Organophosphate inhibitors: the reactions of bis(p-nitrophenyl) methyl phosphate with liver carboxylesterases and alpha-chymotrypsin.

Bis(p-nitrophenyl) methyl phosphate (BNMP) has been tested as a spectrophotometric titrant for a group of serine hydrolases. Bis(p-nitrophenyl) methyl phosphate reacts rapidly with liver carboxylesterases from chicken, sheep, and horse, and more slowly with alpha-chymotrypsin, releasing 2 mol of p-nitrophenol per active site titrated, and producing a phosphorylated enzyme very stable to dephosphorylation. However, pig liver carboxylesterase produces 2.2 mol of p-nitrophenol per active site titratedmreaction of pig and chicken liver carboxylesterases with bis(p-nitrophenyl) [3H]methyl [32P]phosphate clarified this differencemone molecule of the chicken enzyme reacts with one molecule of bis(p-nitrophenyl) methyl phosphate, releasing both p-nitrophenol residues, and resulting in an inhibited enzyme with one phosphorus atom and one methyl group covalently bound. Pig enzyme reacts rapidly, forming (presumably) methyl p-nitrophenyl phosphoryl-carboxylesterasemthis further reacts, concurrently producing methyl phosphoryl-carboxylesterase plus p-nitrophenol, or free enzyme plus methyl p-nitrophenyl phosphate, in the ratio of about 5 : 1 at pH 7.55. The free enzyme produced undergoes further reaction with bis(p-nitrophenyl) methyl phosphate until all the carboxylesterase is inhibited.

Effect of estrogen on fatty acid synthetase in the chicken oviduct and liver.

Estrogen administered to one-month-old female chickens resulted in a 180-fold increase in the amount of fatty acid synthetase, a seven-fold increase in the enzyme activity per gram of tissue and a 25-fold increase in the weight of the oviduct. In contrast, the fatty acid synthetase content in liver increased three-fold; activity per gram of tissue increased two-fold and the weight increased two-fold. The large increase in the fatty acid synthetase activity in the oviduct was due to a corresponding increase in the amount of the fatty acid synthetase protein since the specific activities of highly purified preparations of oviduct and liver fatty acid synthetases were the same and the two enzymes had the same end point as determined by immunoprecipitation. That the increase in activity of the oviduct enzyme is not due to a modification was further supported by physicochemical comparison of the oviduct enzyme with the chicken liver enzyme. Thus, the synthetase complexes have similar size, their subunit composition and size appear to be the same, and both are multifunctional enzymes. Finally, kinetic studies and product analyses indicated no catalytic difference between the enzyme induced by estrogen in the oviduct and the liver enzyme.

Yeast fatty acid synthetase: structure-function relationship and nature of the beta-ketoacyl synthetase site.

Yeast fatty acid synthetase consists of two multifunctional proteins, alpha and beta, which are arranged in a complex of alpha(6)beta(6). Electron microscopic studies of this complex led to a model for the synthetase as an ovate structure consisting of an equatorial plate-like structure to which six arches are equally distributed on either side. The bifunctional reagent 1,3-dibromo-2-propanone inhibits the synthetase by reacting rapidly (t((1/2)) approximately 7 sec) with two juxtapositioned active sulfhydryl groups. Sodium dodecyl sulfate/polyacrylamide gel electrophoresis of the dibromopropanone-inhibited synthetase shows that the beta subunit is intact and the alpha subunit nearly absent with a concomitant appearance of oligomers with an estimated molecular weight of 0.4-1.2 x 10(6). These results indicate that the alpha subunits are crosslinked by this bifunctional reagent. Because the active centers of dibromopropanone are 5 A apart, it is concluded that the alpha subunits are closely packed so that the reacting thiols of the adjacent alpha subunits are within 5 A of each other. Furthermore, because the plate-like structures in our model are the only components that are arranged closely enough to satisfy this requirement, it is proposed that the alpha subunits are the "plates" and the beta subunits therefore are the "arches." Assay of the partial reactions shows that dibromopropanone inhibits the beta-ketoacyl synthetase reaction but none of the six other partial reactions, indicating that the site of action of the bifunctional reagent is the condensing reaction. This conclusion was supported by the finding that pretreatment of the synthetase with acetyl-CoA or iodoacetamide prevented dibromopropanone from interacting at this site and obviated the formation of the crosslinked oligomer. These observations and other lead us to propose that a site of action of the dibromopropanone is the active cysteine-SH of the beta-ketoacyl synthetase of one alpha subunit and the pantetheine-SH of the acyl carrier protein moiety of an adjacent alpha subunit. Thus, the enzymically active center of the beta-ketoacyl synthetase consists of an acyl group attached to the cysteine-SH of one alpha subunit (plate) and a malonyl group attached to the pantetheine-SH of an adjacent alpha subunit. This arrangement appears to be necessary for the coupling of the acyl and beta-carbon of the malonyl group to occur to yield CO(2) and the beta-ketoacyl product.

On the question of half- or full-site reactivity of animal fatty acid synthetase.

Our model of the animal fatty acid synthetase describes a head-to-tail arrangement of two identical subunits and predicts the presence of two centers for fatty acid synthesis. Current experiments which support this conclusion were conducted using the following approach. The thioesterase component of chicken liver fatty acid synthetase was either inhibited using phenylmethanesulfonyl fluoride or diisopropyl fluorophosphate, or released from the synthetase by limited proteolysis with alpha-chymotrypsin, thus ensuring that the fatty acyl products remain bound to the enzyme. Employing such preparations, the amount of NADPH oxidized in the initial burst of fatty acid synthesis was determined by stopped flow techniques. Gas-liquid chromatography showed that C20:0 and C22:0 constituted 85% of the fatty acids formed de novo, a result that was confirmed using [14C]acetyl-CoA in the reaction. These data showed that 1.0 mol of fatty acyl-enzyme product was formed per mol of phosphopantetheine; in addition, the measured stoichiometry of NADPH oxidation was sufficient to account for de novo fatty acid synthesis. Altogether, these results indicate that the two sites for fatty acid synthesis are active and function simultaneously. They also indicate that the thioesterase plays a key role in determining the chain specificity of fatty acid synthesis.

Complete amino acid sequence of chicken liver acyl carrier protein derived from the fatty acid synthase.

The acyl carrier protein domain of the chicken liver fatty acid synthase has been isolated after tryptic treatment of the synthase. The isolated domain functions as an acceptor of acetyl and malonyl moieties in the synthase-catalyzed transfer of these groups from their coenzyme A esters and therefore indicates that the acyl carrier protein domain exists in the complex as a discrete entity. The amino acid sequence of the acyl carrier protein was derived from analyses of peptide fragments produced by cyanogen bromide cleavage and trypsin and Staphylococcus aureus V8 protease digestions of the molecule. The isolated acyl carrier protein domain consists of 89 amino acid residues and has a calculated molecular weight of 10,127. The protein contains the phosphopantetheine group attached to the serine residue at position 38. The isolated acyl carrier protein peptide shows some sequence homology with the acyl carrier protein of Escherichia coli, particularly in the vicinity of the site of phosphopantetheine attachment, and shows extensive sequence homology with the acyl carrier protein from the uropygial gland of goose.

Carboxylesterases (EC 3.1.1). A comparison of some kinetic properties of horse, sheep, chicken, pig, and ox liver carboxylesterases.

A comparative study of the kinetic be,avior of horse, sheep, chicken, pig, and ox liver carboxylesterases is reported. The enzymes exhibit similar specificites towards a series of phenyl esters in which the acyl group is varied, and towards a series of butyrate esters in which the alcohol group is varied. Non-Michaelis-Menten kinetics are exhibited by the horse enzyme in the hydrolysis of methyl and ethyl butyrates, and by the pig enzyme with ethyl butyrate. Each enzyme exhibits inhibition by one or more substrates. A simple scheme which accounts for both activation and inhibition is discussed. pH-k(cat) profiles for the horse and chicken liver carboxylesterase-catalyzed hydrolyses of phenyl butyrate demonstrate dependencies on pK(a)S of 4.75 and 5.0, respectively.

The development and application of a novel chromophoric substrate for investigation of the mechanism of yeast fatty acid synthase.

The acetyl transacylase activity of the fatty acid synthase from yeast has been investigated using p-nitrophenylthiol acetate. The chromophoric nature of the nitrophenylthiol moiety affords a convenient spectrophotometric assay for the transacylase function as well as a means to investigate the kinetics and the mechanism of this process. A probable kinetic scheme for enzyme catalyzed transacetylation from p-nitrophenylthiol acetate to an acyl acceptor (CoA or N-acetylcysteamine) is proposed and the kinetic constants for acetylation of enzyme and for acetyl transfer to an acceptor were determined. It was also demonstrated that p-nitrophenylthiol acetate can replace acetyl-CoA as a substrate in fatty acid synthesis.

Yeast fatty acid synthase: structure to function relationship.

The yeast fatty acid synthase is a multifunctional enzyme composed of two nonidentical subunits in an alpha 6 beta 6 complex that is active in synthesizing fatty acids. The seven catalytic activities required for fatty acid synthesis are divided between the alpha and beta subunits such that the alpha 6 beta 6 complex has six complements of each activity. It has been proposed that these are organized into six centers for fatty acid synthesis. There are different opinions regarding the operation of these centers in the alpha 6 beta 6 complex, on view being that they are functionally independent and the other proposes half-sites activity for the complex. We have attempted to distinguish between these proposals by the most direct method of active site titration, i.e., quantitation of fatty acyl product in the absence of turnover. This was accomplished by using p-nitrophenyl thioacetate and thiophenyl malonate (in place of the coenzyme A analogues) as substrates along with NADPH, thereby depriving the yeast synthase of coenzyme A required to release product as fatty acyl coenzyme A. The amount of fatty acyl product formed was quantitated by gas-liquid chromatography, as well as by direct estimation of radioactivity in the product when p-nitrophenyl thio [1-14C] acetate was used as a substrate. In both cases, a stoichiometry of close to six was found for mole of fatty acid synthesized per mole of alpha 6 beta 6 complex. This indicates that there are six functional centers for fatty acid synthesis in the multifunctional yeast alpha 6 beta 6 fatty acid synthase and that these centers operate independently.(ABSTRACT TRUNCATED AT 250 WORDS)

The yeast fatty acid synthase. Pathway for transfer of the acetyl group from coenzyme A to the Cys-SH of the condensation site.

The reaction pathway of enzyme-catalyzed acetylation of the acyl-accepting sites of the yeast synthase, a Ser-OH at the acetyl transacylase site, a Cys-SH at the beta-ketoacyl synthase site, and the acyl carrier protein 4'-phosphopantetheine-SH (Pant-SH), has been investigated using the chromophoric substrate, p-nitrophenyl thioacetate. The stoichiometry of acetylation of the native enzyme was 3 mol of acetate bound per mol of synthase unit, alpha beta (Mr 430,000). The acetylation process is biexponential; the rate constant of acetylation of the first 2 mol is 5.0 s-1 and the third mol is 0.2 s-1. The pathway by which acetyl moiety is added to the enzyme was determined by selectively blocking the acyl-accepting sites and subsequently determining the kinetics and stoichiometry of acetylation. The dibromopropanone-treated enzyme, in which the Pant-SH and Cys-SH are alkylated, exhibited an exponential burst of approximately 1 mol/mol of synthase unit with a rate constant of 11.0 s-1. The iodoacetamide-treated enzyme, in which Cys-SH is alkylated, had a biexponential burst with a total stoichiometry of approximately 2 mol/mol of synthase unit, with rate constants of 9 and 0.2 s-1, respectively. The kinetically competent acetylation to the extent of 2 and approximately 1 mol/mol of synthase unit for both Cys-SH and Cys-SH and Pant-SH-blocked enzymes, respectively, indicated that the route of acetyl transfer in the yeast synthase is obligatorily Ser-OH----Cys-SH. The acetylation of Pant-SH (0.2 s-1) occurs with a rate insignificant to the process of fatty acid synthesis (turnover rate constant of 1.5 s-1). These conclusions are supported by experiments involving end point radiolabeling of the synthase with [1-14C]acetyl moieties using the substrate, p-nitrophenyl thio[1-14C]acetate. Native, dibromopropanone-treated, and iodoacetamide-treated enzymes bind about 3, 1, and 2 mol of acetyl/mol of synthase unit, respectively. Performic acid oxidation studies of the acetyl-labeled enzyme indicate that there is one Ser-O-acetyl formed in the native and alkylated enzymes and one Cys-S-acetyl and one Pant-S-acetyl formed in the native enzyme. Altogether, these results support our contention that the acetylation of the Pant-SH is kinetically incompetent. Thus, the yeast synthase transacetylation reactions occur by a novel process of acetyl transfer from CoA to Ser-OH----Cys-SH, which is in contrast to the transfer from CoA to Ser-OH----Pant-SH----Cys-SH catalyzed by the prokaryotic synthases.(ABSTRACT TRUNCATED AT 400 WORDS)

Overexpression and mutagenesis of the catalytic domain of dihydrolipoamide acetyltransferase from Saccharomyces cerevisiae.

The inner core domain (residues approximately 221-454) of the dihydrolipoamide acetyltransferase component (E2P) of the pyruvate dehydrogenase complex from Saccharomyces cerevisiae has been overexpressed in Escherichia coli strain JM105 via the expression vector pKK233-2. The truncated E2p was purified to apparent homogeneity. It exhibited catalytic activity (acetyl transfer from [1-14C]acetyl-CoA to dihydrolipoamide) very similar to that of wild-type E2p. The appearance of the truncated and wild-type E2p was also very similar, as observed by negative-stain electron microscopy, namely, a pentagonal dodecahedron. These findings demonstrate that the active site of E2p from S. cerevisiae resides in the inner core domain, i.e., catalytic domain, and that this domain alone can undergo self-assembly. The purified truncated E2p showed a tendency to aggregate. Aggregation was prevented by genetically engineered attachment of the interdomain linker segment (residues approximately 181-220) to the catalytic domain. All dihydrolipoamide acyltransferases contain the sequence His-Xaa-Xaa-Xaa-Asp-Gly near their carboxyl termini. By analogy with chloramphenicol acetyltransferase, the highly conserved His and Asp residues were postulated to be involved in the catalytic mechanism [Guest, J. R. (1987) FEMS Microbiol. Lett. 44, 417-422]. Substitution of the sole His residue in the S. cerevisiae truncated E2p, His-427, by Asn or Ala by site-directed mutagenesis did not have a significant effect on the kcat or Km values of the truncated E2p. However, the Asp-431----Asn, Ala, or Glu substitutions resulted in a 16-, 24-, and 3.7-fold reduction, respectively, in kcat, with little change in Km values.(ABSTRACT TRUNCATED AT 250 WORDS)

Electron microscope studies of human alpha 2-macroglobulin-chymotrypsin complex: demonstration that the two structures assigned to native and proteolyzed alpha 2-macroglobulin represent two views of the proteolyzed molecule.

Electron microscope studies of native and protease-bound human alpha 2-macroglobulin have led to two contradictory models for these two structures. One viewpoint maintains that the native structure has the shape of )+(, which contracts on binding of the protease to the shape of ([). An opposing view proposes that the native structure has the shape of a padlock and that )+( and ([) are the side and end views of the proteolyzed molecule. In this investigation, electron microscope studies of the alpha-chymotrypsin-treated alpha 2-macroglobulin utilizing a tilt stage have shown that the two shapes [)+( and ([)] interconvert. This demonstrates that these two shapes represent the side and end views of the proteolyzed alpha 2-macroglobulin which are related by a 90 degree rotation of the prototype molecule.

The arrangement and role of some of the amino acid residues in the beta-ketoacyl synthetase site of chicken liver fatty acid synthetase.

The beta-ketoacyl synthetase site of eukaryotic fatty acid synthetases is comprised in part of a pantetheinyl residue on one subunit juxtapositioned with a cysteinyl residue on the adjacent subunit. The present study has confirmed this arrangement and has identified 2 additional residues in the site. The active site residues were identified as summarized below. Sodium borohydride reduction of the keto derivatives of the dibromopropanone cross-linked residues yielded the alcohol derivatives which were amenable to isolation in good yields. The active enzyme yielded primarily a cysteinecysteamine derivative of 2-propanol, demonstrating that a cystyl and the pantetheinyl residues were cross-linked by dibromopropanone. However, in the cold-inactivated enzyme, the primary product of the cross-linking reaction was the dicystyl derivative. In addition, cross-linking between the cystyl and pantetheinyl residues, but not the two cystyl residues, resulted in the cross-linking of the two subunits. Therefore, it is proposed that there are two cystyl residues on one subunit juxtapositioned with the pantetheinyl residue on the adjacent subunit. The cystyl residues are highly reactive toward alkylating agents at pH 6.5, suggesting the presence of a cationic residue interacting with the thiolate anion. This proposal was supported using the bifunctional reagent o-phthalaldehyde which was found to cross-link the epsilon-amino group of lysine with the pantetheinyl-SH or the cystyl-SH in the beta-ketoacyl synthetase site to form a thioisoindole ring. The dialdehyde inhibited the enzyme by inactivating the beta-ketoacyl synthetase activity, and the inhibition could be prevented by malonyl-CoA and to a lesser extent by acetyl-CoA. Blocking the reactive thiol groups with dibromopropanone or 5,5'-dithiobis(2-nitrobenzoic acid) reduced the formation of the fluorescent thioisoindole ring. The close arrangement of a cystyl-SH, the pantetheinyl-SH, and the epsilon-amino group of lysine led us to propose that the positive epsilon-amino group may serve as an electron sink in a general acid-catalyzed decarboxylation reaction.

Inactivation of yeast fatty acid synthetase by modifying the beta-ketoacyl reductase active lysine residue with pyridoxal 5'-phosphate.

Treatment of yeast fatty acid synthetase with pyridoxal 5'-phosphate inhibited the enzyme. Assays of the partial activities of the pyridoxal phosphate-treated synthetase showed that only the beta-ketoacyl reductase was significantly inhibited. NADPH prevented inactivation of the enzyme by pyridoxal phosphate, indicating that pyridoxal modifies a residue near or in the beta-ketoacyl reductase site. The pyridoxal-treated synthetase shows a fluorescence spectrum with a maximum of 426 nm after uv irradiation at 325 nm. Binding of the pyridoxal phosphate to the synthetase is reversible as shown by the disappearance of the fluorescence band after dialysis of pyridoxal-treated enzyme. Reduction with NaBH4 of the pyridoxal-treated enzyme eliminates this fluorescence maximum and causes the appearance of a new band at 393 nm. These observations suggest that pyridoxal phosphate interacts with the synthetase by forming a Schiff base with lysine residue at the beta-ketoacyl reductase site. Amino acid analyses of the HCl hydrolysates of the borohydride-reduced, pyridoxal-treated synthetase showed the presence of 6 mol of N6-pyridoxal derivative of lysine per mole of fatty acid synthetase, indicating the presence of six sites of beta-ketoacyl reductase in the native enzyme. Autoradiography of sodium dodecyl sulfate-polyacrylamide gels of the pyridoxal phosphate enzyme reduced with NaB3H4 indicates that the alpha subunit contains the beta-ketoacyl reductase domain. These findings are consistent with the proposed structure of the alpha 6 beta 6 complex required for palmitoyl-CoA synthesis.

On the structural changes of native human alpha2-macroglobulin upon proteinase entrapment. Three-dimensional structure of the half-transformed molecule.

The reconstructions of an intermediate form of human alpha2-macroglobulin (half-transformed alpha2M) in which two of its four bait regions and thiol ester sites were cleaved by chymotrypsin bound to Sepharose were obtained by three-dimensional electron microscopy from stain and frozen-hydrated specimens. The structures show excellent agreement and reveal a structure with approximate dimensions of 195 (length) x 135 (width) and 130 A (depth) with an internal funnel-shaped cavity. The structure shows that a chisel-shaped body is connected to a broad base at the opposing end by four stands. Four approximately 45 A diameter large openings in the body of the structure result in a central cavity that is more accessible to the proteinase than those associated with the native or fully transformed structures. The dissimilarity in the shapes between the two ends of alpha2M half-transformed and the similarity between its chisel-shaped body and that of native alpha2M indicate that the chymotrypsin has cleaved both bait regions in the bottom-half of the structure. Consequently, its functional division lies on the minor axis. The structural organization is in accord with biochemical studies, which show that the half-transformed alpha2M migrates on native polyacrylamide gels at a rate intermediate to the native and fully transformed alpha2M and is capable of trapping 1 mol of proteinase. Even though its upper portion is similar to the native molecule, significant differences in their shapes are apparent and these differences may be related to its slower reaction with a proteinase than the native structure. These structural comparisons further support the view that the transformation of alpha2M involves an untwisting of its strands with an opening of the cavity for entrance of the proteinase and a retwisting of the strands around the proteinase resulting in its encapsulation.

Structure of native alpha 2-macroglobulin and its transformation to the protease bound form.

Well-preserved structures of native and alpha-chymotrypsin-bound alpha 2-macroglobulin were obtained by electron microscopy. Computer processing of these images has shown that the native structure has the shape of a padlock 19 nm long. It is proposed that the native alpha 2-macroglobulin consists of the juxtaposition of two protomers with one protomer shaped like a distorted letter "S" and with the other its reverse image, to form a binding site between the two protomers near the bottom of the complex. On cleavage of the subunits with chymotrypsin, the native structure condenses to 16.7 nm and rearranges so that the interaction between the protomers is near the middle. Two images of the alpha 2-macroglobulin-chymotrypsin conjugate were obtained. We suggest that these images represent the end and side view of this complex. Based on the manner in which the native structure is assembled, we propose that the proteolyzed form of alpha 2-macroglobulin is functionally asymmetric in that both protease binding sites reside on the same half of the complex.

Utility of Butvar support film and methylamine tungstate stain in three-dimensional electron microscopy: agreement between stain and frozen-hydrated reconstructions.

A random conical tilt reconstruction of negatively stained Saccharomyces cerevisiae fatty acid synthase was used as a model to compute a three-dimensional reconstruction from untilted stain specimens of the molecules in multiple orientations using a three-dimensional projection alignment method. The resulting structure (24 A resolution) has a more uniform resolution than the initial structure and the handedness revealed in the random conical tilt method is preserved. In a similar approach, this model was used to compute a 21-A-resolution frozen-hydrated structure from untilted specimens of the molecules in multiple orientations. Even though the reconstructions are in close agreement, the stain structure appears to enhance the protein density associated with less robust features. These procedures significantly reduce the time and effort required to obtain a three-dimensional reconstruction from frozen-hydrated data with a resolution that is comparable to the best obtained by more laborious methods. The agreement between the stain and frozen-hydrated reconstructions affords convincing evidence concerning the validity of the structure and the information afforded by the two reconstructions significantly enhances the structural analysis of the molecule.

Light scattering and transmission electron microscopy studies reveal a mechanism for calcium/calmodulin-dependent protein kinase II self-association.

Calmodulin (CaM)-kinase II holoenzymes composed of either alpha or beta subunits were analyzed using light scattering to determine a mechanism for self-association. Under identical reaction conditions, only alphaCaM-kinase II holoenzymes self-associated. Self-association was detected at a remarkably low enzyme concentration (0.14 microM or 7 microg/mL). Light scattering revealed two phases of self-association: a rapid rise that peaked, followed by a slower decrease that stabilized after 2-3 min. Electron microscopy identified that the rapid rise in scattering was due to the formation of loosely packed clusters of holoenzymes that undergo further association into large complexes of several microns in diameter over time. Self-association required activation by Ca(2+)/CaM and was strongly dependent on pH. Self-association was not detected at pH 7.5, however, the extent of this process increased as reaction pH decreased below 7.0. A peptide substrate (autocamtide-2) and inhibitor (AIP) designed from the autoregulatory domain of CaM-kinase II potently prevented self-association, whereas the peptide substrate syntide-2 did not. Thus, CaM-kinase II self-association is isoform specific, regulated by the conditions of activation, and is inhibited by peptides that bind to the catalytic domain likely via their autoregulatory-like sequence. A model for CaM-kinase II self-association is presented whereby catalytic domains in one holoenzyme interact with the regulatory domains in neighboring holoenzymes. These intersubunit-interholoenzyme autoinhibitory interactions could contribute to both the translocation and inactivation of CaM-kinase II previously reported in models of ischemia.

On the 4'-phosphopantetheine content of chicken and rat liver fatty acid synthetases.

The finding that animal synthetases are complexes consisting of two polypeptide chains (Stoops, J.K., Arslanian, M.J., Oh, Y.H., Vanaman, T.C., and Wakil, S.J. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 1940-1944) led us to investigate their 4'-phosphopantetheine content. We have found that the chicken and rat synthetases contain 1.6 to 2.2 mol of 4'-phosphopantetheine per mol of the complex. The implications of this finding concerning the structure of the complex and the biosynthetic pathway of fatty acid synthesis are discussed.

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.