Synthesis of alpha 2-macroglobulin in rat hepatocytes and in a cell-free system

The biosynthesis and secretion of alpha 2-macroglobulin was studied in rat hepatocyte primary cultures. After immunoprecipitation of alpha 2-macroglobulin from a cell homogenate and the hepatocyte medium, two forms of alpha 2-macroglobulin with app. Mr of 176000 and 182000, respectively, were identified. A precursor-product relationship for the two alpha 2-macroglobulin forms was demonstrated by a pulse-chase experiment. The cellular form of alpha 2-macroglobulin could be deglycosylated by endoglucosaminidase H, whereas the medium form of alpha 2-macroglobulin remained unaffected. On the other hand, only the medium form of alpha 2-macroglobulin was found to be susceptible to neuraminidase. In vitro translation of rat liver poly(A)+ RNA resulted in a translation product of an app. Mr of 162000.     

alpha2-Macroglobulin from hemolymph of the freshwater crayfish Astacus astacus.

1. A high mol. wt proteinase inhibitor has been purified from the haemolymph of the freshwater crayfish Astacus astacus. 2. The protein is a disulphide-bonded dimer (Mr 390,000) of two identical polypeptide chains (Mr 185,000). 3. The inhibitor displays a broad specificity and protects trypsin from inhibition by soybean trypsin inhibitor and thus is similar to vertebrate alpha 2-macroglobulin. 4. The alpha 2-macroglobulin-like inhibitor from Astacus interacts with bovine trypsin in an equimolar stoichiometry thereby decreasing tryptic hydrolysis of N-benzoyl-L-arginine-ethylester to 50% residual activity. In contrast, the activity of Astacus protease, a digestive zinc proteinase from crayfish toward succinyl-alanyl-alanyl-alanyl-4-nitroanilide is inhibited almost completely. 5. Sensitivity of the inhibitor to methylamine and autolytic cleavage suggests the presence of an internal thioester bond. 6. The N-terminal amino acid sequence of Astacus alpha 2-macroglobulin is strongly related to the alpha 2-macroglobulins from Pacifastacus leniusculus (91% identity) and from the lobster Homarus americanus (72% identity). In contrast, only 25% of the residues are identical with the alpha 2-macroglobulin from the horseshoe crab Limulus polyphemus. There is also a faint similarity to human complement protein C3 and human alpha 2-macroglobulin.     

Interaction of hemorrhagic metalloproteinases with human alpha 2-macroglobulin.

The interaction between four Crotalus atrox hemorrhagic metalloproteinases and human alpha 2-macroglobulin was investigated. The proteolytic activity of the hemorrhagic toxins Ht-c, -d, and -e against the large molecular weight protein substrates, gelatin type I and collagen type IV, was completely inhibited by alpha 2-macroglobulin. The proteolytic activity of Ht-a against the same substrates was not significantly inhibited. Each mole of alpha 2-macroglobulin bound maximally 2 mol of Ht-e and 1.1 mol of Ht-c and Ht-d. These proteinases interacted with alpha 2-macroglobulin rapidly at 22 degrees C. Rate constants based on intrinsic fluorescence measurements were 0.62 X 10(5) M-1 s-1 for interaction of alpha 2-macroglobulin with Ht-c and -d and 2.3 X 10(5) M-1 s-1 for the interaction of alpha 2-macroglobulin with Ht-e. Ht-a interacted with alpha 2-macroglobulin very slowly at 22 degrees C. Increasing the temperature to 37 degrees C and prolonging the time of interaction with alpha 2-macroglobulin resulted in the formation of Mr 90,000 fragments and high molecular weight complexes (Mr greater than 180,000), in which Ht-a is covalently bound to the carboxy-terminal fragment of alpha 2-M. The identification of the sites of specific proteolysis of alpha 2-macroglobulin shows that the cleavage sites for the four metalloproteinases are within the bait region of alpha 2-macroglobulin. Ht-c and -d cleave only at one site, the Arg696-Leu697 peptide bond, which is also the site of cleavage for plasmin, thrombin, trypsin, and thermolysin. Ht-a cleaves alpha 2-macroglobulin primarily at the same site, but a secondary cleavage site at the His694-Ala695 peptide bond was also identified.(ABSTRACT TRUNCATED AT 250 WORDS)     

alpha 2-macroglobulin traps a proteinase in the midregion of its arms. An immunoelectron microscopic study

alpha 2-Macroglobulin, one of the major plasma proteinase inhibitors with Mr = 720,000, is known to inhibit proteinases of all four classes through the "trap mechanism" (Barrett, A. J., and Starkey, P. M. (1973) Biochem. J. 133, 709-724), but the proteinase binding site of alpha 2-macroglobulin has not been identified precisely. We localized bound proteinase molecules on the electron microscopic images of alpha 2-macroglobulin, using anti-proteinase IgG. Serratial Mr = 56,000 proteinase produced by Serratia marcescens was chosen as the antigenic probe in this study because its affinity to specific antibodies was retained in its bound state to alpha 2-macroglobulin. Dimers of alpha 2-macroglobulin/Mr = 56,000 proteinase complexes cross-linked with anti-Mr = 56,000 proteinase IgG were prepared and subjected to electron microscopic observations. The electron microscopic image of alpha 2-macroglobulin complexed with Mr = 56,000 proteinase had four straight arms with an overall shape looking like the character "H." From the way anti-Mr = 56,000 proteinase IgG linked two alpha 2-macroglobulins, it was concluded that the proteinase existed in the midregion of one of the arms. This result helps us to form a more concrete view of the trap mechanism in that one of the arms of alpha 2-macroglobulin wraps the trapped proteinase and holds it isolated from high molecular weight substrates in the surrounding medium.     

Inhibition of alpha 2-macroglobulin-bound trypsin by soybean trypsin inhibitor

Soybean trypsin inhibitor, a protein of Mr = 20,000, has been used to assess the degree of inaccessibility of porcine trypsin within the alpha 2-macroglobulin-trypsin complex. The interaction between alpha 2-macroglobulin-bound trypsin and the inhibitor was demonstrated by affinity chromatography and trypsin inhibition. Whereas the free trypsin-inhibitor association is very fast (k = 1.2 X 10(7) M-1 s-1), the reaction between complexed trypsin and inhibitor takes 10 h to reach equilibrium. In addition, alpha 2-macroglobulin reduces, by several orders of magnitude, the affinity of trypsin for the inhibitor. Only one of the two trypsin molecules of the ternary (trypsin)2-alpha 2-macroglobulin complex is readily accessible to soybean inhibitor. It is postulated that the recently discovered proximity of the alpha 2-macroglobulin binding sites (Pochon, F., Favaudon, V., Tourbez-Perrin, M., and Bieth, J. (1981) J. Biol. Chem. 256, 547-550) accounts for this behavior. In the light of these results it is concluded that the proteinase binding sites are localized on the alpha 2-macroglobulin surface and that the two subunits of this protein are either not identical or not symmetrically arranged.     

Distribution of plasma kallikrein between C-1 inactivator and alpha 2-macroglobulin in plasma utilizing a new assay for alpha 2-macroglobulin-kallikrein complexes

We have previously described an enzyme-linked immunosorbent assay for the quantification of C-1 inactivator-kallikrein complexes in plasma (Lewin, M. F., Kaplan, A. P., and Harpel, P. C. (1983) J. Biol. Chem. 258, 6415-6421). We have now developed an immunoimmobilization-enzyme assay for alpha 2-macroglobulin-kallikrein complexes. In this assay these complexes are removed from plasma by immunoabsorption with the IgG fraction of rabbit anti-alpha 2-macroglobulin antiserum coupled to an agarose gel. The immobilized alpha 2-macroglobulin-kallikrein complex hydrolyzes the fluorogenic substrate D-Ser-Pro-Phe-Arg-7-amino-4-trifluoromethyl coumarin, and this activity is proportional to the concentration of complexes in the plasma. Using these assays we have studied the distribution of plasma kallikrein between its inhibitors under several different experimental conditions. When kallikrein is added to plasma, about 57% binds to C-1 inactivator and 43% to alpha 2-macroglobulin. When prekallikrein is activated endogenously in plasma by the addition of kaolin or Hageman factor fragment, approximately 84% of kallikrein is now bound to C-1 inactivator and 16% to alpha 2-macroglobulin. Temperature dramatically affects the distribution of kallikrein. The binding of kallikrein to alpha 2-macroglobulin in plasma is inversely related to temperature, whereas the binding to C-1 inactivator is directly related: 85% of the kallikrein is bound to alpha 2-macroglobulin at 4 degrees C, whereas at 37 degrees C, only 33% is bound. The total amount of kallikrein bound to the two inhibitors is similar at each temperature. These studies thus provide new insight concerning kallikrein formation and regulation in plasma.     

Evolution of human alpha 2-macroglobulin

A papain-binding protein (PBP) resembling human alpha 2-macroglobulin (alpha 2M) but of Mr half that of alpha 2M was purified from plaice (Pleuronectes platessa L.) plasma. The plaice protein displayed most of the distinctive inhibitory properties of the human macroglobulin, and was therefore considered, despite its smaller molecular size, to be homologous with alpha 2M. Plaice PBP was shown to consist of four dissimilar subunits; two I chains (Mr 105 000) and two II chains (Mr 90 000). Each of the larger I chains contained a "bait region" sensitive to proteolytic attack by a variety of proteinases, and an autolytic site analogous to the autolytic site of alpha 2M. Subunit I, almost certainly at the autolytic site, formed SDS-stable, covalent links with methylamine or a proportion of the trapped proteinase molecules. A scheme is proposed for the evolution of human alpha 2M from the smaller fish protein, and the possibility of a shared evolutionary origin for alpha 2M and the complement components C3 and C4 is discussed.     

Subunit and primary structure of a mouse alpha-macroglobulin, a human alpha 2-macroglobulin homologue

A mouse alpha-macroglobulin (AMG), a homologue of human alpha 2-macroglobulin (alpha 2 M), has been purified to homogeneity. In contrast to human and acute-phase rat alpha 2 M which contains subunits of about Mr 190 000, the mouse protein contains two major (Mr 163000 and 35000) and one minor (Mr 185000) subunits. Also unlike human alpha 2 M, which can be broken down into about 85000-dalton subunits when reacted with an endopeptidase, the native AMG is cleaved by trypsin into multiple components (Mr 86000, 63000, 61000 and 33000). Two-dimensional peptide map analysis of these various 125I-labeled subunit components reveals that the 185000- and 163000-dalton components are homologous proteins but only the 185000-dalton protein contains the 35000-dalton component. The 163000-dalton protein is cleaved by trypsin into 86000- and 63000-dalton components, and the 86-kDa component in turn can be broken down into 61000- and 33000-dalton fragments. Since the 35000-dalton component is serologically related to AMG but does not share any tryptic peptides with both the 163000- and 33000-dalton components, it is neither a copurified impurity nor a cleavage product of the major (163000-dalton) subunit. AMG, therefore, is composed of covalently linked subunits of Mr 163000 and 35000, and the 185000-dalton protein may be a variant subunit of AMG. Trypsin treatment of the [14C]methylamine-labeled AMG and alpha 2 M also sequentially generate subunit patterns indistinguishable from those of the unlabeled macroglobulins. The methylamine-sensitive site(s) of AMG is localized in the 63000-dalton peptide, which is rather resistant to trypsin digestion and to staining by Coomassie brillant blue. We conclude from this study that the mouse homologue has a subunit composition and primary structure distinctly different from those of human and rat alpha 2 M.     

Image processing of electron micrographs of human alpha 2-macroglobulin half-molecules induced by Cd2+

Human alpha 2-macroglobulin is a tetrameric plasma inhibitor of proteinases. Its dissociation by Cd2+ gives functional dimers. Electron microscopy of negatively stained dimers shows their round-ended cylindrical shape with furrows delimiting 3 main stain-excluding domains. Image processing of electron micrographs shows the existence of 2 main orientations of the dimers on the carbon support film. The dimer is composed of 2 curved monomers linked in a central domain, and related by a 90 degree rotation. Taking into account the known primary structure of alpha 2-macroglobulin and the linkage of the 2 constitutive monomers by 2 disulfide bonds, the molecular organization of the dimer is discussed, extended to the tetrameric molecule and compared to the published models of human alpha 2-macroglobulin.     

Isolation of rat serum alpha 1-microglobulin. Identification of a complex with alpha 1-inhibitor-3, a rat alpha 2-macroglobulin homologue.

Alpha 1-Microglobulin (alpha 1-m), or protein HC, a low molecular weight plasma protein with immunoregulatory properties, was isolated from rat serum by affinity chromatography using Sepharose-coupled monoclonal anti-alpha 1-m antibodies. High molecular weight forms of alpha 1-m were then separated from the low molecular weight alpha 1-m by gel chromatography of the eluted proteins. The apparent Mr (28,000), the charge heterogeneity, the N-linked carbohydrate, and yellow-brown chromophore suggest that the low molecular weight alpha 1-m is the serum counterpart to urinary alpha 1-m, which was purified previously. A high molecular weight complex of alpha 1-m was also isolated by the gel chromatography. It was homogeneous as judged by nondenaturing polyacrylamide gel electrophoresis. The molecule was bound by antibodies against human alpha 2-macroglobulin, and experiments with antisera against the three alpha-macroglobulin variants in rat serum, alpha 1-macroglobulin, alpha 2-macroglobulin, and alpha 1-inhibitor-3 (alpha 1I3) suggested that alpha 1I3 was the complex-partner of alpha 1-m. An antiserum raised against high molecular weight alpha 1-m was then used to isolate the complex-partner of alpha 1-m from rat serum with affinity chromatography, and this molecule was positively identified as alpha 1I3 by its physicochemical properties. Gel chromatography of the alpha 1I3.alpha 1-m complex suggested a molecule with an Mr of 266,000. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis, however, it migrated as three major molecular species with apparent molecular weights of 224,000, 205,000, and 194,000 and several minor species of both higher and lower molecular weights, suggesting a complex subunit structure. alpha 1-m and alpha 1I3 could be detected in all three major species by Western blotting, and NH2-terminal amino acid sequencing suggested a molar ratio of 1:1 of alpha 1-m and alpha 1I3 in all three species. alpha 1I3.alpha 1-m was colorless, did not show light absorbance beyond 300 nm which is typical of low molecular weight alpha 1-m and was electrophoretically homogeneous, suggesting that it lacks the chromophore. Finally, the serum concentrations of the alpha 1I3.alpha 1-m complex and free alpha 1-m were determined as 0.16 and 0.010 g/liter, respectively. Thus, alpha 1I3.alpha 1-m constitutes 1-3% of the total alpha 1I3 in rat serum (w/w) and approximately 60% of the total alpha 1-m.     

Heat-induced fragmentation of human alpha 2-macroglobulin.

Previous studies have demonstrated that human plasma alpha 2-macroglobulin (alpha 2 M) possesses a single subunit chain (Mr approximately 185,000) when incubated with dodecyl sulfate and dithiothreitol at 37 degrees C and analyzed by dodecyl sulfate-gel electrophoresis. The present study details the observation that heating alpha 2 M to 90 degrees C under identical conditions produces at least two additional polypeptide chains, termed bands II and III, with apparent molecular weights of 125,00 and 62,000. The generation of these fragments is enhanced by increasing the time of incubation. The appearance of band II composition of the buffer, dodecyl sulfate concentrations, or alpha 2 M protein concentration in the incubation mixture. The electrophoretic bands II and III of alpha 2 M have dissimilar 125I-labeled tryptic peptide digests and also differ in their amino acid composition. The heat-induced fragmentation of alpha 2M is not affected by the inclusion of a variety of low molecular weight protease inhibitors, suggesting that the appearance of bands II and III is not due to enzyme-catalyzed hydrolysis. When the subunit chain of alpha 2M is first cleaved by trypsin into the previously described Mr = 85,000 derivative, neither band II nor III material, nor other lower molecular weight products are generated by heat treatment. Furthermore, preincubation of alpha 2M with methylamine prevents fragmentation of the subunit chain. These results indicate that these fragments are neither pre-existing subunits of alpha 2M nor derivatives formed prior to treatment for gel analysis. These data provide evidence that a covalent bond in the alpha 2M molecule is unusually susceptible to heat-induced cleavage.     

Purification of alpha2-macroglobulin and the construction of immunogenic alpha2-macroglobulin-peptide complexes for use as cancer vaccines

A simple method for purification of immunogenic alpha2-macroglobulin from murine serum is described. Also described is a method for creating alpha2-macroglobulin-antigen complexes using purified alpha2-macroglobulin and peptides derived from tumor cell lysates. The application of such alpha2-macroglobulin-antigen complexes for eliciting cancer immunity is discussed.     

Thrombin-induced conformational changes of human alpha 2-macroglobulin: evidence for two functional domains

The interaction of thrombin with alpha 2-macroglobulin (alpha 2M) was characterized by monitoring conformational changes and measuring the increase of free sulfhydryl groups during the reaction. Under experimental conditions where [thrombin] greater than [alpha 2M], the conformational change, measured by increases in the fluorescence of 6-(p-toluidino)-2-naphthalenesulfonate, and thiol group appearance displayed biphasic kinetics. The initial rapid phase results in the formation of a stable complex, the appearance of two sulfhydryl groups, the cleavage of approximately half of the Mr 180 000 subunits, and a conformational change that is not as extensive as that which occurs with trypsin. The slower phase is associated with the appearance of two additional sulfhydryl groups, increased cleavage of the Mr 180 000 subunit, and additional conformational changes. The available evidence suggests that the slow phase results from hydrolysis of the Mr 180 000 subunit(s) due to proteolysis of the alpha 2M-thrombin complex by free thrombin. Experiments with 125I-thrombin document the binding of 1 mol of thrombin/mol of alpha 2M that is not dissociated upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the complex. At higher ratios of thrombin to alpha 2M, a second mole of thrombin will reversibly associate with the 1:1 alpha 2M-thrombin complex. Under conditions where [thrombin] less than [alpha 2M], biphasic kinetics were not observed, and the conformational change, sulfhydryl appearance, and hydrolysis of the Mr 180 000 subunit were found to follow second-order kinetics.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of human blood coagulation factor Xa by alpha 2-macroglobulin

The inactivation of activated factor X (factor Xa) by alpha 2-macroglobulin (alpha 2M) was studied. The second-order rate constant for the reaction was 1.4 X 10(3) M-1 s-1. The binding ratio was found to be 2 mol of factor Xa/mol of alpha 2M. Interaction of factor Xa with alpha 2M resulted in the appearance of four thiol groups per molecule of alpha 2M. The apparent second-order rate constants for the appearance of thiol groups were dependent on the factor Xa concentration. Sodium dodecyl sulfate gradient polyacrylamide gel electrophoresis was used to study complex formation between alpha 2M and factor Xa. Under nonreducing conditions, four factor Xa-alpha 2M complexes were observed. Reduction of these complexes showed the formation of two new bands. One complex (Mr 225,000) consisted of the heavy chain of the factor Xa molecule covalently bound to a subunit of alpha 2M, while the second complex (Mr 400,000) consisted of the heavy chain of factor Xa molecule and two subunits of alpha 2M. Factor Xa was able to form a bridge between two subunits of alpha 2M, either within one molecule of alpha 2M or by linking two molecules of alpha 2M. Complexes involving more than two molecules of alpha 2M were not formed.     

Stability and subunit structure of human alpha2-macroglobulin.

The molecular weights of alpha2-macroglobulin and its non-covalent subunits have been determined by equilibrium centrifugation. The secondary structure of the native and the thermally denatured molecules has been analyzed by circular dichroic measurements. In contrast to most proteins the thermally denatured form contains a slightly more highly organized polypeptide chain than the native form. The relaxation time of the native protein, as determined by fluorescence polarization measurements, indicates that alpha2-macroglobulin is composed of domains smaller than that of the two subunits. The transitions in acid, alkali, and at high temperatures have been explored in order to establish the pH and thermal range of stability of alpha-macroglobin.     

A solid-phase immunosorbent assay to determine the proteinase binding capacity of alpha 2-macroglobulin using 125I-trypsin as indicator proteinase

Hyperimmune sera against human alpha 2 macroglobulin were raised in rabbits following immunization with 's' alpha 2-macroglobulin over half a year. Immunoglobulins were prepared by DEAE-Sephacel anion exchange chromatography. The immunoglobulin preparations showed a remarkably high and equal titer for 's' and 'f' alpha 2-macroglobulin (plasma alpha 2-macroglobulin fully saturated with pig pancreas trypsin), which amounted to 6.4 X 10(-6) as revealed by passive hemagglutination. Immunoimmobilization experiments revealed that at equilibrium, 's' alpha 2-macroglobulin and both 'f' alpha 2-macroglobulins (27 and 82% saturation of 's' alpha 2-macroglobulin with trypsin) had been bound to the same degree from the fluid phase to the monospecific antibodies that had been adsorbed to polystyrene tubes. Comparison of quantitative gel scans for disappearance of the intact alpha 2-macroglobulin subunit (Mr 182000) with 125I-labeled trypsin binding capacity of immunoimmobilized alpha 2-macroglobulin-trypsin complexes showed conspicuous agreement. Rocket immunoelectrophoresis did not give significant differences between 's' alpha 2-macroglobulin and 'f' alpha 2-macroglobulin. In the fluid phase, a binding ratio of 2.4 mol trypsin/mol alpha 2-macroglobulin was observed. Saturation of solid phase immunoimmobilized 's' alpha 2-macroglobulin with trypsin could be accomplished by incubation with a 100-200-fold molar excess of enzyme for 10 min. The solid-phase experiments showed a binding ratio of 2.0 mol trypsin/mol alpha 2-macroglobulin. The high molar excess of trypsin needed to saturate solid-phase immunoimmobilized alpha 2-macroglobulin, which binds 20% less trypsin than in the liquid phase, is partially explained by an enhancement of the negative cooperativity of trypsin binding to alpha 2-macroglobulin found in the liquid-phase system. Assessment of the trypsin-binding capacity of alpha 2-macroglobulin immunoadsorbed from synovial fluids (n = 19) of patients with seropositive rheumatoid arthritis yielded an inactive alpha 2-macroglobulin of 0-53% when compared to the trypsin-binding capacity of normal plasma alpha 2-macroglobulin.     

Complexes of rat alpha 1-macroglobulin and subtilisin are endocytosed by parenchymal liver cells.

Rat alpha 1-macroglobulin was isolated from plasma. Gel electrophoresis of the denatured and reduced protein showed two bands, with Mr values of 163 000 and 37 000. The large subunit contained an autolytic site. This subunit was also split after reaction of the macroglobulin with trypsin. Electron microscopy showed that the macroglobulin changed towards a more compact conformation after reaction with this proteinase. Subtilisin, or alpha 1-macroglobulin, was labelled with a sucrose-containing radio-iodinated group that stays in lysosomes after endocytosis and breakdown of the tagged protein. After intravenous injection into rats, alpha 1-macroglobulin was cleared from plasma with first-order kinetics, showing a half-life of about 9 h, whereas complexes of alpha 1-macroglobulin and subtilisin were cleared with half-lives of only 3 min. Liver contained about 60% of the label at 30 min after injection of complexes. About 90% of the liver radioactivity was found in parenchymal cells isolated after perfusion of the liver with a collagenase solution. Subcellular fractionation indicated a lysosomal localization of the complexes. We conclude that endocytosis by parenchymal liver cells is the major cause of the rapid clearance of alpha 1-macroglobulin-proteinase complexes from plasma.     

Isolation and characterization of horse alpha 2-macroglobulin protease inhibitor

Several publications have described in the past properties of partly purified horse alpha 2-macroglobulin (alpha 2M) which are strikingly different from the human alpha 2M. Horse alpha 2M was therefore isolated to purity by classical procedures, i.e. affinity chromatography, ion exchange chromatography and gel filtration, and its properties are compared with those of its human counterpart. The molecular weight of the native protein and its subunits, the isoelectrofocusing pattern and the change in electrophoretic mobility caused by interaction with protease were similar to those of human alpha 2M. Horse alpha 2M had a broad enzyme specificity and inhibited enzymatic action on macromolecules but not on small molecular weight synthetic substrates. In addition the horse and human alpha 2M were found to be immunochemically related when examined by specific antisera to human as well as to horse alpha 2-macroglobulin.     

Platelet alpha2-macroglobulin and alpha1-antitrypsin.

Subcellular membrane and granule fractions derived from human platelets contain immunologically identifiable alpha2-macroglobulin and alpha1-antitrypsin. These platelet-derived inhibitors show a reaction of immunologic identity when compared to alpha2-macroglobulin and alpha1-antitrypsin purified from human plasma. Further, the platelet protease inhibitors possessed a similar subunit polypeptide chain structure to their plasma counterparts as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoretic analysis. Studies of the binding of radiolabeled trypsin to the various solubilized platelet subcellular fractions suggest that the granule-associated alpha2-macroglobulin and alpha1-antitrypsin, as well as membrane-associated alpha2-macroglobulin were functionally active. Quantitatively, circulating platelets contain relatively small concentrations of these inhibitors as compared to platelet-associated fibrinogen and factor VIIIAGN. Platelet protease inhibitors may modulate the protease-mediated events involved in the formation of hemostatic plugs and thrombi.     

Antiproteinase activity of alpha 2-macroglobulin

Blood serum separation by the method of gel filtration on Sephadex G-200 with the subsequent immunochemical determination of the quantitative content of basic proteolysis inhibitors permitted isolating the alpha 2-macroglobulin fraction while alpha 1-antitrypsin and alpha 1-antichymotrypsin separation was a failure. The immunochemical analysis of the antienzymic activity of the isolated inhibitors showed that 32.3 +/- 3.5% of the introduced kallikrein, 18.7 +/- 0.6% of trypsin and 14.4 +/- 4.1% of chymotrypsin were bound in the zone of alpha 2-macroglobulin. The rest of antienzymic activity was localized in the zone of alpha 1-antitrypsin and alpha 1-antichymotrypsin. After a preliminary saturation of blood serum with trypsin in the amount equivalent to its antitryptic capacity (200 micrograms/ml) the ability of alpha 2-macroglobulin to bind kallikrein and chymotrypsin lowers considerably (by 69 and 72%, respectively). In the zone of alpha 1-antitrypsin and alpha 1-antichymotrypsin a decrease in the ability to bind kallikrein and chymotrypsin amounted to 44 and 12% respectively. Thus, alpha 2-macroglobulin being bound with trypsin looses considerably its ability to bind other enzymes.