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

A recombinant bait region mutant of human alpha2-macroglobulin exhibiting an altered proteinase-inhibiting spectrum

Alpha 2-macroglobulin (alpha2M), a plasma glycoprotein produced in the liver, inhibits a variety of proteinases and thus considered to play important homeostatic roles in the body. This broad inhibitory spectrum has been explained by the trapping theory by which a proteinase recognizes a region of 25-30 amino acid peptide in alpha2M called bait region and cleaves it, leading to the conformational change of alpha2M, and to the subsequent entrapment and inhibition of the proteinase. We constructed alpha2M cDNAs with mutated DNA sequences in the bait region, and obtained recombinant CHO cell lines producing either wild type alpha2M, or mutant alpha2Ms, i.e., alpha2M/K692 and alpha2M/K696, each with substitution of Arg with Lys at codons 692 and 696, respectively. We tested if lysyl endopeptidase is not inhibited by wild type alpha2M, but could be inhibited by these engineered mutant alpha2Ms. Thus, recombinant alpha2M/K696 protein successfully inhibited lysyl endopeptidase activity, while recombinant alpha2M/K692 protein was not sensitive to lysyl endopeptidase, suggesting that not all bait region peptide bonds can equally be accessible and susceptible to proteinases. The present results not only provided the trapping theory with additional supportive evidence, but the first experimental evidence for the value of engineered alpha2M-derived proteinase inhibitor with an artificial proteinase inhibitory spectrum of potential industrial and/or therapeutic usefulness.

The properties of rabbit alpha1-macroglobulin upon activation are distinct from those of rabbit and human alpha2-macroglobulins

We have characterized native and activated forms of rabbit alpha1M and compared them to rabbit and human alpha2M. Similar to human alpha2M, rabbit alpha1M is a tetramer associated via disulfide bonds and non-covalent interactions that exhibits autolysis into two fragments when heated. Like human alpha2M, rabbit alpha1M is cleaved by trypsin at one site; however, rabbit alpha1M shares characteristics with rabbit alpha2M that are different from the properties of human alpha2M. Amine or trypsin treatment of rabbit alpha-macroglobulins does not result in a significant conformational change or cleavage of four thiolester bonds. Full thiolester cleavage is only observed for rabbit alpha1M after exposure to both trypsin and a small amine. Additionally, amine-treated rabbit alpha-macroglobulins retain trypsin inhibitory potential and do not fully shield bound proteinases. Methylamine and trypsin treatment of rabbit alpha1M results in two dissimilar conformations that display differing exposure of the receptor-recognition site. While ammonia- and methylamine-modified rabbit alpha1M bind to macrophages with similar affinity to that of human alpha2M, trypsin-treated rabbit alpha1M exhibits dramatically lower affinity. This suggests that rabbit alpha1M may not play the same proteinase-inhibiting physiological role as human alpha2M.

Isolation and characterization of an alpha-macroglobulin from the gastropod mollusc Helix pomatia with tetrameric structure and preserved activity after methylamine treatment

A proteinase inhibitor with M(r) 697000 and 20.3% (w/w) carbohydrate was isolated from the haemolymph of the snail Helix pomatia and characterized. It was shown to have a tetrameric structure with subunits disulphide linked by two. It inhibited the activity of several types of proteinases against large substrates but not that of trypsin against N-alpha-benzoyl-DL-arginine-4-nitroanilide. This indicated a nonspecific and steric hindrance mode of inhibition. The ratio of trypsin molecules inactivated per inhibitor amounted to 1.5. This interaction led to a cleavage of the subunits into two equal fragments and to a slow to fast conformational change of the whole molecules. Experiments with 125I-labelled trypsin indicated that the proteinase had become covalently linked to one of the fragments. Heating of the inhibitor led to autolytic cleavage products but not when methylamine treated. Thiol titration after trypsin or methylamine treatment indicated the presence of one thiol ester bond per subunit. These facts are all indicative of an alpha-macroglobulin type of inhibitor. However, unlike for most of them the methylamine treatment did not induce a conformational change nor suppress its proteinase inhibitory activity. Moreover, invertebrate alpha-macroglobulins are mostly dimeric in structure but tetramers likewise do occur in Biomphalaria glabrata.

The structure of the C949S mutant human alpha(2)-macroglobulin demonstrates the critical role of the internal thiol esters in its proteinase-entrapping structural transformation

A three-dimensional reconstruction of a protein-engineered mutant alpha(2)-macroglobulin (alpha(2)M) in which a serine residue was substituted for the cysteine 949 (C949S), making it unable to form internal thiol ester moieties, was compared with native and methylamine-transformed alpha(2)Ms. The native alpha(2)M structure consists of two oppositely oriented Z-shaped strands. Thiol ester cleavage following an encounter with a proteinase or a nucleophilic attack by methylamine causes a structural transformation in which the strands assume an opposite handedness and a significant portion of the protein density migrates from the distal ends of the molecule toward the center. The C949S mutant showed a protein density distribution very similar to that of transformed alpha(2)M, with a compact central region of protein density connected to two receptor-binding arms on each end of the molecule. Since no particle shapes characteristic of native or half-transformed alpha(2)Ms were seen in electron micrographs and the C949S mutant and alpha(2)M-methylamine structures are highly similar, we conclude that the intact thiol esters maintain native alpha(2)M in a quasi-stable state. In their absence, alpha(2)M folds into the more stable transformed structure, which displays the functionally important receptor-binding domains and contains the proteinase-entrapping internal cavity.

Prevention of the influence of fibrin and alpha2-macroglobulin in the continuous measurement of the thrombin potential: implications for an endpoint determination of the optical density

We proposed the endogenous thrombin potential (ETP) as an overall function test of the coagulation system. We recently introduced a routine test which requires defibrinated plasma. In order to develop an assay in which the ETP-value can be directly obtained by measuring the optical density, we investigated two methods to inhibit fibrinogen clottability and to inactivate alpha2-macroglobulin. The first method makes use of hydroxylamine to inactivate alpha2-macroglobulin and H-Gly-Pro-Arg-Pro-OH to inhibit fibrin polymerization. At pH 7.35, plasma incubated with 25 mM hydroxylamine and 1.5 mg/mL H-Gly-Pro-Arg-Pro-OH for 5 minutes at 37 degrees C resulted in a reduced endlevel of the amidolytic activity on small chromogenic substrates. The second method uses a metalloprotease purified from Crotalus basiliscus to remove alpha2-macroglobulin from plasma in combination with H-Gly-Pro-Arg-Pro-OH. Herein plasma is incubated with 3.5 LM protease during 15 minutes at 37 degrees C in the presence of 1 mg/mL polymerization inhibitor. The enzymatic method results in a zero endlevel of the amidolytic activity and this would imply that measurement of the ETP is reduced to an endpoint determination of the optical density. We show that the endpoint determination of the optical density correlates well with the calculated ETP in plasmas with different degrees of anticoagulation.

Bait region involvement in the dimer-dimer interface of human alpha 2-macroglobulin and in mediating gross conformational change. Evidence from cysteine variants that form interdimer disulfides

We have characterized four human alpha 2-macroglobulin (alpha 2M) bait region variants (G679C, M690C, V700C, and T705C) to test the hypothesis that the bait regions are involved in the interface between noncovalently associated dimers. All four variants folded correctly as judged by many normal properties. However, the presence of a cysteine resulted in disulfide formation between otherwise noncovalently associated dimers in all four variants. The extent of disulfide cross-linking varied with the location of the cysteine and gave a mixture of species that probably contained two, one, or zero interdimer disulfides in the tetramer. This was reflected in heterogeneity of conformational change upon thiol ester cleavage by methylamine, with the presence of crosslinks correlating with blockage of conformational change. The stoichiometry of trypsin inhibition was less in all cases than for wild-type alpha 2M. The M690C variant also showed evidence of some species with an intramolecular disulfide between bait regions of monomers within the same dimer. Taken together, the results are consistent with a location of the four bait regions in contact with, or in very close proximity to, one another. This suggests that they form all or part of the "cavity body" seen in the low resolution x-ray structure of transformed alpha 2M.

Critical role of asparagine 1065 of human alpha2-macroglobulin in formation and reactivity of the thiol ester

It has been shown that the relative reaction preference of the C4 thiol ester toward oxygen and nitrogen nucleophiles upon activation by proteinase depends on whether residue 1106 is aspartate or histidine (Dodds, A. W., Ren, X.-D., Willis, A. C., and Law, S. K. A. (1996) Nature 379, 177-179). To determine if the equivalent residue in the related thiol ester-containing protein human alpha2-macroglobulin (alpha2M), asparagine 1065, plays a similar role, we have expressed and characterized four alpha2M variants in which this asparagine has been replaced by aspartate, alanine, histidine, or lysine. The change from asparagine resulted in an altered ability to form the thiol ester. This ranged from failure to form the thiol ester (Asn --> Asp) to a maximum extent of formation of about 50% (Asn --> Ala). For the three variants that were able to form the thiol ester, the rates of thiol ester cleavage by a given amine were found to be different from one another and slower in nearly all cases than plasma alpha2M, but with the same relative reactivity of methylamine > ethylamine > ammonia. The rate of conformational change that follows cleavage of thiol esters in a functional half-molecule was also found to differ between the variants and to be slower than plasma alpha2M. TNS emission spectra indicated that the conformations of the transformed variants differed measurably from transformed plasma alpha2M. These findings suggest that residue 1065 plays a critical role in human alpha2M, for formation of the thiol ester, for its subsequent reaction with nucleophiles, and for the conformational change induced by this reaction. By analogy with C4, where this residue influences the nucleophile preference through direct interaction with the thiol ester, residue 1065 in alpha2M is expected to be located in or very close to the thiol ester region in alpha2M.

The contact zones in human alpha2-macroglobulin--functional domains important for the regulation of the trapping mechanism

A functional domain termed the contact zone, which is the region of a subunit interacting with another non-covalently bound subunit, is suggested to play a decisive role in the trapping mechanism of human alpha2-macroglobulin. Tetrameric alpha2-macroglobulin can be dissociated into stable dimers with intact thiol esters by sodium thiocyanate, whereby the contact zones are disrupted. The dissociation leads to significant conformational changes, as studied by ultraviolet-difference spectroscopy, CD, fluorescence and affinity partitioning. The conformation of the dimers is similar to that of MeNH2-treated alpha2-macroglobulin, in which the thiol esters are cleaved, a conformational state with a closed trap occurs, and receptor-recognition sites are exposed. The receptor-binding domain is at least partly exposed in the dimer, as judged by binding of specific mAbs. The bait region in the dimers can be cleaved by proteases, and activation of the thiol esters ensues without binding of the protease. When the dimers were treated with MeNH2, no conformational changes could be detected by ultraviolet-difference spectroscopy or CD. The conformational changes occurring on dissociation into dimers are suggested to be related to trap closure and receptor-recognition-site exposure without cleavage of the thiol esters. The model presented here suggests that two separate conformational changes occur in alpha2-macroglobulin upon activation. The first involves changes at the contact zones as a result of the thiol-ester cleavage, and the second causes exposure of the receptor-recognition sites and closure of the trap.

Alteration of dopamine release by rat caudate putamen tissues superfused with alpha 2-macroglobulin

Monoamine-activated alpha-2-macroglobulin (alpha 2M) has been shown to decrease the dopamine concentrations in rat caudate putamen (CP) in vivo as well as inhibit choline acetyltransferase activities in the culture of basal forebrain neurons. In this study, we further investigated the effects of methylamine-activated alpha 2M (MA-alpha 2M) upon striatal dopaminergic function by determining whether a direct infusion of this glycoprotein will alter dopamine (DA) release in vitro from superfused CP tissue fragments. In experiment 1, an infusion of 2.8 microM MA-alpha 2M produced a statistically significant increase in DA release compared with control superfusions. In experiment 2, varying doses (0, 0.7, 1.4, 2.8, 4.1 microM) of MA-alpha 2M were tested for their capacity to alter DA release. Only the 2.8 microM dose of MA-alpha 2M was effective in producing a significant increase of DA release. In experiment 3, the normal form of alpha 2M (N-alpha 2M) at 2.8 microM was compared with the control superfusions. The infusion of N-alpha 2M produced an increase in DA release which was substantially lower than the DA increase induced by MA-alpha 2M, and not significantly different from that of the control superfusion. These results show that MA-alpha 2M, like some other neurotoxins, can markedly alter CP dopaminergic function as indicated by the acute increase in DA release following infusion of this glycoprotein, and these effects are exerted at a relatively narrow range of doses. Taken together, these data suggest that this glycoprotein, if allowed to accumulate in the central nervous system (CNS), may promote some neurodegenerative changes that can occur in disorders like Parkinson's disease.

Alpha 2-macroglobulin bait region variants. A role for the bait region in tetramer formation

To test the hypothesis that a large portion of the bait region of human alpha 2-macroglobulin (alpha 2M) can be removed without adversely affecting the protein's structural and functional properties, we expressed two human alpha 2M variants with truncated bait regions and examined whether these variants folded normally and functioned as proteinase inhibitors. Each variant contains sites that are normal bait region cleavage sites in wild-type alpha 2M, including the primary trypsin cleavage site. The truncated bait regions are shorter by 23 and 27 residues, respectively, and lack the C-terminal portion as well as different parts of the N-terminal section of the bait region. We found that such bait region truncation permitted normal folding of the monomers as well as formation of the thiol ester and dimerization by disulfide cross-linking, although the resulting species bound 6-(p-toluidino)-2-naphthalenesulfonic acid in a manner more like thiol ester-cleaved alpha 2M than native alpha 2M. The variants' thiol esters reacted with nucleophiles at rates identical to wild-type alpha 2M. Surprisingly, however, the truncations prevented the noncovalent association of the covalent 360-kDa dimers that normally gives tetrameric alpha 2M, decoupled bait region cleavage from thiol ester activation, and resulted in the inability of the two variants to "trap" proteinase. This was despite apparent cleavage of the bait region by proteinase, albeit at very much reduced rates relative to wild-type tetrameric alpha 2M. The kinetics of thiol ester cleavage-dependent protein conformational changes also changed from sigmoidal to exponential. These findings indicate that residues in the bait region appear to be necessary for noncovalent association of 360-kDa disulfide-linked dimers to give tetrameric alpha 2M and suggest a role for the bait region in normal alpha 2M in coupling bait region cleavage to the sequence of conformational changes that result in thiol ester activation and ultimately proteinase trapping.

Comparison of conformational changes of pregnancy zone protein and human alpha 2-macroglobulin, a study using hydrophobic affinity partitioning

Conformational changes of human alpha 2-macroglobulin (alpha 2M) and pregnancy zone protein (PZP), reflected in changes in surface hydrophobicity, have been studied. The results show that the conformation of alpha 2M is governed by the degree of 'trapping'. Thus, cleavage in the bait region and of the thiol ester by proteinase treatment causes a two-fold increase in surface hydrophobicity of alpha 2M. However, the increase is still higher (three-fold) when the thiol esters in alpha 2M alone are cleaved by methylamine. Cyanylation of the thiol groups exposed upon methylamine treatment yields a derivative with the same hydrophobicity as native alpha 2M. Treatment of this derivative with chymotrypsin restores the hydrophobicity to that of methylamine-treated alpha 2M. Since the C-terminal 18 kDa fragment of alpha 2M exhibits no hydrophobicity, the change in hydrophobicity seems not to reside in the receptor binding site. In contrast to alpha 2M, modification of both native and methylamine-treated PZP with chymotrypsin gives a reduction (about 40%) in hydrophobicity. The change in hydrophobicity is insignificant on treatment with methylamine alone. Furthermore, hydrophobic interactions appear not to contribute to tetramerization of PZP. The present study indicates major differences in the conformational states of alpha 2M and PZP as reflected in the hydrophobic surfaces exhibited.

Proteinase inhibitory activity in the plasma of a mollusc: evidence for the presence of alpha-macroglobulin in Biomphalaria glabrata

1. A methylamine-sensitive inhibitor was present in the plasma of B. glabrata. 2. This inhibitor decreased trypsin activity against a protein substrate, however trypsin retained activity against a low molecular weight substrate in the presence of the inhibitor. 3. Snail plasma protected trypsin from inhibition by soybean trypsin inhibitor. 4. The results give evidence for an alpha-macroglobulin proteinase inhibitor in the plasma of this gastropod mollusc.

Ultrastructure of alpha 2-macroglobulins

New results concerning the ultrastructure of human alpha 2-macroglobulin (alpha 2M) molecules are presented in connection and comparison with the historical, the current and our own most recent, even unpublished results on the structure and function of alpha 2M and related proteins. The electron microscopic approach uses classical negative staining, combined with the new imaging mode "Electron Energy Loss Spectroscopy", which provides unusual contrast, resolution and readability of the electron micrographs. Immuno- and cryoelectron microscopy, as well as image processing has provided new data necessary to the building of tentative 3D models of the molecule. A model for the native tetrameric alpha 2M is described for the first time, and tries to explain and gather the various observations, sometimes contradictory, taken from different laboratories. A revised version for a model of the methylamine- and proteinase-transformed forms of alpha 2M is also shown. The probable positions of the bait regions and the thiol esters are given on both models. We confirm that alpha 2M is a twin trap capable of inactivating one or two proteinases by partial immobilization. Preliminary results on the production of crystals of alpha 2M-chymotrypsin complexes are also presented. A critical analysis of our models is presented in comparison with others. The technical limitations reached with some techniques and some possible extensions of future research in the field are also presented.

X-ray scattering study of hagfish protease inhibitor, a protein structurally related to complement and alpha 2-macroglobulin

A protease inhibitor from hagfish blood plasma, homologous to human alpha 2-macroglobulin, has been studied in solution using small-angle X-ray scattering; the radius of gyration, R, was found to be 7.0 nm, the molecular weight 340,000 +/- 20,000, and the largest distance within the molecule, Dmax, 22 nm. When the inhibitor reacts with chymotrypsin, its 1:1 chymotrypsin complex is found to be more compact than the native molecule, R = 6.1 nm. A very similar conformational change is observed after the protein is reacted with methylamine. The data are consistent with models consisting of two equal elliptic cylinders with the same size as the one used as a model for the complement proteins C3 and C4 [cf. Osterberg et al. (1989) Eur. J. Biochem. 183, 507-511]. In the model for the native protein, these cylinders are arranged in an extended form, and in the one for the methylamine derivative (or chymotrypsin complex), they are closer together so that the projection of their elliptic surfaces forms an angle of about 70 degrees. These models for the hagfish protease inhibitor were expanded to models for the twice as large human alpha 2-macroglobulin using symmetry operations, and the resulting alpha 2-macroglobulin models were found to agree with those emerged from earlier studies involving electron microscopy and X-ray scattering methods.

Reaction of proteinases with alpha 2-macroglobulin: rapid-kinetic evidence for a conformational rearrangement of the initial alpha 2-macroglobulin-trypsin complex

The kinetics of the reaction of trypsin with alpha 2M were examined under pseudo-first-order conditions with excess inhibitor. Initial studies indicated that the fluorescent dye TNS is a suitable probe for monitoring the reaction over a wide concentration range of reactants. Titration experiments showed that the conformational changes associated with the binding of trypsin to alpha 2M result in an increased affinity of the inhibitor for TNS. Two distinct phases were observed when this dye was used to monitor the progress of the reaction. Approximately half of the fluorescence signal was generated during a rapid phase, with the remainder generated during a second, slower phase. The observed pseudo-first-order rate constant of the first phase varied linearly with the concentration of alpha 2M up to the highest concentration of inhibitor used, whereas the rate constant of the second phase was independent of alpha 2M concentration. The data fit a mechanism in which the association of trypsin with alpha 2M occurs in two consecutive, essentially irreversible steps, both leading to alterations in TNS fluorescence. The initial association occurs with a second-order rate constant of (1.0 +/- 0.1) X 10(7) M-1 s-1 and is followed by a slower, intramolecular conformational rearrangement of the initial complex with a rate constant of 1.4 +/- 0.2 s-1. The data are consistent with a previously proposed model for the reaction of proteinases with alpha 2M [Larsson et al. (1989) Biochemistry 28, 7636-7643].2+ this model, once an initial 1:1 alpha 2M-proteinase

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.

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., & Björk, 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)

Electrophoretic and spectroscopic analyses of equine alpha 2-macroglobulin with cleavage of the thiol ester bonds by methylamine

Reaction of equine alpha 2-macroglobulin (alpha 2M) with methylamine caused generation of 3.7 mol of thiol groups per mole of the protein, and the second-order rate constant of the generation was calculated to be 3.5 M-1 s-1. The inhibitory profile of caseinolytic activity of trypsin indicated that one molecule of equine alpha 2M inhibited two molecules of trypsin, similar to human alpha 2M. The methylamine-treated equine alpha 2M, with complete cleavage of the thiol ester bonds, still inhibited the activity of trypsin, though human alpha 2M lost its inhibitory activity by treatment with methylamine. These results indicate that the mode of inhibition of trypsin by equine alpha 2M is substantially unperturbed by cleavage of the thiol ester bonds and that the intact thiol ester bonds per se are not essential for the ability of equine alpha 2M to bind the enzyme. Ultraviolet absorption difference, intrinsic fluorescence, and circular dichroism spectra of the methylamine-treated equine alpha 2M showed that this treatment caused only a small change in conformation of the protein. Reaction of the methylamine-treated protein with trypsin induced appreciable changes in the spectra, indicating a large change in conformation of the protein. These findings were consistent with the results obtained by electrophoresis: The band of methylamine-treated equine alpha 2M showed indistinguishable mobility from that of the unmodified protein, indicating that no appreciable change in conformation occurred, and distinctly different mobility from that of the unmodified or methylamine-treated equine alpha 2M when each had reacted with trypsin.

Properties of the complex between alpha 2-macroglobulin and brinase, a proteinase from Aspergillus oryzae with thrombolytic effect

The proteinase, brinase (Mr approximately 35000), from Aspergillus oryzae, which has been used in therapeutic attempts as a thrombolytic agent in arterial thrombosis, binds to purified human alpha 2-macroglobulin (alpha 2M) with a stoichiometry of 1.7-1.9 mol of enzyme/mol inhibitor. This binding leads to quantitative cleavage of the bait region of the inhibitor and to release of 3.6 thiol groups per molecule of alpha 2M, reflecting cleavage of the thioester bonds. The reaction with brinase is accompanied by a similar conformational change of alpha 2M as the reaction with trypsin, as shown by gradient gel electrophoresis and spectroscopic analyses. Brinase thus binds to alpha 2M in a similar manner as most small proteinases. However, in the complex formed at saturation of alpha 2M with brinase, the enzyme retains considerable proteolytic activity against macromolecular substrates, corresponding to about 25% of that of the free enzyme with fibrin as substrate. This finding indicates that the trapping of brinase by alpha 2M is less efficient than that of smaller proteinases. The complex formed at equimolar concentrations of the reactants has appreciably lower, although still significant, activity, amounting to 5-10% of that of free brinase against fibrin. This proteolytic activity of alpha 2M-brinase complexes against high-molecular-weight substrates most likely accounts for the thrombolytic effect of brinase in vivo. The observations also indicate that this thrombolytic activity increases more than proportionally to the brinase concentration as the latter is increased to approach saturation of alpha 2M in plasma.

Limulus alpha 2-macroglobulin. First evidence in an invertebrate for a protein containing an internal thiol ester bond

Intra-chain thiol ester bonds are present in a limited number of proteins. The thiol ester class of proteins includes vertebrate alpha 2-macroglobulin and the complement proteins C3 and C4. We report here the first instance of a thiol ester protein from an invertebrate, the alpha 2-macroglobulin proteinase-inhibitor homologue present in the plasma of the American horseshoe crab Limulus polyphemus. Our evidence is of three kinds: (1) the proteinase-binding activity of Limulus alpha 2-macroglobulin is inactivated by the low-molecular-mass primary amine methylamine; (2) the native protein is subject to autolytic fragmentation during mild thermal denaturation, yielding fragments of approx. 125 kDa and 55 kDa, whereas the methylamine-treated protein is stable under these conditions of thermal treatment; (3) new thiol groups are generated rapidly during reaction of the protein with trypsin. The demonstration of the thiol ester bond in a protein from an ancient invertebrate provides evolutionary evidence for the importance of this bond in the function of plasma forms of the alpha 2-macroglobulin-like proteinase inhibitors.

Amino acid sequence of a 32-residue region around the thiol ester site in duck ovostatin

To obtain the amino acid sequence at the thiol ester site in duck ovostatin for comparisons with other proteins, the native ovostatin was labeled with 14CH3NH2 at the reactive thiol ester site. The modified protein was reduced, carboxymethylated, and digested with trypsin. 14C-labeled peptides isolated by gel filtration with Sephadex G-50, ion-exchange chromatography on DEAE-cellulose and HPLC were subjected to automated sequence analysis, and the stretch of 32 amino acid residues containing the 14CH3NH2-binding site were determined. A comparison of this sequence with the corresponding sequences in alpha 2-macroglobulin, and complement components C3 and C4 revealed 72, 31 and 34% homology, respectively. The results indicate that ovostatin is a close relative to plasma alpha-macroglobulins and may share a common ancestor with C3 and C4.

Some consequences of the covalent and non-covalent binding modes of plasmin with alpha 2-macroglobulin

Analysis of plasmin-alpha 2-macroglobulin interactions by polyacrylamide gel electrophoresis showed that both the light and heavy chains of the proteinase have covalent links with the inhibitor. This covalent binding occurs with a 95 +/- 5% yield and can be abolished in the presence of hydroxylamine without modification of the plasmin-alpha 2-macroglobulin stoichiometry, the extent of the 180-kDa peptide chain cleavage and the generation of the -SH groups. However, these two different binding modes greatly influence the enzymatic properties of the proteinase as well as the occupancy by an other proteinase molecule of the free binding site of the (1:1) plasmin-alpha 2-macroglobulin complex. Non-covalently bound plasmin is more active on synthetic substrates and interacts more tightly with the basic pancreatic trypsin inhibitor than the covalently bound enzyme. Furthermore, the former complex incorporates significantly more chymotrypsin than the latter. The incorporation of chymotrypsin influences the catalytic properties of plasmin within the ternary complex.

Evidence of an alpha 2-macroglobulin-like molecule in plasma of Salamandra salamandra. Structural and functional similarity with human alpha 2-macroglobulin

A high-Mr (Mr 750,000) alpha 1-macroglobulin, obtained from Salamandra salamandra, is described. Salamander alpha 1-macroglobulin is composed of two monomers of equal Mr, which are composed of two polypeptide chains, each of Mr 180,000, linked by disulfide bonds. The molecular parameters of this protein, its binding to trypsin and inactivation by methylamine suggest that salamander alpha 1-macroglobulin is closely related to human alpha 2-macroglobulin and to other related proteins described in the animal kingdom.

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].

The structure around the thioester bond in bovine alpha 2-macroglobulin. Possible implications for the conformational stability of the inhibitor on thioester cleavage

The residues contributing to the thioester bonds in bovine alpha 2-macroglobulin were differentially labelled by modification of the Glu moiety with [14C]methylamine and of the Cys moiety with iodo[3H]acetate. The labelled region was identified and analyzed in a tryptic peptide. Two amino acid replacements between human and bovine alpha 2-macroglobulin were found at positions +3 (Val/Ala) and +4 (Leu/Arg) from the Glu moiety of the thioester. Thus, marked differences exist between the human and bovine proteins in side chain size and charge close to the thioester bonds. These differences may explain the greater conformational stability of bovine alpha 2-macroglobulin, compared with that of the human inhibitor, after cleavage of the thioester bonds.

Unusual properties of crocodilian ovomacroglobulin shown in its methylamine treatment and sulfhydryl titration

The inhibitory activity of chicken and crocodilian ovomacroglobulins against trypsin was measured before and after their incubation with methylamine. The result for crocodilian ovomacroglobulin showed that methylamine treatment destroyed half of its activity, in unique contrast to human alpha 2-macroglobulin and chicken ovomacroglobulin for which methylamine either destroys the inhibitory activity of the former completely or does not affect that of the latter at all. Free sulfhydryl groups of chicken and crocodilian ovomacroglobulins were titrated with 5,5'-dithiobis(2-nitrobenzoic acid) before and after incubation with trypsin. Prior to the incubation with trypsin the chicken and crocodilian proteins respectively had 0 and 1 titratable sulfhydryl per molecule of Mr 720,000. After treatment with trypsin the crocodilian protein had 3.5-4 titratable sulfhydryls, whereas there were no titratable sulfhydryls in the chicken protein. After denaturation of the crocodilian protein in sodium dodecyl sulfate at 100 degrees C the number of titratable sulfhydryls was 4. Chicken ovomacroglobulin again did not have an appreciable number of titratable sulfhydryls under similar denaturing conditions. Incubation of crocodilian protein with [14C]methylamine showed an incorporation of at least 2 mol of methylamine per molecule. The result indicated the presence of three intramolecular thiol ester bonds in crocodilian ovomacroglobulin with differential stability against external perturbations.

Binding of proteinases to human alpha 2-macroglobulin with its thioester bonds cleaved by methylamine in the presence of a thiol-group-cyanylating reagent

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.