Citramalate lyase of Clostridium tetanomorphum

Summary Assay methods and some properties of (+)-citramalate pyruvatelyase, an enzyme from Clostridium tetanomorphum that converts (+)-citramalate to pyruvate and acetate, are described. The enzyme is very active (0.8–1.2 units per mg protein) in freshly prepared extracts, but loses activity rapidly during storage. (+)-Citramalate is the only substrate found to be cleaved by the lyase; the equilibrium for the reaction permits almost complete cleavage at low substrate concentrations. A divalent cation is required as a cofactor. A sensitive and specific enzymic method for estimating (+)-citramalate is described.It is a pleasure to dedicate this paper to Prof. C. B. Van Niel who first awakened the interest of the author in the problems of bacterial metabolism and, more specifically, in the fermentation of glutamic acid.This work was supported in part by a research grant from the National Institutes of Health (AI-00563), U.S. Public Health Service, and by funds from the California Agricultural Experiment Station     

Purification and characterization of an extracellular lipase from Clostridium tetanomorphum

Summary The strictly anaerobic bacterium Clostridium tetanomorphum formed an extracellular lipase when the growth medium contained glycerol in addition to fermentable substrates such as l-glutamate or glucose. The lipase was purified from the concentrated culture supernatant and exhibited a final specific activity of 900 U/mg. The purified lipase had a Stokes’ radius of 5.0 nm and a sedimentation coefficient of 5.7S. The native molecular mass calculated from these values was 118,000 Da, which is considerably higher than the molecular mass calculated by PAGE (70,000 Da). With p-nitrophenyl esters of different fatty acids as substrates enzyme activity was highest when the acyl chain was short (C₂). The purified lipase showed no protease or thioesterase activity.     

The structure of 3-methylaspartase from Clostridium tetanomorphum functions via the common enolase chemical step.

Methylaspartate ammonia-lyase (3-methylaspartase, MAL; EC ) catalyzes the reversible anti elimination of ammonia from L-threo-(2S,3S)-3-methylaspartic acid to give mesaconic acid. This reaction lies on the main catabolic pathway for glutamate in Clostridium tetanomorphum. MAL requires monovalent and divalent cation cofactors for full catalytic activity. The enzyme has attracted interest because of its potential use as a biocatalyst. The structure of C. tetanomorphum MAL has been solved to 1.9-A resolution by the single-wavelength anomalous diffraction method. A divalent metal ion complex of the protein has also been determined. MAL is a homodimer with each monomer consisting of two domains. One is an alpha/beta-barrel, and the other smaller domain is mainly beta-strands. The smaller domain partially occludes the C terminus of the barrel and forms a large cleft. The structure identifies MAL as belonging to the enolase superfamily of enzymes. The metal ion site is located in a large cleft between the domains. Potential active site residues have been identified based on a combination of their proximity to a metal ion site, molecular modeling, and sequence homology. In common with all members of the enolase superfamily, the carboxylic acid of the substrate is co-ordinated by the metal ions, and a proton adjacent to a carboxylic acid group of the substrate is abstracted by a base. In MAL, it appears that Lys(331) removes the alpha-proton of methylaspartic acid. This motif is the defining mechanistic characteristic of the enolase superfamily of which all have a common fold. The degree of structural conservation is remarkable given only four residues are absolutely conserved.     

Coordinated action of pectinesterase and polygalacturonate lyase complex of Clostridium multifermentans.

The polygalacturonate lyase and pectinesterase activities of Clostridium multifermentans, both produced extracellularly when the organism grows on pectin or polygalacturonate, have been suggested to be associated in a single complex. Both enzymic sites act on their respective substrates by single-chain action patterns, as shown by equivalent release of terminal tritium label and total product throughout the reaction. From these results, the Km and V of the lyase, and the amount of lyase activity present, we calculate the steady-state concentration of lyase substrate expected during action of the two sites on pectin if the sites are independent. No such steady-state concentration of lyase substrate was observed. Therefore, we conclude that the two types of active site act in a coordinated manner; the polysaccharide chain passes from the esterase site to the lyase site without intermediate dissociation and rebinding. This 'molecular disassembly line' constituted by the two sites may represent a system of general significance in synthesis and degradation of biological polymers.     

Purification and characterization of N-acetylneuraminate lyase from Clostridium perfringens.

Clostridium perfringens cells were cultivated on a large scale using an automatic system. 2) N-Acetylneuraminate lyase, which is a cytosolic enzyme, was liberated from the bacteria by cell lysis using lysozyme in hypotonic solution. The enzyme was purified 770-fold by precepitation with ammonium sulfate, filtration on Sephadex A-50 and final preparative electrophoresis in a 7.5% polyacrylamide gel. Yield: 12 mg from 1 kg wet cell paste; specific activity: 167 nkat/mg protein. 3) The enzyme preparation appeared homogeneous in analytical disc electrophoresis, in gel electrophroesis in 0.1% sodium dodecylsulfate or 8m urea and in immunoelectrophoresis. Contaminating enzyme activities were not detected. 4) The isoelectric point of pH 4.7 was found for the enzyme. At 278 nm a molar extinction coefficient of 6.4 x 10(4)M-1 Xcm-1 was determined. The enzyme exhibited a Km value for N-acetylneuraminic acid of 2.8mM at its pH optimum of pH 7.2. The pH dependence of the Km value gives evidence that an ionizing guoup in the active center of the enzyme with a pKe value of 6.4 may be involved in the catalytic reaction. Pyruvate inhibited the cleavage reaction of N-acetylneuraminic acid competitively; Ki = 2.9mM. 5) An average molecular weight of 99200 was determined for the native enzyme using different methods. After denaturation in sokium dodecylsulfate or urea, a mean molecular weight of only 50000 could be demonstrated, indicating the existence of two enzyme subunits. The lyase molecule was shown by electron microscopy, using a negative staining technique, to consist of two hemispherical parts. 6) Two active sites per native enzyme molecule, probably corresponding to one active site per subunit, were found by incubation of the enzyme with radioactive pyruvate followed by borohydride reduction. The results obtained from chemical modification of the lyase with 5-diazonium-1H-tetrazole and iodocaetamide under various conditionsare interpreted as evidence for the presence of two reactive histidine residues in the enzyme molecule. It is probable that one residue per subunit forms the nucleophilic group participating in enzyme catalysis. A model suggesting the mechanism of reversible cleavage of N-acylneuraminic acids by the lyase is presented.     

Acetic anhydride: an intermediate analogue in the acyl-exchange reaction of citramalate lyase.

1. Reactivation of deacetyl citramalate lyase by acetic anhydride proceeds through an enzyme-anhydride complex prior to actual acetylation. The reaction is inhibited by citramalate which is competitive with acetic anhydride. 2. A corresponding complex is an intermediate in the carboxymethylation of deacetyl enzyme by iodoacetate. However, the inhibition of this reaction by S-citramalate appears to be non-competitive with iodoacetate. 3. The results lead to the conclusion that acetic anhydride can be regarded as a structural analogue of citramalic acetic anhydride, the proposed intermediate in the acyl exchange reaction on citramalate lyase. 4. The formation of 6-citryl thiolester from the 1-thiolester via the cyclic citric anhydride provides a chemicla model for enzymic acyl exchange. 5. The data suggest that anhydrides are of general importance in acyl exchange reactions of thiolesters.     

Characterization of citrate lyase from Clostridium sporosphaeroides

Cells of Clostridium sporosphaeroides which were grown on citrate contained citrate lyase and citrate lyase acetylating enzyme, but no detectable citrate synthase and citrate lyase deacetylase activities. Citrate lyase from C. sporosphaeroides was purified to homogeneity as judged by polyacrylamide gel electrophoresis and high performance liquid chromatography. In contrast to the enzyme from Clostridium sphenoides, the addition of l-glutamate was not necessary for activity and stabilization of the enzyme. The purified enzyme had a specific activity of 34 U/mg protein and was comparable to other citrate lyases with respect to its molecular weight and subunit composition. Electron microscopic investigations showed that similar to the lyase from C. sphenoides and in contrast to all other citrate lyases examined so far, the majority of the enzyme molecules was present in star form.     

Cloning and sequencing of glutamate mutase component S from Clostridium tetanomorphum. Homologies with other cobalamin-dependent enzymes.

The gene encoding component S, the small subunit, of glutamate mutase, an adenosylcobalamin (coenzyme B12)-dependent enzyme from Clostridium tetanomorphum has been cloned and its nucleotide sequence determined. The mutS gene encodes a protein of 137 amino acid residues, with M(r) 14,748. The deduced amino acid sequence showed homology with the C-terminal portion of adenosylcobalamin-dependent methylmalonyl-CoA mutase [1989, Biochem. J. 260, 345-352] and a region of cobalamin-dependent methionine synthase which has been shown to bind cobalamin [1989, J. Biol. Chem 264, 13888-13895].     

The cellulolytic enzyme complex of Clostridium thermocellum is very large

The cellulolytic enzyme system bound to cellulose during the early stages of growth of C. thermocellum on this substrate was resolved into two major complexes. These complexes, as viewed by electron microscopy, are spherical particles with diameters of 210 A and 610 A and calculated molecular weights of 4.2 million and 102 million daltons, respectively.     

Acryloyl-CoA reductase from Clostridium propionicum. An enzyme complex of propionyl-CoA dehydrogenase and electron-transferring flavoprotein.

Acryloyl-CoA reductase from Clostridium propionicum catalyses the irreversible NADH-dependent formation of propionyl-CoA from acryloyl-CoA. Purification yielded a heterohexadecameric yellow-greenish enzyme complex [(alpha2betagamma)4; molecular mass 600 +/- 50 kDa] composed of a propionyl-CoA dehydrogenase (alpha2, 2 x 40 kDa) and an electron-transferring flavoprotein (ETF; beta, 38 kDa; gamma, 29 kDa). A flavin content (90% FAD and 10% FMN) of 2.4 mol per alpha2betagamma subcomplex (149 kDa) was determined. A substrate alternative to acryloyl-CoA (Km = 2 +/- 1 microm; kcat = 4.5 s-1 at 100 microm NADH) is 3-buten-2-one (methyl vinyl ketone; Km = 1800 microm; kcat = 29 s-1 at 300 microm NADH). The enzyme complex exhibits acyl-CoA dehydrogenase activity with propionyl-CoA (Km = 50 microm; kcat = 2.0 s-1) or butyryl-CoA (Km = 100 microm; kcat = 3.5 s-1) as electron donor and 200 microm ferricenium hexafluorophosphate as acceptor. The enzyme also catalysed the oxidation of NADH by iodonitrosotetrazolium chloride (diaphorase activity) or by air, which led to the formation of H2O2 (NADH oxidase activity). The N-terminus of the dimeric propionyl-CoA dehydrogenase subunit is similar to those of butyryl-CoA dehydrogenases from several clostridia and related anaerobes (up to 55% sequence identity). The N-termini of the beta and gamma subunits share 40% and 35% sequence identities with those of the A and B subunits of the ETF from Megasphaera elsdenii, respectively, and up to 60% with those of putative ETFs from other anaerobes. Acryloyl-CoA reductase from C. propionicum has been characterized as a soluble enzyme, with kinetic properties perfectly adapted to the requirements of the organism. The enzyme appears not to be involved in anaerobic respiration with NADH or reduced ferredoxin as electron donors. There is no relationship to the trans-2-enoyl-CoA reductases from various organisms or the recently described acryloyl-CoA reductase activity of propionyl-CoA synthase from Chloroflexus aurantiacus.