Interaction of human plasmin with human alpha 2-macroglobulin

The steady-state kinetic parameters of plasmin and the alpha 2-macroglobulin (alpha 2M)-plasmin complex toward the chromogenic substrate Val-Leu-Lys-p-nitroanilide (S-2251), in the presence and absence of plasmin competitive inhibitors, have been determined. At pH 7.4 and 22 degrees C, the Km values for plasmin and alpha 2M-plasmin for S-2251 were 0.13 +/- 0.02 mM and 0.3 +/- 0.03 mM. The kcat of this reaction, when catalyzed by alpha 2M-plasmin, was 6.0 +/- 0.5 s-1, a value significantly decreased from the kcat of 11.0 +/- 1.0 s-1, determined when free plasmin was the enzyme. KI values for benzamidine of 0.50 +/- 0.05 mM and 0.23 +/- 0.02 mM were obtained for S-2251 hydrolysis, as catalyzed by alpha 2M-plasmin and plasmin, respectively. When leupeptin was the competitive inhibitor, KI values of 5.0 +/- 0.65 microM and 1.0 +/- 0.1 microM were obtained when alpha 2M-plasmin and plasmin, respectively, were the enzymes employed for catalysis of S-2251 hydrolysis. The comparative rates of reaction of the peptide inhibitor Trasylol (Kunitz basic pancreatic inhibitor) with plasmin and alpha 2M-plasmin were also determined. A concentration of Trasylol of at least 3 orders of magnitude greater for alpha 2M-plasmin than for free plasmin was required to observe inhibition rates on comparable time scales.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of human plasma kallikrein and its light chain with alpha 2-macroglobulin

Human plasma kallikrein participates in the contact activation system of plasma. The light chain of kallikrein contains the enzymatic active site; the heavy chain is required for binding to high molecular weight kininogen and for surface-dependent activation of coagulation. This study has examined the functional contributions of the heavy chain of kallikrein and of high molecular weight kininogen in the inactivation of kallikrein and of its isolated light chain by alpha 2-macroglobulin (alpha 2M). Irreversible inhibition was observed for both kallikrein and its light chain, with the initial formation of a reversible enzyme-inhibitor complex. The second-order rate constants for these reactions were 3.5 X 10(5) and 4.8 X 10(5) M-1 min-1 for kallikrein and its light chain, respectively. When present in excess, high molecular weight kininogen decreased the rate of kallikrein inactivation by alpha 2M, whereas the rate of inactivation of the light chain was unaffected by high molecular weight kininogen. Although at a drastically reduced rate, high molecular weight kininogen was cleaved by alpha 2M-bound kallikrein. Sodium dodecyl sulfate gradient polyacrylamide gel electrophoresis was used to study complex formation between alpha 2M and kallikrein or its light chain. Under reducing conditions, four kallikrein-alpha 2M complexes were observed. Three of these complexes consisted of alpha 2M and the light chain of kallikrein (Mr 123 000, 235 000, and 330 000). Two alpha 2M-kallikrein light chain complexes incorporated [3H]diisopropyl fluorophosphate ( [3H]DFP) whereas the Mr 330 000 complex did not react with [3H]DFP.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

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.     

Characterization of human pregnancy zone protein. Comparison with human alpha 2-macroglobulin

Native human pregnancy zone protein (PZP), a close homolog of alpha 2-macroglobulin (alpha 2M), can be obtained in approximately 20% yield from pooled late pregnancy plasma or serum by a combination of polyethylene glycol precipitation, euglobulin precipitation, DEAE-Sephacel chromatography, zinc-chelate affinity chromatography, and negative affinity chromatography on insolubilized antibodies against human serum proteins. Both proteins are similarly organized as disulfide-bridged dimers of 360 kDa containing 180-kDa subunits. These dimers constitute the proteinase-binding units of PZP, and in contrast to alpha 2M, they appear to be only loosely associated, indicating a subtle difference in the quaternary structure of these alpha-macroglobulins. The preparations contain functionally intact beta-cysteinyl-gamma-glutamyl thiol esters, located in the same nonapeptide sequence as found in alpha 2M, and form complexes with a variety of proteinases in which a large fraction of the proteinase is bound covalently. Proteinases bound to PZP are still active and poorly accessible to reaction with large inhibitors like alpha 1-proteinase inhibitor. The structural and functional features of PZP indicate that PZP and alpha 2M, although extremely similar, may have different yet overlapping sets of proteinases as targets. It is possible that PZP mainly controls the activity of cellular proteinases released under conditions of increased cellular turnover and that PZP could be the human equivalent to the acute phase alpha-macroglobulins known in other species.     

Kinetics of association of human proteinases with human alpha 2-macroglobulin

Association rates have been determined for the interaction of human alpha 2-macroglobulin with human neutrophil elastase, cathepsin G, and human plasma kallikrein. Both of the neutrophil enzymes are rapidly inactivated by this inhibitor; however, the inactivation of plasma kallikrein is much slower. Comparison of the rates of inactivation with those already established for other inhibitors clearly indicate that alpha 1-proteinase inhibitor is the controlling inhibitor for neutrophil elastase and alpha 1-antichymotrypsin for cathepsin G, alpha 2-macroglobulin acting only as a secondary inhibitor. The control of plasma kallikrein would appear to be rather poor since neither alpha 2-macroglobulin nor C1-inhibitor appears to react very rapidly with this proteinase. Thus, a primary role for alpha 2-macroglobulin in directly inactivating proteinases in blood, under normal physiological conditions, remains to be established.     

Reaction of methylamine with human alpha 2-macroglobulin. Mechanism of inactivation

The human protease inhibitor alpha 2-macroglobulin (alpha 2 M) is inactivated by reaction with methylamine. The site of reaction is a protein functional group having the properties of a thiol ester. To ascertain the relationship between thiol ester cleavage and protein inactivation, the rates of methylamine incorporation and thiol release were measured. As expected for a concerted reaction of a nucleophile with a thiol ester, the rates were identical. Furthermore, both rates were first order with respect to methylamine and second order overall. The methylamine inactivation of alpha 2M was determined by measuring the loss of total protease-binding capacity. This rate was slower than the thiol ester cleavage and had a substantial initial lag. However, the inactivation followed the same time course as a conformational change in alpha 2M that was measured by fluorescent dye binding, ultraviolet difference spectroscopy, and limited proteolysis. Thus, the methylamine inactivation of alpha 2M is a sequential two-step process where thiol ester cleavage is followed by a protein conformational change. It is the latter that results in the loss of total protease-binding capacity. A second assay was used to monitor the effect of methylamine on alpha 2M. The assay measures the fraction of alpha 2M-bound protease (less than 50%) that is resistant to inactivation by 100 microM soybean trypsin inhibitor. In contrast to the total protease-binding capacity, this subclass disappeared with a rate coincident with methylamine cleavage of the thiol ester. alpha 2M-bound protease that is resistant to a high soybean trypsin inhibitor concentration may reflect the fraction of the protease randomly cross-linked to alpha 2M. Both the thiol ester cleavage and the protein conformational change rates were dependent on methylamine concentration. However, the thiol ester cleavage depended on methylamine acting as a nucleophile, while the conformational change was accelerated by the ionic strength of methylamine. Other salts and buffers that do not cleave the thiol ester increased the rate of the conformational change. A detailed kinetic analysis and model of the methylamine reaction with alpha 2M is presented. The methylamine reaction was exploited to study the mechanism of protease binding by alpha 2M. At low ionic strength, the protein conformational change was considerably slower than thiol ester cleavage by methylamine. Thus, at some time points, a substantial fraction of the alpha 2M had all four thiol esters cleaved, yet had not undergone the conformational change. This fraction (approximately 50%) retained full protease-binding capacity.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Cadmium binding to human alpha 2-macroglobulin

alpha 2-Macroglobulin (alpha 2M) is one of the major cadmium-binding proteins of human plasma. As determined with equilibrium dialysis, alpha 2M bound 4.6 (+/- 0.7) mol Cd2+ per mol protein with an apparent dissociation constant of (9.6 (+/- 5.0] X 10(-7) M. Methylamine-modified alpha 2M (alpha 2M-Me) had a similar affinity for Cd2+ (Kd,app = 5.3 X 10(-7) M), but fewer binding sites. Cadmium produced a small increase in the amidolytic activity of trypsin in the presence of alpha 2M and soybean trypsin inhibitor. Using the binding parameters determined from the equilibrium dialysis studies, the Cd2+ concentration which produced a half-maximal increase in amidolytic activity corresponded to saturation of all Cd2+-binding sites in one-half of the alpha 2M molecules. From these results, a model is proposed in which one Cd2+-binding site is present in each of the four polypeptide chains which compose alpha 2M.     

Characterization of human alpha 2-macroglobulin monomers obtained by reduction with dithiothreitol.

We compared the physicochemical characteristics of alpha 2-macroglobulin (alpha 2M) monomers produced by limited reduction and carboxamidomethylation to those of the naturally occurring monomeric alpha-macroglobulin homologue rat alpha 1-inhibitor 3 (alpha 1 I3). Unlike alpha 1 I3, alpha 2 M monomers fail to inhibit proteolysis of the high molecular weight substrate hide powder azure by trypsin. In contrast to alpha 1 I3, which remains monomeric after reacting with proteinase, alpha 2 M monomers reassociate to higher molecular weight species (dimers, trimers, and tetramers) after reacting with proteinase. Reaction of alpha 2 M monomers at molar ratios of proteinase to alpha 2M monomers as low as 0.3:1 leads to extensive reassociation and is accompanied by complete bait-region and thiolester bond cleavage. During the reaction of alpha 2M monomers with proteinases, the proteinase binds to the reassociating alpha 2M subunits but is not inhibited. Of significance, all the bound proteinase was covalently linked to the reassociated alpha 2M species. Treatment of alpha 2M monomers with methylamine results in thiolester bond cleavage but minimal reassociation. Treatment of alpha 2M monomers with methylamine followed by proteinase results in complete bait-region cleavage and is accompanied by marked reassociation of alpha 2M monomers to higher molecular weight species. However, no proteinase is associated with these higher molecular weight forms. We infer that bait-region cleavage is more important than thiolester bond cleavage in driving alpha 2M monomers to reassociate. Despite many similarities between alpha 1I3 and alpha 2M monomers, significant differences must exist with respect to proteinase orientation within the inhibitor to account for the failure of alpha 2M monomers to protect large molecular weight substrates from proteolysis by bound proteinase, in contrast to the naturally occurring monomeric homologue rat alpha 1 I3.     

Evolution of alpha 2-macroglobulin. The demonstration in a variety of vertebrate species of a protein resembling human alpha 2-macroglobulin.

The amino acid sequence of the Pronase-released heads of neuraminidase subtype N2 from the A/Tokyo/3/67 strain of influenza virus was determined by a combination of peptide and nucleic acid sequence analysis. The results show that the Pronase-released heads contain 396 amino acid residues and extend from residue 74 in the original protein to the C-terminus at residue 469. The heads contain five potential glycosylation sites at asparagine residues 86, 146, 200, 234 and 402, but only the first four are glycosylated. The sequence homology with the corresponding region of the previously published sequence of the neuraminidase subtype N1 [Fields, Winter & Brownlee (1981) Nature (London) 290, 213-217] is 45%. Detailed evidence for the sequence data has been deposited as Supplementary Publication SUP 50116 (14 pages) at the British Library Lending Division, Boston Spa, Wetherby, West Yorkshire LS23 7BQ, U.K., from whom copies may be obtained on the terms given in Biochem. J. (1981) 193, 5.     

Interaction and complex-formation between the eosinophil cationic protein and alpha 2-macroglobulin.

The interaction between the highly basic and cytotoxic eosinophil cationic protein (ECP) and human plasma proteins is described. The major plasma protein responsible for complex-formation with ECP was shown to be the 'fast' form of alpha 2-macroglobulin (alpha 2M). Large amounts of complexes were observed in a serum obtained from a patient with hypereosinophilic syndrome. The amount of complexes that could be generated in vitro in normal fresh serum was rather low and was even less in fresh citrated plasma. Complex-formation between the non-proteolytic ECP and alpha 2M was augmented in the presence of methylamine. Binding of ECP to alpha 2M was also induced by the proteinases cathepsin G and thrombin, and the binding was competitive with cathepsin G. Methylamine and the proteinases seem to share a common mechanism in inducing binding of ECP. The nature of the ECP-alpha 2M interaction is non-covalent, but withstands high salt concentrations. The interaction with alpha 2M may reflect a mechanism by which the organism protects itself against the deleterious effects of the highly cytotoxic protein ECP.     

Physical and chemical properties of human plasma alpha2-macroglobulin.

Alpha2-M (alpha2-macroglobulin) was purified from human plasma by two different procedures. As well as having no detectable impurities by the usual criteria for testing the homogeneity of protein preparations, these alpha2M preparations showed a single component, after reduction in urea, of 185000 daltons by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. The molecular weight of the alpha2M was found to be 718000 by sedimentation equilibrium experiments using the gravimetrically determined -v of 0.731 ml/g. The interaction of several proteinases with alpha2M was studied by using a novel discontinuous polyacrylamide-gel system, which showed clear separation of the enzyme-complexed alpha2M from the free alpha2M. These studies indicated that urokinase, as well as trypsin, chymotrypsin, plasmin and thrombin forms complexes with alphaM. The cleavage of the 185000-dalton subunit to a 85000-dalton species on interaction of trypsin with alpha2M was demonstrated by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis after reduction of the alpha2M-trypsin complex in urea. The amino acid composition, carbohydrate content, absorption coefficient at 280 nm, the specific refractive increment and the sedimentation coefficient for these alpha2M preparations were measured. The stability of the trypsin-binding activity of the alpha2M preparations was also studied under several storage situations.     

The reaction of human alpha 2-macroglobulin with alpha-chymotrypsin. A stopped-flow kinetic investigation

The kinetics of the conformational changes of human alpha 2-macroglobulin (alpha 2M) induced by reaction with pure alpha-chymotrypsin, have been analyzed using three fluorescent probes, namely protein tryptophan groups and the dye 6-(4-toluidino)-2-naphthalenesulfonate, to monitor alterations of the alpha 2M structure, and a covalent conjugate of chymotrypsin and fluorescein isothiocyanate (Chy-FITC). The main reaction sequence exhibits a triphasic time course with any of the labels used. Each phase is first-order. The fixation of a single molecule of chymotrypsin to one protease-binding site of alpha 2M (site A) initiates the whole process and determines the access to the second site (site B). Of the three exponential phases of the reaction (20 degrees C), phase I (k1 approximately 19.6 min-1) and phase II (k2 approximately 5.3 min-1) belong to site A. Phase III is related to site B transformation. It contains two steps with different responses from tryptophan (k3 approximately 0.77 min-1) and Chy-FITC (k3 approximately 0.19 min-1) fluorescence measurements. The point to be stressed is that site A and site B, while presumably identical in the native form, are not equivalent with regard to their fluorescence and kinetic properties. However, the activation energy (E = 30.1 +/- 2.7 kJ mol-1) is the same for the three phases of the reaction. When present in sufficient excess, free chymotrypsin or native alpha 2M is able to form reversible complexes with the above-related chymotrypsin-alpha 2M adducts. Only the alpha 2M site A core seems to be involved in this parallel process. In addition the conformational state of the chymotrypsin-alpha 2M complexes is shown to depend on the pH, with a pKa of 6.4.     

Subunit structure of human alpha 2-macroglobulin (alpha 2-MG) with respect to its interaction with trypsin.

SDS-polyacrylamide gel electrophoresis of a recently prepared alpha 2-macroglobulin solution showed only the polypeptide chains of 190,000 molecular weight. Reduction-alkylation of this preparation followed by gel-filtration on a Sephadex G-200 column in 5.2 M guanidine hydrochloride was unable to separate a fraction of 83,000 molecular weight as previously described. Nevertheless, after incubation of a mixture alpha 2-macroglobulin-trypsin during 45 minutes at 37 degrees C, approximately 60 per cent of the preparation were converted in a component with 83,000 molecular weight as detected in SDS polyacrylamide gel. That component was isolated on Sephadex G-200 in guanidine hydrochloride and corresponds to the subunit, fraction II. According to the results of the present work together with those of previous studies, it can be assumed that alpha 2-MG is a 780,000 molecular weight protein (19S) formed of two half-molecules of equal weight (11-12S). The half-molecule contains two polypeptide chains of 180,000-190,000 molecular weight, each of them having, in its middle, a specific region particularly susceptible to attack by proteases.     

Primary structure of human alpha 2-macroglobulin. V. The complete structure

The primary structure of the tetrameric plasma glycoprotein human alpha 2-macroglobulin has been determined. The identical subunits contain 1451 amino acid residues. Glucosamine-based oligosaccharide groups are attached to asparagine residues 32, 47, 224, 373, 387, 846, 968, and 1401. Eleven intrachain disulfide bridges have been placed (Cys25-Cys63, Cys228-Cys276, Cys246-Cys264, Cys255-Cys408, Cys572-Cys748, Cys619-Cys666, Cys798-Cys826, Cys824-Cys860, Cys898-Cys1298, Cys1056-Cys1104, and Cys1329-Cys1444). Cys-447 probably forms an interchain bridge with Cys-447 from another subunit. The beta-SH group of Cys-949 is thiol esterified to the gamma-carbonyl group of Glx-952, thus forming an activatable reactive site which can mediate covalent binding of nucleophiles. A putative transglutaminase cross-linking site is constituted by Gln-670 and Gln-671. The primary sites of proteolytic cleavage in the activation cleavage area (the "bait" region) are located in the sequence: -Arg681-Val-Gly-Phe-Tyr-Glu-. The molecular weight of the unmodified alpha 2-macroglobulin subunit is 160,837 and approximately 179,000, including the carbohydrate groups. The presence of possible internal homologies within the alpha 2-macroglobulin subunit is discussed. A comparison of stretches of sequences from alpha 2-macroglobulin with partial sequence data for complement components C3 and C4 indicates that these proteins are evolutionary related. The properties of alpha 2-macroglobulin are discussed within the context of proteolytically regulated systems with particular reference to the complement components C3 and C4.