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.

Inhibition of human blood coagulation factor XIa by C-1 inhibitor.

The inactivation of activated factor XI (factor XIa) and of its isolated light chain by C-1 inhibitor was studied. Irreversible inhibition was observed in a reaction in which no reversible enzyme-inhibitor complex was formed. The second-order rate constants for the inactivation of factor XIa or its light chain by C-1 inhibitor were 2.3 X 10(3) and 2.7 X 10(3) M-1 s-1, respectively. High molecular weight kininogen did not affect the rate of inactivation. The nature of the complexes formed between factor XIa or its light chain and C-1 inhibitor was studied by using sodium dodecyl sulfate gradient polyacrylamide slab gel electrophoresis. Under nonreducing conditions, two factor XIa-C-1 inhibitor complexes were observed with apparent molecular weights of 230,000 and 300,000. Reduction of these complexes resulted in the formation of a single band with a molecular weight of 130,000. This band is also formed in the reaction of the isolated light chain of factor XIa with C-1 inhibitor. These results demonstrate that two C-1 inhibitor molecules can become bound to the light chains of a factor XIa molecule. In addition, the mechanism of interaction of factor XIa or its isolated light chain with C-1 inhibitor appears identical, and the rate of inactivation of the enzyme by C-1 inhibitor is very similar. Neither the heavy chain of factor XIa nor high molecular weight kininogen is significantly involved in the inactivation of factor XIa by C-1 inhibitor.

Immunologic studies of human coagulation factor XI and its complex with high molecular weight kininogen.

Coagulation factor XI was purified from human plasma using ion-exchange chromatography and affinity chromatography on high molecular weight kininogen-Sepharose. A monospecific precipitating antiserum was prepared and used to study factor XI antigen. Factor XI did not migrate during electrophoresis at pH 8.3. High molecular weight kininogen (HMWK), an alpha globulin, reversibly associates with factor XI. Complex formation between HMWK and factor XI was observed under conditions of crossed-immunoelectrophoresis. Using Laurell rocket immunoelectrophoresis, it was shown that the isolated alkylated light chain of kinin-free HMWK formed a complex with factor XI. In contrast to previous studies of prekallikrein, titrations of factor XI with increasing amounts of HMWK did not give a simple titration curve, suggesting that factor XI dissociates from the complex during electrophoresis. Prekallikrein and factor XI were shown to compete for the same HMWK molecules under the conditions of immunoelectrophoresis, and prekallikrein appeared to have a higher affinity for binding to HMWK than factor XI. Quantitative determinations of factor XI antigen in plasma by rocket immunoelectrophoresis were made. The average amount of factor XI measured in plasma samples from 20 normal individuals was 4.5 micrograms/ml (range 3-6). No factor XI antigen was detected in plasma from a patient deficient in factor XI. Normal factor XI antigen levels were detected in 3 different HMWK-deficient plasmas only if the plasmas were reconstituted with purified HMWK (2 U/ml). Addition of HMWK to normal plasma resulted in an increase of the factor XI antigen rocket. At HMWK levels of 2 U/ml, no further increase of the factor XI antigen rocket was observed. Therefore, accurate measurement of factor XI antigen by rocket immunoelectrophoresis is possible only if an excess of HMWK is present.

Identification of monoclonal antibodies that inhibit the function of protein C inhibitor. Evidence for heparin-independent inhibition of activated protein C in plasma.

Monoclonal antibodies specific for protein C inhibitor (PCI) partially blocked the inactivation of activated protein C (APC) in plasma, whereas in a purified system, the PCI activity could be completely blocked. The inactivation of APC in normal and in PCI-depleted plasma was similar in the absence of heparin. The addition of heparin did not change the rate of inactivation of APC in PCI-depleted plasma, whereas in normal plasma a rapid phase of inhibition of APC was followed by a slower phase of inhibition. The slower phase was identical to the rate of inhibition of APC in the absence of heparin. After incubation of normal plasma with a monoclonal antibody specific for PCI that blocked its activity, there was no difference in heparin-dependent or heparin-independent inhibition of APC. These results indicate that in the absence of heparin PCI is unable to inactivate APC in a plasma environment.

Heterogeneity of human factor VIII. III. Transitions between forms of factor VIII present in cryoprecipitate and in cryosupernatant plasma.

Human factor VIII in plasma is a disperse protein consisting of a series of aggregates wih different molecular weight. VIIR:Ag and VIII:C are present in all forms, but VIIR:WF is confined to the highest molecular weight forms only. After cryoprecipitation of plasma the latter are recovered in the precipitate, and the lowest molecular weight forms remain in the supernatant. Disaggregation of high molecular weight forms of factor VIII was found in vitro upon repeated cryoprecipitations. The disaggregation was detected only when the original low molecular weight forms were removed. The additional low molecular weight forms possessed VIII:C and VIIR:WF was lacking. The reverse process of aggregation of low molecular weight factor VIII to more highly aggregated forms was not observed. Exchange of VIII:C between high and low molecular weight fractions was demonstrated by gel chromatography of mixtures of hemophilic cryoprecipitate and normal concentrated cryosupernatant, and vice versa, at physiologic ionic strength. This suggests that VIII:C and VIIR:Ag are weakly and noncovalently linked in normal conditions. This was further supported by the dissociation of VIII:C from VIIIR:Ag and VIIIR:WF upon gel chromatography and cryoprecipitation at pH 6.2 The dissociation could be reversed by readjustment of the pH.

The contact activation mechanism in human plasma: activation induced by dextran sulfate.

Incubation of normal human plasma with dextran sulfate for 7 min at 4 degrees C generates kallikrein amidolytic activity. No kallikrein activity is generated in factor XII or prekallikrein-deficient plasma and only small amounts (8%) in high molecular weight (HMW) kininogen-deficient plasma. Addition of specific antisera directed against prekallikrein or HMW kininogen to normal plasma blocked the generation of kallikrein activity by dextran sulfate. Thus, factor XII, prekallikrein, and HMW kininogen are essential components for optimal activation of prekallikrein. The role of limited proteolysis in the activation of prekallikrein induced by dextran sulfate was studied by adding 125I-prekallikrein to plasma. The generation of kallikrein activity paralleled the proteolytic cleavage of prekallikrein as judged on SDS gels in the presence of reducing agents. The same cleavage fragments were observed as obtained by activation of purified prekallikrein by beta-factor-XIIa. Addition of 131I-HMW kininogen and 125I-factor XII or 131I-HMW kininogen and 125I-prekallikrein to normal plasma followed by activation with dextran sulfate and analysis on SDS gels indicated that the observed cleavage of prekallikrein and HMW kininogen is fast compared to the observed cleavage of factor XII, which is much slower and less extensive. During the first minutes of incubation of normal plasma with dextran sulfate, mainly alpha-factor-XIIa is formed. During prolonged incubation, beta-factor-XIIa is also formed.

The localization of heparin-binding fragments on human C4b-binding protein.

C4b-binding protein (C4BP) is a multimeric plasma protein, which regulates the classical pathway of the C system. C4BP interacts with C C4b on a domain located in a 48-kDa chymotryptic fragment. We now demonstrate that C4BP contains heparin-binding fragments, which are located within the C4b binding domain. We have used an assay using heparin coupled to Sepharose CL-6B to show that 125I-C4BP binds to heparin in a time-dependent, saturable, and reversible manner. Binding could be inhibited by purified 48-kDa fragments and direct binding on the 48-kDa fragments to heparin-Sepharose was demonstrated by SDS-PAGE. mAb against native C4BP and the isolated 160-kDa central core fragment were evaluated for their ability to block the binding of 125I-C4BP to heparin and C4b. The relative efficacy of mAb against intact C4BP in blocking C4BP binding to heparin-Sepharose was similar to that for blocking 125I-C4BP binding to C4b. In addition, heparin blocked the binding of 125I-C4BP to C4b and vice versa. It is therefore likely that the heparin-binding fragments are localized on or close to the C4b-binding site of C4BP.

Inactivation of human plasma kallikrein and factor XIa by protein C inhibitor.

The inhibition of kallikrein and factor XIa by protein C inhibitor (PCI) was studied. The method of Suzuki et al. [Suzuki, K., Nishioka, J., & Hashimoto, S. (1983) J. Biol. Chem. 258, 163-168] for the purification of PCI was modified in order to avoid the generation of proteolytic activity and subsequent inactivation of PCI. With the use of soybean trypsin inhibitor, an efficient inhibitor of kallikrein and factor XIa, the generation of proteolytic activity was avoided. The kinetics for the inactivation of activated protein C (APC), kallikrein, and factor XIa by PCI were determined. In the absence of heparin, no inactivation of APC was observed, in contrast to kallikrein and factor XIa, which are inhibited with second-order rate constants of (11 +/- 4) X 10(4) and (0.94 +/- 0.07) X 10(4) M-1 s-1, respectively. Addition of heparin potentiated the inhibition of APC [(1.2 +/- 0.2) X 10(4) M-1 s-1] and factor XIa [(9.1 +/- 0.7) X 10(4) M-1 s-1] by PCI, whereas the inhibition of kallikrein by PCI was unchanged [(10 +/- 1) X 10(4) M-1 s-1]. The second-order rate constants for the inhibition of kallikrein or factor XIa by PCI were similar to the second-order rate constants for the inhibition of their isolated light chains by PCI, indicating a minor role for the heavy chains of both molecules in the inactivation reactions. With sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis and immunoblotting, complex formation of APC, kallikrein, and factor XIa with PCI could be demonstrated. APC and kallikrein formed 1:1 molar complexes with PCI.(ABSTRACT TRUNCATED AT 250 WORDS)

Quantification of major peanut allergens Ara h 1 and Ara h 2 in the peanut varieties Runner, Spanish, Virginia, and Valencia, bred in different parts of the world.

BACKGROUND: The serology of peanut allergy seems to be different in various parts of the world. We analyzed the composition of 13 samples of three varieties of peanut in order to compare their allergenic nature. METHODS: Peanut cultivars that are commonly processed in the West were analyzed for protein content, protein composition, and Ara h 1 and Ara h 2 content by biochemical methods. IgE-binding properties were analyzed by ELISA using serum from patients with documented peanut allergy. RESULTS: Total protein contents were comparable for all tested samples (24-29%), and proteins were extractable to the same extent. SDS-PAGE patterns differed slightly, but all major bands were visible in all samples (molecular masses of approximately 14100 kDa under reducing conditions). Ara h 1 and Ara h 2 were quantified by SDS PAGE densitometry and were expressed as percentage of the total protein content. Ara h 1 was in the range 12-16%, whereas Ara h 2 was 5.9-9.3%. In view of the analytic uncertainty of this determination, the content of both Ara h 1 and Ara h 2 was not significantly different between the tested samples. In an IgE-binding inhibition ELISA, the affinities of the peanut proteins for peanut-specific IgE were measured. Minor differences were observed between the tested samples, with the most potent IgE-binding sample having a two times higher ability to bind IgE than the weakest IgE-binding sample. CONCLUSIONS: The results suggest that peanuts of different varieties and from different parts of the world contain similar proteins, including Ara h I and Ara h 2. Consequently, the IgE-binding properties are similar to a great extent. This indicates that differences in the serology of peanut allergy may not originate from differences in the allergen composition of the peanut.

Peanut allergen Ara h 3: isolation from peanuts and biochemical characterization.

BACKGROUND: Peanut allergen Ara h 3 has been the subject of investigation for the last few years. The reported data strongly depend on recombinant Ara h 3, since a purification protocol for Ara h 3 from peanuts was not available. METHODS: Peanut allergen Ara h 3 (glycinin), was purified and its posttranslational processing was investigated. Its allergenic properties were determined by studying IgE binding characteristics of the purified protein. RESULTS: Ara h 3 consists of a series of polypeptides ranging from approximately 14 to 45 kDa that can be classified as acidic and basic subunits, similar to the subunit organization of soy glycinin. N-terminal sequences of the individual polypeptides were determined, and using the cDNA deduced amino-acid sequence, the organization into subunits was explained by revealing posttranslational processing of the different polypeptides. IgE-binding properties of Ara h 3 were investigated using direct elisa and Western blotting with sera from peanut-allergic individuals. The basic subunits, and to a lesser extent the acidic subunits, bind IgE and may act as allergenic peptides. CONCLUSIONS: We conclude that peanut-derived Ara h 3, in contrast to earlier reported recombinant Ara h 3, resembles, to a large extent, the molecular organization typical for proteins from the glycinin family. Furthermore, posttranslational processing of Ara h 3 affects the IgE-binding properties and is therefore an essential subject of study for research on the allergenicity of Ara h 3.