect in patients with von Willebrand's disease, showed the same level of VIIIR:Ag determined by EI and by IRMA, while all the other preparations (i.e. cryoprecipitates purified further in different ways) had considerably lower levels of VIIIR:Ag determined by IRMA than by EL Based on these in vitro techniques it seems to be possible to predict which preparations can be used successfully in patients with von Willebrand's disease, while no such conclusions can be made from VIIIR:RCF determinations. EI yielded similar concentrations of factor XIII a subunit in all the preparations tested. 3 functional assays showed high factor XIII activities in AHF-Kabi but low or no activities in the others. Thus, considerable differences were found of the in vitro properties of the proteins in 5 factor VIII concentrates and a cryoprecipitate. The action of proteases and the techniques used in the purification procedure are probably of crucial importance for the properties of the various factors.     

Factor VIII:C and VIII:CAg Response in Patients with Haemophilia A and von Willebrand's Disease after Administration of Different Factor VIII Concentrates or Plasma

S ummary . Factor VIII procoagulant activity (VIII:C) and factor VIII procoagulant antigen (VIII:CAg) were studied in seven patients with haemophilia A after administration of three different factor VIII concentrates or plasma. The in vivo recovery of VIII:CAg was less than that of VIII:C and the disappearance rate of VIII:CAg was much higher either when concentrates or plasma were given. The half-life of VIII:C was thus about 12 h but of VIII:CAg only about 3 h or less. Six patients with von Willebrand's disease were studied after administration of AHF- Kabi. In contrast to haemophilia A the discrepancy between VIII:C and VIII:CAg disappearance rates was not present in von Willebrand's disease, since both VIII:C and VIII:CAg showed a typical progressive increase. We conclude that factor VIII:C given to haemophilia patients does not behave like native VIII:C, not even when fresh plasma is used. Patients with von Willebrand's disease are capable of forming a normal VIII:C when appropriately stimulated.     

The combined use of monoclonal antibody-based enzyme-linked immunosorbent assays (ELISA) for factor VIII antigen (VIII:Ag) and von Willebrand factor antigen (vWF:Ag) for the detection of carriers of haemophilia A

Enzyme-linked immunosorbent assays (ELISA) for factor VIII antigen (VIII:Ag) and von Willebrand factor antigen (vWF:Ag) have been developed, each employing monoclonal antibodies. In the majority of severe haemophilic plasmas tested, VIII:Ag was undetectable by ELISA and also by immunoradiometric assay (IRMA) using haemophilic VIII:C antibodies. In haemophilic plasmas with mild/moderate deficiency of coagulant factor VIII (VIII:C), there was no significant difference between the two immunoassays although there was a general trend for ELISA VIII:Ag results to be higher. Assay of von Willebrand's disease (vWd) plasmas with the ELISA for vWF:Ag demonstrated reduced levels of this antigen in type I vWd, normal levels in type IIA, and a severe reduction of vWF:Ag in type III vWd. The discrimination of obligate carriers of haemophilia from normal was determined using ratios of factor VIII/vWF. Factor VIII antigen/von Willebrand factor antigen measured by IRMA and Laurell immunoelectrophoresis respectively, gave a superior discriminant to that of VIII:C/vWF:Ag (Laurell), but optimal discrimination was obtained with the combination of ELISAs for VIII:Ag and vWF:Ag.     

Analysis of factor VIII coagulant antigen in normal, thrombin-treated, and hemophilic plasma.

The relationship between Factor VIII coagulant antigen (VIII:CAg) and Factor VIII-associated von Willebrand factor (VIII:vWF), and the effect of thrombin on VIII:CAg have been determined in plasma by using complexes of VIII:CAg and 125I-labeled human anti-VIII:CAg-Fab. Antibody-treated plasma samples were electrophoresed on NaDodSO4/polyacrylamide agarose gels and analyzed by autoradiography. The major VIII:CAg-125I-labeled Fab complex that persisted in NaDodSO4 had Mr 3.2 x 10(5). This Mr value was confirmed by column chromatography and sucrose density centrifugation and is presumed to reflect a free VIII:CAg of Mr 2.7 x 10(5). Minor bands were also present on autoradiograms of normal plasma corresponding to Mr values of 2.5, 1.85, and 1.7 x 10(5) (free VIII:CAg related proteins with Mr values of 2.0, 1.35, and 1.2 x 10(5), respectively). None of the VIII:CAg bands was present in plasma samples from five patients with severe hemophilia A. No radioactivity was associated with VIII:vWF multimers on NaDodSO4 gels. Thrombin treatment of normal plasma eliminated the radioactive band at 3.2 x 10(5) and increased the intensity of a band of Mr 1.7 x 10(5). Generation of this presumed VIII:CAg fragment of Mr is approximately equal to 1.2 x 10(5) coincided with a thrombin-induced increase in Factor VIII coagulant activity. These data demonstrate that the form of VIII:CAg detected in normal plasma is not covalently linked to VIII:vWF multimers and is absent in plasma from five hemophilia A patients. Thrombin-induced proteolysis of VIII:CAg can be detected in microliter quantities of normal plasma.