Mechanism of insulin incorporation into alpha 2-macroglobulin: implications for the study of peptide and growth factor binding.

In recent years, many studies have suggested a direct role for alpha 2-macroglobulin (alpha 2M), a plasma proteinase inhibitor, in growth factor regulation. When coincubated in the presence of either trypsin, pancreatic elastase, human neutrophil elastase, or plasmin, 125I-insulin rapidly formed a complex with alpha 2M which was greater than 80% covalent. The covalent binding was stable to reduction but abolished by competition with beta-aminopropionitrile. Neither native alpha 2M nor alpha 2M pretreated with proteinase or methylamine incorporated 125I-insulin. Experiments utilizing alpha 2M cross-linked with cis-dichlorodiammineplatinum(II) indicated that 125I-insulin must be present during alpha 2M conformational change to covalently bind. A maximum stoichiometry of 4 mol of insulin bound per mole of alpha 2M and the short half-life of the alpha 2M intermediate capable of covalent incorporation were consistent with thiol ester involvement. Protein sequence analysis of unlabeled insulin-alpha 2M complexes, together with results of beta-aminopropionitrile competition, confirmed that insulin incorporation occurs via the same gamma-glutamyl amide linkage responsible for covalent proteinase and methylamine binding to alpha 2M. Although intact insulin apparently incorporated through its sole lysine residue on the B chain, we found that isolated A chain also bound covalently to alpha 2M. Phenyl isothiocyanate derivatization of the N-terminus had no effect on A-chain binding, supporting the possibility of heretofore unreported gamma-glutamyl ester linkages to alpha 2M.     

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)     

α2-Macroglobulin-protease reactions: Relationship of covalent bond formation,methylamine reactivity,and specific proteolysis

Experiments were performed to define the relation between covalent binding of enzymes to β₂-macroglobulin (α₂M), the specific proteolysis of α₂M subunits to 85K fragments, and the reactivity of the methylamine site on α₂M. We studied the reaction of α₂M with native trypsin, anhydrotrypsin, and two active lysyl-blocked derivatives, methyl-trypsin and dimethylmaleyl-trypsin, the last with reversibly modified amino groups that can be regenerated at low pH. The results were: (1) All enzymes tested reacted with α₂M but only native trypsin formed covalent complexes (not dissociable by sodium dodecyl sulfate). Trypsin and the lysyl-blocked enzymes caused complete proteolysis of the α₂M subunits, in agreement with previous studies. (2) The dimethyl-maleyl-trypsin became covalently bound to α₂M only after removing the blocking groups of the bound enzyme, indicating that sequential proteolysis and covalent bond formation is possible. Under the conditions used for deblocking, there was no change in the covalent/noncovalent binding ratio of native trypsin, anhydrotrypsin, or the other lysyl-blocked derivative, methyl-trypsin. (3) Native trypsin or anhydrotrypsin displaced methyl- or dimethylmaleyl-trypsin from their α₂M complexes but the newly bound enzymes with free amino groups did not form covalent bonds indicating that enzymes must remain in association with the inhibitor for the bond to form. (4) Methylamine reacts with noncovalent α₂M complexes but not with covalent complexes. (5) Methylamine-treated α₂M can still form complexes with trypsin but at a drastically reduced rate and only noncovalent complexes are formed. In summary, sequential proteolysis and covalent bond formation is possible under certain conditions, and there is a strong correlation between covalent binding and loss of methylamine reactivity. The latter observation is suggestive evidence for the identity of the covalent binding site of α₂M and the putative thiol ester of the methylamine site. The enzyme lysyl amino groups, are likewise possible candidates for attacking nucleophile at that site.     

Further characterization of the covalent linking reaction of alpha 2-macroglobulin.

It is shown that non-proteolytic proteins can become covalently linked to alpha 2M (alpha 2-macroglobulin) during its reaction with proteinases, and that this probably occurs by the mechanism that leads to the covalent linking of proteinases described previously [Salvesen & Barrett (1980) Biochem. J. 187, 695-701]. The covalent linking of trypsin was at least partly dependent on the presence of unblocked lysine side chains on the protein. The covalent linking of proteinases was inhibited by nucleophiles of low Mr, and these compounds were themselves linked to alpha 2M in a molar ratio approaching one per quarter subunit. Peptide "mapping" indicated that the site of proteinase-mediated incorporation of the amines was the same as that at which methylamine is incorporated in the absence of a proteinase. The nucleophile-reactive site revealed in alpha 2M after reaction with a proteinase was shown to decay with a t1/2 of 112 s, at pH 7.5. After the reaction with a proteinase or with methylamine, a free thiol group was detectable on each subunit of alpha 2M. We propose that the site for incorporation of methylamine in each subunit is a thiol ester, which in S-alpha 2M (the electrophoretically "slow" form) is sterically shielded from reaction with large nucleophiles, but is revealed as a highly reactive group, free from steric hindrance, after the proteolytic cleavage. We have designated the activated species of the molecule "alpha 2M".     

Differences in the proteinase inhibition mechanism of human alpha 2-macroglobulin and pregnancy zone protein.

Different conformational states of human alpha 2-macroglobulin (alpha 2M) and pregnancy zone protein (PZP) were investigated following modifications of the functional sites, i.e. the 'bait' regions and the thiol esters, by use of chymotrypsin, methylamine and dinitrophenylthiocyanate. Gel electrophoresis, mAb (7H11D6 and alpha 1:1) and in vivo plasma clearance were used to describe different molecular states in the proteinase inhibitors. In alpha 2M, in which the thiol ester is broken by binding of methylamine and the 'trap' is closed, cyanylation of the liberated thiol group from the thiol ester modulates reopening of the 'trap' and the 'bait' regions become available for cleavage again. The trapping of proteinases in the cyanylated derivative indicates that the trap functions as in native alpha 2M. In contrast, cyanylation has no effect on proteinase-treated alpha 2M. As demonstrated by binding to mAb, the methylamine and dinitrophenylthiocyanate-treated alpha 2M exposes the receptor-recognition site, but the derivative is not cleared from the circulation in mice. The trap is not functional in PZP. In native PZP and PZP treated with methylamine, the conformational states seem similar. The receptor-recognition sites are not exposed and removal from the circulation in vivo is not seen for these as for the PZP-chymotrypsin complex. Tetramers are only formed when proteinases can be covalently bound to the PZP. Conformational changes are not detected in PZP derivatives in which the thiol ester is treated with methylamine and dinitrophenylthiocyanate. The results suggest that the conformational changes in alpha 2M are generated by mechanisms different to these in PZP. The key structure gearing the conformational changes in alpha 2M is the thiol ester, by which the events 'trapping' and exposure of the receptor-recognition site can be separated. In PZP, the crucial step for the conformational changes is the cleavage of the 'bait' region, since cleavage of the thiol ester does not lead to any detectable conformational changes by the methods used.     

Relation of internal thioesters to conformational change and receptor-recognition site in alpha 2-macroglobulin complexes.

The unique steric type of inhibition of endopeptidases by human alpha 2-macroglobulin (alpha 2-M) and the inactivation of the latter by methylamine were examined in relation to the internal thioesters in alpha 2M. The present results confirm our previous findings that disruption of the internal thioesters, is not in itself sufficient to cause the conformational change of alpha 2M typical of alpha 2-M-proteinase complexes; the electrophoretically slow form of alpha 2M with [14C]methylamine incorporated was isolated. Moreover, this group is stabilized by derivatization of the exposed cysteine thiol groups. Cyanylation with 2,4-dinitrophenyl thiocyanate during the methylamine reaction was the most effective procedure, yielding essentially only slow-form alpha 2M. Other thiol-specific reagents were less effective. When allowed to react with trypsin the cyanylated derivative (slow-form alpha 2M with thioesters broken) produced anomalous complexes; only half the expected amount of trypsin was bound, whereas the complexes were fully inhibited by soya-bean trypsin inhibitor and were proteolytically active. Despite this, the anomalous complexes were recognized by two highly specific probes: the fibroblast alpha 2M-complex receptor and the monoclonal antibody (F2B2) directed against the receptor-recognition site on alpha 2M complexes. The results show that the internal thioesters in alpha 2M are necessary for the conformational change producing sterically inhibited endoproteinase complexes, but do not participate as such in receptor-mediated endocytosis of these complexes.     

Identification of a monoclonal antibody specific for a neoantigenic determinant on alpha 2-macroglobulin: use for the purification and characterization of binary proteinase-inhibitor complexes

A monoclonal antibody was obtained from the fusion of spleen cells of mice, immunized with methylamine-treated alpha 2-macroglobulin (alpha 2M), with the myeloma cell line P3-X63-Ag8.653. A competitive binding assay demonstrated that the antibody was specific for a neoantigen expressed on alpha 2M when the inhibitor reacts with proteinases or with methylamine. When immobilized, the monoclonal antibody retained its ability to specifically bind alpha 2M-proteinase complexes or methylamine-treated alpha 2M, both of which could be quantitatively recovered from the immunoaffinity column by lowering the pH to 5.0. Binary alpha 2M-proteinase complexes of trypsin, plasmin, and thrombin, prepared by incubating large amounts of alpha 2M with a small amount of enzyme, were isolated by immunoaffinity chromatography. Each purified complex was characterized with regard to proteinase content, extent of alpha 2M subunit cleavage, extent of thiol ester hydrolysis, and extent of conformational change. Each complex contained 0.8-0.9 mol of proteinase/mol of inhibitor. In the alpha 2M-thrombin, alpha 2M-plasmin, and alpha 2M-trypsin complexes, approximately 50%, 60%, and 75% of the subunits are cleaved, respectively. Titration of sulfhydryl groups revealed that all purified binary complexes contained 2 +/- 0.5 mol of thiol/mol of complex, suggesting that each complex retains two intact thiol ester bonds. When the purified complexes were incubated with excess trypsin or with methylamine, an additional 1-2 mol of sulfhydryl/mol of complex could be titrated.(ABSTRACT TRUNCATED AT 250 WORDS)     

Pregnancy zone protein, a proteinase binding alpha-macroglobulin. Stopped-flow kinetic studies of its interaction with chymotrypsin

Human pregnancy zone protein (PZP) is a major pregnancy-associated plasma protein, strongly related to alpha 2-macroglobulin (alpha 2M). The proteinase binding reaction of PZP is investigated using chymotrypsin as a model enzyme. The time-course of the interaction is studied by measuring the change in intrinsic protein fluorescence of PZP-chymotrypsin reaction mixtures as a function of time after rapid mixing in a stopped-flow apparatus. Titrations show the changes of fluorescence at equilibrium to correspond with the formation of a chymotrypsin-PZP(tetramer) species. The kinetic results show the formation of the species to take place in an overall second-order process dependent on the concentrations of chymotrypsin and of PZP(dimers), k = 5 x 10(5) M-1 x s-1. Reactions of PZP-thiol groups do not give rise to fluorescence changes. The fluorescence changes most likely reflect the formation of an intermediate with intact thiol esters. Further analysis of the kinetic results suggests that the chymotrypsin-PZP(tetramer) intermediate is formed in two reaction steps: (1) initially native PZP(dimers) are cleaved at bait regions by enzyme molecules, and that is the rate determining reaction of the fluorescence changes; (2) association with another PZP(dimer) or PZP(dimer)-chymotrypsin complex in a very fast reaction that leads to the formation of 1:1 -chymotrypsin-PZP(tetramer) intermediate, probably with intact thiol esters. The interactions studied apparently are established early in the path of the reaction and the fluorescence changes probably reflect noncovalent enzyme-PZP contacts, which are not changed when covalent binding occurs. Further, fluorescence changes are seen only in reactions of PZP with enzymes, not with methylamine.     

Pregnancy zone protein, a proteinase-binding macroglobulin. Interactions with proteinases and methylamine

Human pregnancy zone protein (PZP) is a major pregnancy-associated plasma protein, strongly related to alpha 2-macroglobulin (alpha 2M). Its properties and its reactions with a number of enzymes, particularly chymotrypsin, and with methylamine have been investigated. It is concluded that native PZP molecules are dimers of disulfide-bridged 180-kDa subunits and that proteinase binding results in covalent 1:1 (tetrameric)PZP-enzyme complexes. Native PZP is unstable, and storage should be avoided, but when kept unfrozen at 0 degree C most PZP preparations stay native 1-3 months. The reaction of PZP with chymotrypsin involves (i) proteolysis of bait regions, (ii) cleavage of beta-cysteinyl-gamma-glutamyl thiol ester groups, (iii) some change of the conformation and quaternary structure of PZP, and (iv) the formation of covalent 1:1 chymotrypsin-PZP(tetramer) complexes in which chymotrypsin is active but shows less activity than free chymotrypsin. The emission spectra of intrinsic fluorescence show significant differences between the PZP-chymotrypsin complex and its native components, whereas no differences are observed between methylamine-reacted PZP and native PZP. Methylamine reacts with the beta-cysteinyl-gamma-glutamyl thiol ester groups of PZP in a second-order process with k = (13.6 +/- 0.5) M-1 s-1, pH 7.6, 25 degrees C. The reaction product is PZP(dimers); no PZP(tetramers) are formed. The proteinase-binding specificity of PZP is far more restricted than that of alpha 2M. Certain chymotrypsin-like and trypsin-like enzymes are bound much less efficiently than is chymotrypsin itself.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetics of the reaction of thrombin and alpha 2-macroglobulin.

The kinetics of the reaction of alpha 2-macroglobulin (alpha 2M) with human thrombin were studied by recording the appearance of thiol groups spectrophotometrically and by measuring the distribution of protein species by denaturing non-reducing gel electrophoresis. The goals were to study the relation between the formation of various covalent enzyme-inhibitor complex species and the appearance of free thiol, and from the kinetic analysis, to try to characterize the chemical nature of the protein complexes. The kinetics of thiol-group release were observed to be biphasic, the early phase showing second-order behaviour, results consistent with previous reports in the literature. The observed second-order rate constant for thiol-group release was found to be faster than the second-order rate constant for the disappearance of the band corresponding to native alpha 2M on gel electrophoresis. This may be a reflection of the multiple products formed from the thioester. Alternatively, it is possible that covalent-bond formation is slower than some enzyme-induced change in the thioester centre, and this may be suggestive evidence for a reactive alpha 2M centre that does not contain an intact thioester. The kinetics of covalent-bond formation were found to be consistent with the internal cross-link of several alpha 2M chains by the bound proteinase, providing further evidence that the very-high-Mr species seen on gels may arise from dimers of the alpha 2M molecule held together by covalent bonds to the enzyme.     

Functional modifications of α2-macroglobulin by primary amines. Kinetics of inactivation of α2-macroglobulin by methylamine, and formation of anomalous complexes with trypsin

The unique steric inhibition of endopeptidases by human alpha(2)M (alpha(2)-macroglobulin) and the inactivation of the latter by methylamine were examined in relation to each other. Progressive binding of trypsin by alpha(2)M was closely correlated with the loss of the methylamine-reactive sites in alpha(2)M: for each trypsin molecule bound, two such sites were inactivated. The results further showed that, even at low proteinase/alpha(2)M ratios, no unaccounted loss of trypsin-binding capacity occurred. As alpha(2)M is bivalent for trypsin binding and no trypsin bound to electrophoretic slow-form alpha(2)M was observed, this indicates that the two sites must react (bind trypsin) in rapid succession. Reaction of [(14)C]methylamine with alpha(2)M was biphasic in time; in the initial rapid phase complex-formation with trypsin caused a largely increased incorporation of methylamine. In the subsequent slow phase trypsin had no such effect. These results prompted further studies on the kinetics of methylamine inactivation of alpha(2)M with time of methylamine treatment. It was found that conformational change of alpha(2)M and decrease in trypsin binding (activity resistant to soya-bean trypsin inhibitor) showed different kinetics. The latter decreased rapidly, following pseudo-first-order kinetics. Conformational change was much slower and followed complex kinetics. On the other hand, binding of (125)I-labelled trypsin to alpha(2)M did follow the same kinetics as the conformational change. This discrepancy between total binding ((125)I radioactivity) and trypsin-inhibitor-resistant binding of trypsin indicated formation of anomalous complexes, in which trypsin could still be inhibited by soya-bean trypsin inhibitor. Further examination confirmed that these complexes were proteolytically active towards haemoglobin and bound (125)I-labelled soya-bean trypsin inhibitor to the active site of trypsin. The inhibition by soya-bean trypsin inhibitor was slowed down as compared with reaction with free trypsin. The results are discussed in relation to the subunit structure of alpha(2)M and to the mechanism of formation of the complex.     

Characterization of thrombin binding to alpha 2-macroglobulin

The formation and structural characteristics of the human alpha 2-macroglobulin (alpha 2M)-thrombin complex were studied by intrinsic protein fluorescence, sulfhydryl group titration, electrophoresis in denaturing and nondenaturing polyacrylamide gel systems, and in macromolecular inhibitor assays. The interaction between alpha 2M and thrombin was also assessed by comparison of sodium dodecyl sulfate-gel electrophoretic patterns of peptides produced by Staphylococcus aureus V-8 proteinase digests of denatured alpha 2M-125I-thrombin and alpha 2M-125I-trypsin complexes. In experiments measuring fluorescence changes and sulfhydryl group exposure caused by methylamine, we found that thrombin produced its maximum effects at a mole ratio of approximately 1.3:1 (thrombin:alpha 2M). Measurements of the ability of alpha 2M to bind trypsin after prior reaction with thrombin indicated that thrombin binds rapidly at one site on alpha 2M, but occupies the second site with some difficulty. Intrinsic fluorescence studies of trypsin binding to alpha 2M at pH 5.0, 6.5, and 8.0 not only revealed striking differences in trypsin's behavior over this pH range, but also some similarities between the behavior of thrombin and trypsin not heretofore recognized. Structural studies, using sodium dodecyl sulfate-polyacrylamide gel electrophoresis to measure alpha 2M-125I-thrombin covalent complex formation, indicated that covalency reached a maximum at a mole ratio of approximately 1.5:1. At this ratio, only 1 mol of thrombin is bound covalently per mol of alpha 2M. These gel studies and those of proteolytic digests of denatured alpha 2M-125I-trypsin and alpha 2M-125I-thrombin complexes suggest that proteinases form covalent bonds with uncleaved alpha 2M subunits. The sum of our results is consistent with a mechanism of proteinase binding to alpha 2M in which the affinity of the proteinase for alpha 2M during an initial reversible interaction determines its binding ratio to the inhibitor.     

Reaction of alpha 2-macroglobulin with plasmin increases binding of transforming growth factors-beta 1 and beta 2.

The binding of 125I-transforming growth factors-beta 1 and beta 2 (TGF-beta 1 and TGF-beta 2) to alpha 2-macroglobulin (alpha 2M) was studied before and after reaction with plasmin, thrombin, trypsin, or methylamine. Complex formation between TGF-beta and native or reacted forms of alpha 2M was demonstrated by non-denaturing polyacrylamide gel electrophoresis and autoradiography. Reaction of native alpha 2M with plasmin or methylamine markedly increased the binding of 125I-TGF-beta 1 and 125I-TGF-beta 2 to alpha 2M. The alpha 2M-plasmin/TGF-beta complexes were minimally dissociated by heparin. Reaction of alpha 2M with thrombin or trypsin reduced the binding of 125I-TGF-beta 1 and 125I-TGF-beta 2; the resulting complexes were readily dissociated by heparin. Complexes between TGF-beta 2 and native or reacted forms of alpha 2M were less dissociable by heparin than the equivalent complexes with TGF-beta 1. These studies demonstrate that the TGF-beta-binding activity of alpha 2M is significantly affected by plasmin, thrombin, trypsin and methylamine. Observations that alpha 2M-plasmin preferentially binds TGFs-beta suggest a mechanism by which alpha 2M may regulate availability of TGFs-beta to target cells in vivo.     

Binding of IL-1 beta to alpha-macroglobulins and release by thioredoxin.

Human alpha 2-macroglobulin (H alpha 2M) is a major IL-1 beta binding plasma protein. The characteristics of the H alpha 2M IL-1 beta complex formation suggested, that cleavage of the internal thiol ester in other members of the alpha-macroglobulin family (alpha M) could enable these proteins to bind IL-1 beta. Characterization of optimal conditions for binding 125I IL-1 beta to H alpha 2M showed that H alpha 2M-IL-1 beta complex formation could be obtained over a pH range of 6.3 to 9 in the presence of some metal cations (i.e., Zn2+, Cd2+, Cu2+, Ni2+). Other divalent metal cations (i.e., Mn2+, Mg2+, Ca2+) were without effect. Time kinetic studies showed that binding of IL-1 beta to H alpha 2M was complete within 200 min and that H alpha 2M-IL-1 beta complexes became increasingly resistant to dissociation by boiling in SDS as a function of incubation time. Human pregnancy zone protein, rat alpha 1-, alpha 2-macroglobulin (R alpha 1M, R alpha 2M), all homologous with H alpha 2M, were tested for their ability to bind IL-1 beta. In each instance, alpha M-IL-1 beta complex formation was observed only after treatment of alpha M with methylamine, a primary amine that causes cleavage of the internal thiol ester in alpha M and the appearance of free thiol groups. Similarly, for each of these proteins, complex formation was increased several fold in the presence of Zn2+. Competition experiments using cytokines or proteins of similar molecular mass as IL-1 beta established that only unlabeled IL-1 beta was effective in inhibiting binding of 125I IL-1 beta to H"F" alpha 2M. Acylation of H"F" alpha 2M by diethylpyrocarbonate blocked the binding of IL-1 beta when analyzed by native PAGE. Deacylation of H"F" alpha 2M with hydroxylamine partially restored the binding capacity of H"F" alpha 2M further supporting the involvement of histidyl residues in the Zn2(+)-dependent binding of IL-1 beta. Reduced thioredoxin, but not its alkylated form, from Escherichia coli readily releases H"F" alpha 2M bound IL-1 beta under conditions that did not lead to reduction of disulfide bonds in H"F" alpha 2M. The action of thioredoxin also augmented IL-1-like activity in two independent bioassays suggesting that H"F" alpha 2M bound IL-1 beta is partially biologically inactive or latent. These results suggest that "activated" alpha M exert a modulating role for IL-1 beta by exposing specific binding sites, which are inaccessible in the native proteins.(ABSTRACT TRUNCATED AT 400 WORDS)     

Inhibition and partial reversal of the methylamine-induced conversion of "slow" to "fast" electrophoretic forms of human alpha 2-macroglobulin by modification of the thiols.

It has been shown previously [Van Leuven, F., Marynen, P., Cassiman, J. J., & Van den Berghe, H. (1982) Biochem. J. 203, 405-411] that 2,4-dinitrophenyl thiocyanate (DNPSCN) can block the conversion of "slow" to "fast" electrophoretic forms of human alpha 2-macroglobulin (alpha 2M) normally resulting from reaction of alpha 2M with methylamine. The kinetics of reaction of DNPSCN with alpha 2M in the presence of methylamine are examined here and shown to approximate pseudo first order, reflecting the rate-limiting reaction of alpha 2M with methylamine [Larsson, L. J., & Bj?rk, I. (1984) Biochemistry 23, 2802-2807]. One mole of DNPS is liberated per mole of free thiol in alpha 2M, consistent with cyanylation of the thiol liberated upon scission of the internal thiol esters by methylamine. I3(-) can also react with the methylamine-generated thiol groups of alpha 2M with a stoichiometry consistent with conversion of the thiol to a sulfenyl iodide. Reaction of the thiol groups with either DNPSCN or I3(-) inhibits the conversion of alpha 2M from the "slow" to the "fast" electrophoretic form. Furthermore, DNPSCN added after the conformational change can partially reverse the change. A similar reversal can be effected by cyanylation, with NaCN, of methylamine-treated alpha 2M in which the liberated thiols have first been converted to mixed disulfides by reaction with dithiobis(nitrobenzoic acid). Differential scanning calorimetry shows nearly identical properties for the methylamine-treated "fast" form and the cyanylated "slow" form of alpha 2M.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification of alpha 2-macroglobulin as a cytokine binding plasma protein. Binding of interleukin-1 beta to "F" alpha 2-macroglobulin

Treatment of normal human plasma with methylamine resulted in the discovery of an interleukin-1 beta(IL-1 beta) binding protein. The protein was labeled with 125I-IL-1 beta and the relative molecular mass (Mr) determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The protein-IL-1 beta complex had a Mr of approximately 400,000 in non-reducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis but became dissociated when exposed to beta-mercaptoethanol. The 125I-IL-1 beta labeled protein complex could be immunoprecipitated from plasma by using an anti-alpha 2-macroglobulin (alpha 2M) antiserum. Similarly, a monoclonal antibody (mAb) specific for electrophoretically fast ("F")alpha 2M was able to adsorb the 125I-IL-1 beta labeled complex from plasma. The mAb was also capable of adsorbing "F" alpha 2M-125I-IL-1 beta complexes from binary reaction mixtures, but failed to adsorb free 125I-IL-1 beta. Experiments carried out with purified plasma alpha 2M established that IL-1 beta became bound to alpha 2M only upon reaction with trypsin or methylamine, which results in the appearance of free thiol groups in alpha 2M ("F" alpha 2M). There was no binding of IL-1 beta to the native form of alpha 2M (electrophoretically slow or "S" alpha 2M), which lacks free thiol groups. Pretreatment of "F" alpha 2M with N-ethylmaleimide or [ethylenebis(oxyethylenenitrilo)] tetraacetic acid prevented complex formation between "F" alpha 2M and IL-1 beta. In contrast, the yield of "F" alpha 2M IL-1 beta complex formation was increased severalfold in the presence of 2.5 mM Zn2+. These findings indicate that "F" alpha 2M interacts with IL-1 beta through a thiol-disulfide exchange reaction. Zn2+ may play a major role in bringing together the reactive domains of the adjoining peptide backbones into proper orientation. The ready complex formation between "F" alpha 2M and the pleiotropic cytokine IL-1 beta suggests a novel biological role for "F" alpha 2M, since "F" alpha 2M-IL-1 beta complexes, but not "F" alpha 2M alone, retained IL-1-like activity in the thymocyte costimulator bioassay.     

Three-dimensional reconstruction of a complex of human alpha 2-macroglobulin with monomaleimido Nanogold (Au1.4nm) embedded in ice.

Cysteine 949 and glutamine 952 are known to be part of the thiol ester site of each of the four subunits of human alpha 2-macroglobulin (alpha 2M). The hydrolysis of this thiol ester bound to methylamine results in the incorporation of the amine and liberation of a free sulfhydryl group that can be specifically labeled. Therefore, a high-resolution marker specific for the sulfhydryl groups, the monomaleimido Nanogold (Au1.4nm) cluster was used to bind this amino acid. After cryoelectron microscopy, a three-dimensional reconstruction of the alpha 2M-Nanogold conjugates (alpha 2M-Au1.4nm) was achieved, revealing the internal location of the thiol ester sites in the transformed alpha 2M molecules. From this study we propose three possible locations for the cysteine 949.     

Alpha 2-macroglobulin is the primary inhibitor of miniplasmin in vitro and in vivo in the mouse. Comparison with alpha 2-antiplasmin in simultaneous reaction experiments.

Miniplasmin reacted rapidly with purified human alpha 2-macroglobulin (alpha 2M). More than 98% of the complexes were stabilized by at least one covalent bond. The second-order rate constant for the reaction of alpha 2M with miniplasmin at 4 degrees C was 5.1 x 10(5) M-1.s-1. This value was determined by measuring the formation of covalent alpha 2M-125I-miniplasmin complex; however, the rate constant most likely reflects the bait-region cleavage step in the reaction mechanism. Miniplasmin bound primarily to alpha 2M when incubated at 37 degrees C with various mixtures of alpha 2-antiplasmin (alpha 2AP) and alpha 2M. A 2.4-fold molar excess of alpha 2AP was required to yield an equal distribution of proteinase between the two inhibitors. alpha 2M was the primary miniplasmin inhibitor in human and murine plasma (4 degrees C and 37 degrees C). The extent of covalent-bond formation with murine alpha 2M was approx. 96%. Intravenously injected miniplasmin cleared rapidly from the circulation of mice and was recovered principally in the liver. The catabolic pathway was distinctly different from that of miniplasminogen, which was sequestered mainly in the kidneys. The rate of miniplasmin clearance was much faster than that of purified alpha 2AP-miniplasmin complex, suggesting reaction with alpha 2M in vivo. This was confirmed in clearance competition experiments with alpha 2M-methylamine.     

The conformational changes of alpha 2-macroglobulin induced by methylamine or trypsin. Characterization by extrinsic and intrinsic spectroscopic probes.

The conformational changes around the thioester-bond region of human or bovine alpha 2M (alpha 2-macroglobulin) on reaction with methylamine or trypsin were studied with the probe AEDANS [N-(acetylaminoethyl)-8-naphthylamine-1-sulphonic acid], bound to the liberated thiol groups. The binding affected the fluorescence emission and lifetime of the probe in a manner indicating that the thioester-bond region is partially buried in all forms of the inhibitor. In human alpha 2M these effects were greater for the trypsin-treated than for the methylamine-treated inhibitor, which both have undergone similar, major, conformational changes. This difference may thus be due to a close proximity of the thioester region to the bound proteinase. Reaction of trypsin with thiol-labelled methylamine-treated bovine alpha 2M, which retains a near-native conformation and inhibitory activity, indicated that the major conformational change accompanying the binding of proteinases involves transfer of the thioester-bond region to a more polar environment without increasing the exposure of this region at the surface of the protein. Labelling of the transglutaminase cross-linking site of human alpha 2M with dansylcadaverine [N-(5-aminopentyl)-5-dimethylaminonaphthalene-1-sulphonamide] suggested that this site is in moderately hydrophobic surroundings. Reaction of the labelled inhibitor with methylamine or trypsin produced fluorescence changes consistent with further burial of the cross-linking site. These changes were more pronounced for trypsin-treated than for methylamine-treated alpha 2M, presumably an effect of the cleavage of the adjacent 'bait' region. Solvent perturbation of the u.v. absorption and iodide quenching of the tryptophan fluorescence of human alpha 2M showed that one or two tryptophan residues in each alpha 2M monomer are buried on reaction with methylamine or trypsin, with no discernible change in the exposure of tyrosine residues. Together, these results indicate an extensive conformational change of alpha 2M on reaction with amines or proteinases and are consistent with several aspects of a recently proposed model of alpha 2M structure [Feldman, Gonias & Pizzo (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 5700-5704].     

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.