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.     

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)     

Proteolysis of human alpha 2-macroglobulin without hydrolysis of the internal thiolesters or expression of the receptor recognition site

Proteolysis of human alpha 2-macroglobulin (alpha 2M) in the bait region is the prerequisite and necessary trigger for the trapping of the proteinase by a massive conformational change of alpha 2M. This labilization of the native conformation of alpha 2M is mediated by activation of the internal thiolesters, but the underlying mechanism is unknown. We now describe observations on proteolysis of human alpha 2M without concomitant hydrolysis of the internal thiolesters or conformational change. This proteolysis was obtained with a novel bacterial proteinase we recently used to isolate the receptor-binding domain from alpha 2M (Van Leuven, F., Marynen, P., Sottrup-Jensen, L., Cassiman, J.-J., and Van Den Berghe, H. (1986) J. Biol. Chem. 261, 11369-11373). This proteinase is not inhibited by alpha 2M, and therefore it was possible to study its effect on native alpha 2M at pH 4.5, conditions used previously to produce the receptor-binding domain (Van Leuven, F., Marynen, P., Sottrup-Jensen, L., Cassiman, J.-J., and Van Den Berghe, H. (1986) J. Biol. Chem. 261, 11369-11373). The major observations are that despite extensive proteolysis, alpha 2M largely retained its native conformation as shown by rate electrophoresis, the absence of binding of monoclonal antibody F2B2, and the incorporation of [14C]methylamine into a 145-kDa fragment of alpha 2M. Moreover, the derivative still bound trypsin to 88% of control values. Treatment of the derivative with trypsin or methylamine produced the conformational change as with intact alpha 2M, and concomitantly released the receptor-binding domain. This indicated that proteolysis at Lys1313-Glu also proceeded in native alpha 2M. At least one more major proteolysis site was deduced from the observation of a 27-kDa heat-induced fragment, the 145-kDa [14C]methylamine-labeled fragment, and from the presence of the 20-kDa receptor-binding domain. These results demonstrate indirectly the particular relation of the bait region to the internal thiolesters and illustrate further the domain-structure of alpha 2M and the expression of the receptor-recognition site by activation of the internal thiolesters.     

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)     

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.     

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].     

Analysis of thiolester bond cleavage-dependent conformational changes in binary alpha 2-macroglobulin-proteinase complexes

The structures of the two proteinase-binding sites in human alpha 2-macroglobulin (alpha 2M) were probed by treatment of alpha 2M with the serine proteinases thrombin and plasmin. Each proteinase forms an equimolar complex with alpha 2M (a binary alpha 2M-proteinase complex) which results in the activation and cleavage of two internal thiolester bonds in alpha 2M. Binary alpha 2M-proteinase complexes demonstrated an incomplete conformational change as determined by nondenaturing polyacrylamide gel electrophoresis and incomplete receptor recognition site exposure as determined by in vivo plasma elimination studies. Treatment of binary alpha 2M-proteinase complexes with CH3NH2, trypsin, or elastase resulted in cleavage of an additional one or two thiolester bonds in alpha 2M and complete receptor recognition site exposure, demonstrating that a limited conformational change had occurred. Treatment of the alpha 2M-thrombin complex with elastase resulted in the incorporation of approximately 0.5 mol proteinase/mol alpha 2M and completion of the conformational change in the complex. Similar treatment of the alpha 2M-plasmin complex resulted in the incorporation of less than 0.1 mol proteinase/mol alpha 2M. Unlike the alpha 2M-thrombin complex, the alpha 2M-plasmin complex did not undergo a complete conformational change following treatment with CH3NH2 or trypsin. Incubation of this complex with elastase resulted in proteolysis of the kringle 1-4 region of the alpha 2M-bound plasmin heavy chain, and following this treatment the alpha 2M-plasmin complex underwent a complete conformational change. The results of this investigation demonstrate that binary alpha 2M-proteinase complexes retain a relatively intact proteinase-binding site. In the case of the alpha 2M-plasmin complex, however, the heavy chain of alpha 2M-bound plasmin protrudes from the proteinase-binding site and prevents a complete conformational change in the complex despite additional thiolester bond cleavage.     

Clearance and binding of two electrophoretic "fast" forms of human alpha 2-macroglobulin

These studies explore the role of conformational change and exposed carbohydrate residues in the clearance of alpha 2-macroglobulin-trypsin (alpha 2M-T) complexes in the mouse. Human alpha 2-macroglobulin (alpha 2M) was purified and demonstrated to be homogeneous in the electrophoretic "slow" form. Two conformationally altered derivatives, alpha 2M-T and alpha 2-macroglobulin-methylamine (alpha 2M-MeNH2), were prepared and demonstrated to exist in the electrophoretic "fast" form. Radiolabeled alpha 2M-T and alpha 2M-MeNH2 were cleared rapidly with a half-life of 2-4 min following injection into mice. Radiolabeled native alpha 2M, however, remained in the circulation with a half-life of several hours. Both alpha 2M-T and alpha 2M-MeNH2 bound specifically to mouse peritoneal macrophages at 4 degrees C and occupancy of receptor sites increased with increasing time and radioligand concentration. Excess amounts of unlabeled alpha 2M-T or alpha 2M-MeNH2 cross-completed with trace amounts of the other in both clearance studies and binding assays, indicating that both derivatives were removed by the same receptor pathway. The clearance and binding of alpha 2M-T and alpha 2M-MeNH2 were not inhibited by excess amounts of unlabeled asialoorosomucoid, fucosyl-bovine serum albumin, mannosyl-BSA, or N-acetylglucosaminyl-BSA. Our results indicate that the clearance pathway removing alpha 2M-T complexes from the circulation recognizes a fundamental conformational change in alpha 2M secondary to protease binding, which can also be induced by exposure to methylamine. Therefore, other chemical or physical alterations that occur in alpha 2M upon binding trypsin, apart from the conformational change also present in alpha 2M-MeNH2, do not seem necessary for the recognition of alpha 2M-T by cells in the clearance pathway. In addition, this pathway appears distinct from several systems already described mediating clearance of glycoproteins through recognition of terminal galactose, fucose, N-acetylglucosamine, or mannose on oligosaccharide side chains.     

Purification and characterization of frog alpha-macroglobulin: receptor recognition of an amphibian glycoprotein

Frog alpha-macroglobulin was purified to apparent homogeneity by Ni2+ chelate affinity chromatography. Frog alpha-macroglobulin migrated as an alpha 1-globulin in cellulose acetate electrophoresis. A molecular weight of 730 000 was obtained by equilibrium sedimentation, and in sodium dodecyl sulfatepolyacrylamide gel electrophoresis (SDS-PAGE), the protein migrated as a single band of Mr approximately 360 000 before reduction and Mr approximately 180 000 after reduction. Treatment with trypsin resulted in subunit cleavage to yield a fragment of Mr approximately 90 000. After being heated, the protein fragmented, migrating in SDS-PAGE as two bands of Mr approximately 120 000 and 60 000. This fragmentation was inhibited by prior reaction of the protein with methylamine. In native pore-limit electrophoresis the protein exhibited the characteristic "slow" to "fast" conformational change of protease-treated alpha-macroglobulins. In contrast, typical "slow" to "fast" conformational change was not observed in native PAGE with this preparation. Moreover, the protein incorporated approximately 2 mol of [14C]methylamine/mol of inhibitor without demonstrating a change in mobility in native PAGE. In circular dichroism studies, the protein exhibited a spectrum similar to that of human alpha 2M. Reaction with trypsin resulted in a broadening and decrease in the magnitude of the spectrum. Reaction with methylamine resulted in similar changes, but of smaller magnitude. The inhibitor bound approximately 0.7 mol of trypsin in both radiolabeled protease binding and amidolytic titration studies. 125I-Labeled native frog alpha 1M was removed slowly from the circulation of mice with a t1/2 greater than 2h.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes of the proteinase binding properties and conformation of bovine alpha 2-macroglobulin on cleavage of the thio ester bonds by methylamine

Cleavage of the thio ester bonds of human alpha2-macroglobulin (alpha 2M) by methylamine leads to an extensive conformational change and to inactivation of the inhibitor. In contrast, cleavage of these bonds in bovine alpha 2M only minimally perturbs the hydrodynamic volume of the protein [Dangott, L. J., & Cunningham, L. W. (1982) Biochem. Biophys. Res. Commun. 107, 1243-1251], as well as its spectroscopic properties, as analyzed by ultraviolet difference spectroscopy, circular dichroism, and fluorescence in this work. A conformational change analogous to that undergone by human alpha 2M thus does not occur in the bovine inhibitor. However, changes of several functional properties of bovine alpha 2M are induced by the amine. The apparent stoichiometry of inhibition of trypsin thus is reduced from about 1.2 to about 0.7 mol of enzyme/mol of inhibitor. In spite of this decrease, the interaction with the proteinase induces similar conformational changes in methylamine-treated alpha 2M as in intact alpha 2M, as revealed by spectroscopic analyses, indicating that the mode of binding of the proteinase to the inhibitor is essentially unperturbed by thio ester bond cleavage. The reaction with methylamine also greatly increases the sensitivity of bovine alpha 2M to proteolysis by trypsin at sites other than the "bait" region. Moreover, the second-order rate constant for the reaction with thrombin is reduced by about 10-fold. These results indicate that the thio ester bonds of bovine alpha 2M, although not required per se for the binding of proteinases, nevertheless are responsible for maintaining certain structural features of the inhibitor that are of importance for full activity.     

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.     

Horse alpha 2-macroglobulin. Circular dichroism studies of conformational changes upon reaction with proteinases and methylamine

The interaction of horse alpha 2-macroglobulin with methylamine, trypsin and cathepsin D was studied by circular dichroism in the far and near UV region, by polyacrylamide gel electrophoresis and by determination of its inhibitory activity. The CD spectra of horse alpha 2-macroglobulin resemble those of bovine und human alpha 2-macroglobulin. The CD spectra were changed in a different manner after the interaction of alpha 2-macroglobulin with methylamine, trypsin and inactive or active cathepsin D, indicating that more than one conformational change occurs. Cathepsin D activity was not affected by complex formation with horse alpha 2-macroglobulin. In contrast to the action of trypsin, treatment with methylamine did not increase the electrophoretic mobility of alpha 2-macroglobulin.     

Mutation of lysine 1370 in full-length human alpha2-macroglobulin blocks binding to the low density lipoprotein receptor-related protein-1

alpha2-Macroglobulin (alpha2M) regulates cell physiology by binding to cellular receptors; however, residues that contribute to receptor-binding have not been elucidated in the full-length protein. In alpha2M fragments, expressed in bacteria, Lys(1370) and Lys(1374) are critical for binding to the low density lipoprotein receptor-related protein-1 (LRP-1) and a distinct alpha2M-signaling receptor. We expressed full-length recombinant human alpha2M (r(alpha)2M) and mutants in which Lys(1370) or Lys(1374) was converted to alanine in K-562 cells. The r(alpha)2M species demonstrated intact structure and function, as determined by subunit size, intersubunit disulfide bonds, reaction with trypsin or methylamine, and ability to undergo conformational change. Binding of transforming growth factor-beta1 was unaltered. Mutation of Lys(1370) almost entirely inhibited specific binding of methylamine-activated r(alpha)2M to RAW 264.7 cells. Mutation of Lys(1374) had no effect. Binding of r(alpha)2M to RAW 264.7 cells was blocked by receptor-associated protein, indicating an essential role for LRP-1. These studies demonstrate that a single mutation in full-length r(alpha)2M is sufficient to block binding to LRP-1.     

Conformation and protease binding activity of binary and ternary human alpha 2-macroglobulin-protease complexes

Human alpha 2-macroglobulin (alpha 2M) undergoes a conformational change after reaction with proteases. In this report, it is shown that although two trypsin molecules may bind simultaneously to each alpha 2M, only one trypsin is necessary to induce alpha 2M conformational change. Ternary complexes of alpha 2M and either two radioiodinated trypsins or two nonradioiodinated trypsins were purified by gel filtration chromatography. The nonradioactive complex did not bind 125I-trypsin, even after incubation for 24 h with the free protease present at a large molar excess. Under comparable conditions, a large molar excess of nonradioactive trypsin did not cause significant dissociation of the complex prepared with radioiodinated protease. Equations are presented that distinguish between two separate models of protease binding and demonstrate that binary alpha 2M-trypsin complex retains no significant trypsin binding activity despite the presence of a vacant protease binding site. Purified alpha 2M-plasmin complex, with 1.10 mol of plasmin/mol of inhibitor, also retained no trypsin binding activity as assessed with radioiodinated protein binding experiments. These studies suggest that reactions of alpha 2M with proteases are accurately described by the "trap hypothesis" (Barrett, A. J., and Starkey, P. M. (1973) Biochem. J. 133, 709-724) independent of protease size or binding stoichiometry.     

The primary structures of Pseudomonas AM1 amicyanin and pseudoazurin. Two new sequence classes of blue copper proteins.

After cleavage of the thioester bonds of human alpha 2-macroglobulin (alpha 2M) by methylamine, the inhibitor undergoes an extensive conformational change and loses its ability to bind proteinases. In contrast, similar cleavage in the presence of dinitrophenyl thiocyanate, a reagent that cyanylates the liberated thiol groups, does not change the mobility of alpha 2M in gel electrophoresis, and the inhibitor also retains activity [Van Leuven, Marynen, Cassiman & Van den Berghe (1982) Biochem. J. 203, 405-411]. Analyses in this work show that also the spectroscopic properties of alpha 2M are essentially unperturbed under these conditions. These observations are consistent with the major change of the conformation of the protein having been arrested by the cyanylation reaction. However, several functional properties of the protein are altered, indicating that a limited conformational change does occur. The apparent stoichiometry of binding of trypsin is thus decreased to about 0.5 mol of enzyme/mol of alpha 2M. Nevertheless trypsin induces a similar conformational change in all molecules of the modified inhibitor as that induced in untreated alpha 2M. This behaviour indicates a similar mode of binding of the enzyme to the modified alpha 2M as to intact alpha 2M, but also a high extent of non-productive activation of binding sites in the modified inhibitor. A further difference to untreated alpha 2M is that most of the bound trypsin molecules react considerably faster with soya-bean trypsin inhibitor. The rate of inhibition of thrombin is also greatly decreased, and the modified inhibitor is more sensitive than untreated alpha 2M to proteolysis at sites outside the ''bait'' region. The properties of the cyanylated human alpha 2M are thus similar to those of bovine alpha 2M in which the thioester bonds have been cleaved by methylamine in the absence of the cyanylating reagent [Björk, Lindblom & Lindahl (1985) Biochemistry 24, 2653-2660]. These results indicate that the thioester bonds of human and bovine alpha 2M are not required as such for the stability of the gross conformation of the protein or for the binding of proteinases. Nevertheless they participate directly in maintaining certain structural features, similar in the two inhibitors, that are necessary for full proteinase-binding ability. Disruption of these structures leads to a slower and less efficient trapping of the enzymes.     

Inactivation of the plasma protease inhibitor alpha 2-macroglobulin by the antitumor drug cis-dichlorodiamineplatinum(II)

The plasma protease inhibitor alpha 2-macroglobulin (alpha 2M) was reacted in vitro with cis-dichlorodiamineplastinum(II) (cis-DDP). Following the reaction, alpha 2M demonstrated a significantly decreased ability to bind trypsin as determined by esterase activity assays in the presence of soybean trypsin inhibitor and studies with radiolabeled trypsin. Inactivation of alpha 2M by cis-DDP was not associated with a conversion to the "fast" electrophoretic form, as determined on nondenaturing gels, in contrast to the inactivation of alpha 2M by proteases and certain amine salts. The extent of reaction increased with the elevation of temperature within the thermal stability range of the protein; however, variation of pH within the range 6.82-8.55 had little effect. Binding of [14C]methylamine to alpha 2M was not affected by cis-DDP. The conformational change, however, which normally accompanies this reaction did not occur. It is concluded that the alpha 2M thiolesters are most likely not reactive sites for cis-DDP. cis-DDP-treated alpha 2M failed to dissociate into quarter subunits under denaturing and reducing conditions, suggesting cross-linking of subunits. This cross-linking may be responsible for locking the alpha 2M quarternary structure into the "slow conformation."     

Subunits of human alpha 2-macroglobulin produced by specific reduction of interchain disulfide bonds with thioredoxin

Disulfide bonds in alpha 2-macroglobulin (alpha 2M) were reduced with the thioredoxin system from Escherichia coli. Under the conditions selected, 3.5-4.1 disulfide bonds were cleaved in each alpha 2M molecule, as determined by the consumption of NADPH during the reaction and by the incorporation of iodo[3H]acetate into the reaction product. This extent of disulfide bond reduction, approximately corresponding to that expected from specific cleavage of all four interchain disulfide bonds of the protein, coincided with the nearly complete dissociation of the intact alpha 2M molecule to a species migrating as an alpha 2M subunit in gel electrophoresis, under both denaturing and nondenaturing conditions. The dissociation was accompanied by only small changes of the spectroscopic properties of the subunits, which thus retain a near-native conformation. Reaction of isolated subunits with methylamine or trypsin led to the appearance of approximately 0.55 mol of thiol group/mol of subunits, indicating that the thio ester bonds are largely intact. Moreover, the rate of cleavage of these bonds by methylamine was similar to that in the whole alpha 2M molecule. Although the bait region was specifically cleaved by nonstoichiometric amounts of trypsin, the isolated subunits had minimal proteinase binding ability. Reaction of subunits with methylamine or trypsin produced changes of farultraviolet circular dichroism and near-ultraviolet absorption similar to those induced in the whole alpha 2M molecule, although in contrast with whole alpha 2M no fluorescence change was observed. The methylamine- or trypsin-treated subunits reassociated to a tetrameric species, migrating as the "fast" form of whole alpha 2M in gradient gel electrophoresis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Probing the stability of native and activated forms of alpha2-macroglobulin

alpha2-Macroglobulin (alpha2M) is a 718 kDa homotetrameric proteinase inhibitor which undergoes a large conformational change upon activation. This conformational change can occur either by proteolytic attack on an approximately 40 amino acid stretch, the bait region, which results in the rupture of the four thioester bonds in alpha2M, or by direct nucleophilic attack on these thioesters by primary amines. Amine activation circumvents both bait region cleavage and protein incorporation, which occurs by proteolytic activation. These different activation methods allow for examination of the roles bait region cleavage and thioester rupture play in alpha2M stability. Differential scanning calorimetry and urea gel electrophoresis demonstrate that both bait region cleavage and covalent incorporation of protein ligands in the thioester pocket play critical roles in the stability of alpha2M complexes.     

Reaction of proteinases with alpha 2-macroglobulin: evidence for alternate reaction pathways in the inhibition of trypsin

Titration experiments were employed to measure the binding stoichiometry of alpha 2M for trypsin at high and low concentrations of reactants. These titration experiments were performed by measuring the SBTI-resistant trypsin activity and by direct binding measurements using 125I-labeled trypsin. The binding stoichiometry displayed a marked dependence upon protein concentration. At high alpha 2M concentrations (micromolar), 2 mol of trypsin are bound/mol of inhibitor. However, at low alpha 2M concentrations (e.g., 0.5 nM), only 1.3 mol of trypsin were bound/mol of inhibitor. Sequential additions of subsaturating amounts of trypsin to a single aliquot of alpha 2M also resulted in a reduction in the final binding ratio. A model has been formulated to account for these observations. A key element of this model is the observation that purified 1:1 alpha 2M-proteinase complexes are not capable of binding a full mole of additional proteinase [Strickland et al. (1988) Biochemistry 27, 1458-1466]. The model predicts that once the 1:1 alpha 2M-proteinase complex forms, this species undergoes a time-dependent conformational rearrangement to yield a complex with greatly reduced proteinase binding ability. According to this model, the ability of alpha 2M to bind 2 mol of proteinase depends upon the association rate of the second enzyme molecule with the binary (1:1) complex, the enzyme concentration, and the rate of the conformational alteration that occurs once the initial complex forms. Modeling experiments suggest that the magnitude of the rate constant for this conformational change is in the order of 1-2 s-1.     

Physical properties of human alpha 2-macroglobulin following reaction with methylamine and trypsin

Circular dichroism spectroscopy, sedimentation velocity and ultraviolet difference spectroscopy were used to compare alpha 2-macroglobulin, alpha 2-macroglobulin-trypsin complex and alpha 2-macroglobulin-methylamine complex. The circular dichroic spectrum of native alpha 2-macroglobulin is significantly changed in shape and magnitude following reaction with either trypsin or methylamine. The spectra of alpha 2-macroglobulin-trypsin and alpha 2-macroglobulin-methylamine are, however, indistinguishable. The ultraviolet difference spectrum between alpha 2-macroglobulin-methylamine and native alpha 2-macroglobulin displays a tyrosine blue shift consistent with the exposure of several tyrosine residues to solvent. The conformational change which occurs in alpha 2-macroglobulin during reaction with methylamine follows pseudo-first-order kinetics. T 1/2 was 10.5 min for the reaction with 200 mM methylamine at pH 8.0 and 45 min for the reaction with 50 mM methylamine, also at pH 8.0. Reaction of methylamine with alpha 2-macroglobulin results in loss of trypsin-binding activity which appears to be a direct consequence of the conformational change induced by methylamine. A sedimentation coefficient (S0(20),W) of 20.5 was determined for alpha 2-macroglobulin-methylamine compared to a value of 18.5 for unreacted alpha 2-macroglobulin. This increase in sedimentation velocity is attributed to a 10% decrease in alpha 2-macroglobulin Stokes radius. alpha 2-Macroglobulin-trypsin complex prepared by reaction of the protease at a 2-fold molar excess with the inhibitor was a S0(20),W of 20.3. Although this sedimentation coefficient does reflect compacting of the alpha 2-macroglobulin structure compared to native alpha 2-macroglobulin, it is not large enough to rule out significant protrusion of the proteases from pockets in the alpha 2-macroglobulin structure.