Glutamate Mutase Research Articles

Rearrangement of L-2-hydroxyglutarate to L-threo-3-methylmalate catalyzed by adenosylcobalamin-dependent glutamate mutase.

Adenosylcobalamin-dependent enzymes catalyze a variety of chemically difficult isomerizations in which a nonacidic hydrogen on one carbon is interchanged with an electron-withdrawing group on an adjacent carbon. We describe a new isomerization, that of L-2-hydroxyglutarate to L-threo-3-methylmalate, involving the migration of the carbinol carbon. This reaction is catalyzed by glutamate mutase, but k(cat) = 0.05 s(-)(1) is much lower than that for the natural substrate, L-glutamate (k(cat) = 5.6 s(-)(1)). EPR spectroscopy confirms that the major organic radical that accumulates on the enzyme is the C-4 radical of L-2-hydroxyglutarate. Pre-steady-state kinetic measurements revealed that L-2-hydroxyglutarate-induced homolysis of AdoCbl occurs very rapidly, with a rate constant approaching those measured previously with glutamate and methylaspartate as substrates. These observations are consistent with the rearrangement of the 2-hydroxyglutaryl radical being the rate-determining step in the reaction. The slow rearrangement of the 2-hydroxyglutaryl radical can be attributed to the poor stabilization by the hydroxyl group of the migrating glycolyl moiety of the radical transiently formed on the migrating carbon. In contrast, with the normal substrate the migrating carbon atom bears a nitrogen substituent that better stabilizes the analogous glycyl moiety. These studies point to the importance of the functional groups attached to the migrating carbon in facilitating the carbon skeleton rearrangement.

Elucidation of the coenzyme binding mode of further B 12-dependent enzymes using a base-off analogue of coenzyme B 12

(Coβ-5′-Deoxyadenosin-5′-yl)-( p-cresyl)cobamide (Ado-PCC), a base-off analogue of coenzyme B 12 (Ado-Cbl), was used to elucidate the coenzyme B 12 binding mode of glutamate mutase, 2-methyleneglutarate mutase and ethanolamine ammonia–lyase (EAL). Ado-PCC functions as excellent coenzyme for the carbon skeleton rearrangements with apparent K m values of 200 and 10 nM for glutamate and 2-methyleneglutarate mutases, respectively. The corresponding values for Ado-Cbl are 60 and 54 nM, respectively. In contrast, Ado-PCC showed no coenzyme activity with EAL but was a competitive inhibitor with respect to Ado-Cbl. The K i value for Ado-PCC was 26 nM, the apparent K m value for Ado-Cbl was 30 nM. These results are in agreement with the notion that in glutamate and 2-methyleneglutarate mutases, a conserved histidine residue of the protein is coordinated to the cobalt atom of coenzyme B 12, whereas in EAL the dimethylbenzimidazole residue of the coenzyme itself serves as ligand.

XAS spectroscopy reveals X-ray-induced photoreduction of free and protein-bound B12cofactors

Crystal structures of several proteins with a B(12) cofactor show abnormally long axial bonds between the cofactor's Co atom and its ;lower' ligand, which is typically a protein-derived imidazole from a histidine residue. X-ray absorption spectroscopy (XAS) experiments were carried out with the following cofactor derivatives to examine the question of whether the bond elongation might be due to an X-ray-induced reduction of the cofactor's cobalt centre: aquocobalamin, cyanocobalamin, methylcobalamin, 5'-desoxyadenosylcobalamin and cob(II)alamin. Each cofactor was investigated at 100 K in a water/glycerol or water/trehalose glass, both as unbound free species and bound to the protein components of the enzyme glutamate mutase. XAS data were collected for each sample around the cobalt absorption edge before and after exhaustive (10 min) irradiation with X-rays of energy 7.76 keV. While XAS spectra for cob(II)alamin, methylcobalamin and 5'-desoxyadenosylcobalamin were the same (within experimental error) before and after irradiation, both in the free and protein-bound state, the spectra of samples with aquocobalamin and cyanocobalamin changed substantially upon irradiation. The spectra of the irradiated samples resembled each other and were similar - but not identical - to the spectrum of the reduced cob(II)alamin. The implications of these observations for the interpretation of the ;long' axial Co-N bonds observed crystallographically in B(12) proteins are discussed.

EXAFS Data Indicate a “Normal” Axial Cobalt−Nitrogen Bond of the Organo-B12 Cofactor in the Two Coenzyme B12-Dependent Enzymes Glutamate Mutase and 2-Methyleneglutarate Mutase

A key step in the catalytic cycle of coenzyme B12-dependent enzymes is the homolysis of the cofactor's organometallic bond, leading to the formation of a 5‘-deoxyadenosyl radical. For the adenosylcobalamin-dependent enzyme methylmalonyl CoA mutase (MCM), it has been suggested that this step is mediated by a protein-induced lengthening of the cofactor's axial cobalt−nitrogen bond, in trans position to the scissile organometallic bond. In fact, such a lengthening was first observed in the crystal structure of MCM (Mancia et al. Structure 1996, 4, 339−350) and was later confirmed by an analysis of EXAFS data on the same protein in frozen solution (Scheuring et al. J. Am. Chem. Soc. 1997, 119, 12192−12200). Here, we report the results of an EXAFS study on the related coenzyme B12-dependent enzymes glutamate mutase from Clostridium cochlearium and 2-methyleneglutarate mutase from Clostridium barkeri. Both apoenzymes were overproduced from E. coli and reconstituted with methylcobalamin (MeCbl) to yield inactive...

Cloning and Sequencing of the Coenzyme B12-binding Domain of Isobutyryl-CoA Mutase from Streptomyces cinnamonensis, Reconstitution of Mutase Activity, and Characterization of the Recombinant Enzyme Produced inEscherichia coli

Isobutyryl-CoA mutase (ICM) catalyzes the reversible, coenzyme B(12)-dependent rearrangement of isobutyryl-CoA to n-butyryl-CoA, which is similar to, but distinct from, that catalyzed by methylmalonyl-CoA mutase. ICM has been detected so far in a variety of aerobic and anaerobic bacteria, where it appears to play a key role in valine and fatty acid catabolism. ICM from Streptomyces cinnamonensis is composed of a large subunit (IcmA) of 62.5 kDa and a small subunit (IcmB) of 14.3 kDa. icmB encodes a protein of 136 residues with high sequence similarity to the cobalamin-binding domains of methylmalonyl-CoA mutase, glutamate mutase, methyleneglutarate mutase, and cobalamin-dependent methionine synthase, including a conserved DXHXXG cobalamin-binding motif. Using IcmA and IcmB produced separately in Escherichia coli, we show that IcmB is necessary and sufficient with IcmA and coenzyme B(12) to afford the active ICM holoenzyme. The large subunit (IcmA) forms a tightly associated homodimer, whereas IcmB alone exists as a monomer. In the absence of coenzyme B(12), the association between IcmA and IcmB is weak. The ICM holoenzyme appears to comprise an alpha(2)beta(2)-heterotetramer with up to two molecules of bound coenzyme B(12). The equilibrium constant for the ICM reaction at 30 degrees C is 1.7 in favor of isobutyryl-CoA, and the pH optimum is near 7.4. The K(m) values for isobutyryl-CoA, n-butyryl-CoA, and coenzyme B(12) determined with an equimolar ratio of IcmA and IcmB are 57 +/- 13, 54 +/- 12, and 12 +/- 2 microM, respectively. A V(max) of 38 +/- 3 units/mg IcmA and a k(cat) of 39 +/- 3 s(-1) were determined under saturating molar ratios of IcmB to IcmA.

Pre-steady-state kinetic investigation of intermediates in the reaction catalyzed by adenosylcobalamin-dependent glutamate mutase.

Glutamate mutase catalyzes the reversible isomerization of L-glutamate to L-threo-3-methylaspartate. Rapid quench experiments have been performed to measure apparent rate constants for several chemical steps in the reaction. The formation of substrate radicals when the enzyme was reacted with either glutamate or methylaspartate was examined by measuring the rate at which 5'-deoxyadenosine was formed, and shown to be sufficiently fast for this step to be kinetically competent. Furthermore, the apparent rate constant for 5'-deoxyadenosine formation was very similar to that measured previously for cleavage of the cobalt-carbon bond of adenosylcobalamin by the enzyme, providing further support for a mechanism in which homolysis of the coenzyme is coupled to hydrogen abstraction from the substrate. The pre-steady-state rates of methylaspartate and glutamate formation were also investigated. No burst phase was observed with either substrate, indicating that product release does not limit the rate of catalysis in either direction. For the conversion of glutamate to methylaspartate, a single chemical step appeared to dominate the overall rate, whereas in the reverse direction a lag phase was observed, suggesting the accumulation of an intermediate, tentatively ascribed to glycyl radical and acrylate. The rates of formation and decay of this intermediate were also sufficiently rapid for it to be kinetically competent. When combined with information from previous mechanistic studies, these results allow a qualitative free energy profile to constructed for the reaction catalyzed by glutamate mutase.

Glutamate mutase from Clostridium cochlearium: the structure of a coenzyme B12-dependent enzyme provides new mechanistic insights.

Glutamate mutase (Glm) equilibrates (S)-glutamate with (2S,3S)-3-methylaspartate. Catalysis proceeds with the homolytic cleavage of the organometallic bond of the cofactor to yield a 5'-desoxyadenosyl radical. This radical then abstracts a hydrogen atom from the protein-bound substrate to initiate the rearrangement reaction. Glm from Clostridium cochlearium is a heterotetrameric molecule consisting of two sigma and two epsilon polypeptide chains. We have determined the crystal structures of inactive recombinant Glm reconstituted with either cyanocobalamin or methylcobalamin. The molecule shows close similarity to the structure of methylmalonyl CoA mutase (MCM), despite poor sequence similarity between its catalytic epsilon subunit and the corresponding TIM-barrel domain of MCM. Each of the two independent B12 cofactor molecules is associated with a substrate-binding site, which was found to be occupied by a (2S,3S)-tartrate ion. A 1:1 mixture of cofactors with cobalt in oxidation states II and III was observed in both crystal structures of inactive Glm. The long axial cobalt-nitrogen bond first observed in the structure of MCM appears to result from a contribution of the species without upper ligand. The tight binding of the tartrate ion conforms to the requirements of tight control of the reactive intermediates and suggests how the enzyme might use the substrate-binding energy to initiate cleavage of the cobalt-carbon bond. The cofactor does not appear to have a participating role during the radical rearrangement reaction.

Structure and dynamics of the B12-binding subunit of glutamate mutase from Clostridium cochlearium.

Glutamate mutase (Glm) is an adenosylcobamide-dependent enzyme that catalyzes the reversible rearrangement of (2S)-glutamate to (2S, 3S)-3-methylaspartate. The active enzyme from Clostridium cochlearium consists of two subunits (of 53.6 and 14.8 kDa) as an alpha2beta2 tetramer, whose assembly is mediated by coenzyme B12. The smaller of the protein components, GlmS, has been suggested to be the B12-binding subunit. Here we report the solution structure of GlmS, determined from a heteronuclear NMR-study, and the analysis of important dynamical aspects of this apoenzyme subunit. The global fold and dynamic behavior of GlmS in solution are similar to those of the corresponding subunit MutS from C. tetanomorphum, which has previously been investigated using NMR-spectroscopy. Both solution structures of the two Glm B12-binding subunits share striking similarities with that determined by crystallography for the B12-binding domain of methylmalonyl CoA mutase (Mcm) from Propionibacterium shermanii, which is B12 bound. In the crystal structure a conserved histidine residue was found to be coordinated to cobalt, displacing the endogenous axial ligand of the cobamide. However, in GlmS and MutS the sequence motif, Asp-x-His-x-x-Gly, which includes the cobalt-coordinating histidine residue, and a predicted alpha-helical region following the motif, are present as an unstructured and highly mobile loop. In the absence of coenzyme, the B12-binding site apparently is only partially formed. By comparing the crystal structure of Mcm with the solution structures of B12-free GlmS and MutS, a consistent picture on the mechanism of B12 binding has been obtained. Important elements of the binding site only become structured upon binding B12; these include the cobalt-coordinating histidine residue, and an alpha helix that forms one side of the cleft accommodating the nucleotide 'tail' of the coenzyme.

The Reaction of the Substrate Analog 2-Ketoglutarate with Adenosylcobalamin-dependent Glutamate Mutase

Glutamate mutase is one of several adenosylcobalamin-dependent enzymes that catalyze unusual rearrangements that proceed through a mechanism involving free radical intermediates. The enzyme exhibits remarkable specificity, and so far no molecules other than L-glutamate and L-threo-3-methylaspartate have been found to be substrates. Here we describe the reaction of glutamate mutase with the substrate analog, 2-ketoglutarate. Binding of 2-ketoglutarate (or its hydrate) to the holoenzyme elicits a change in the UV-visible spectrum consistent with the formation of cob(II)alamin on the enzyme. 2-ketoglutarate undergoes rapid exchange of tritium between the 5'-position of the coenzyme and C-4 of 2-ketoglutarate, consistent with the formation of a 2-ketoglutaryl radical analogous to that formed with glutamate. Under aerobic conditions this leads to the slow inactivation of the enzyme, presumably through reaction of free radical species with oxygen. Despite the formation of a substrate-like radical, no rearrangement of 2-ketoglutarate to 3-methyloxalacetate could be detected. The results indicate that formation of the C-4 radical of 2-ketoglutarate is a facile process but that it does not undergo further reactions, suggesting that this may be a useful substrate analog with which to investigate the mechanism of coenzyme homolysis.

Radical species in the catalytic pathways of enzymes from anaerobes

Radicals are reactive intermediates of growing importance in enzymatic catalysis. There are reactions in which neutral radicals participate and those where radical anions are involved. The former class is illustrated by lysine 2,3-aminomutase and also by enzymes dependent on coenzyme B12, that catalyse carbon skeleton rearrangements (e.g. glutamate mutase). A substrate-based radical for both lysine 2,3-aminomutase and glutamate mutase has been characterised by EPR spectroscopy. Representatives of the second class are 2-hydroxyglutaryl-CoA dehydratase, benzoyl-CoA reductase, DNA photolyase and chorismate synthase, all of which may generate the radical anion by one-electron reduction. 4-Hydroxybutyryl-CoA dehydratase, pyruvate formate lyase, and the coenzyme B12-dependent eliminases (ribonucleotide reductase, ethanolamine ammonia lyase and diol dehydratase) could be examples of radical anion formation by one-electron oxidation. The electron-rich ketyl-like radical anions cause the elimination of an adjacent group. The advantages of using radicals as intermediates in enzymatic transformations are their high reactivity and special properties. However, this reactivity includes rapid bimolecular combination with dioxygen and radicals are therefore primarily utilised as intermediates by anaerobic organisms.

Crystallization and preliminary X-ray analysis of recombinant glutamate mutase and of the isolated component S from Clostridium cochlearium.

Glutamate mutase [varepsilon2sigma2(B12)1] was reconstituted by incubating purified components E (varepsilon2) and S (sigma2) from Clostridium cochlearium, both produced in Escherichia coli, with either aquo- or cyanocobalamin. The inactive glutamate mutase obtained was crystallized with polyethyleneglycol 4000 as precipitant. Crystals are monoclinic with space group P21 and have cell dimensions a = 64.6, b = 113.2, c = 108.4 A and beta = 96.0 degrees for the glutamate mutase reconstituted with aquocobalamin. They diffract to a resolution of at least 2.7 A. Isolated component S was crystallized in the presence of an excess of cyanocobalamin, yielding red crystals of space group I422 with unit-cell dimensions of a = b = 69.9 and c = 107.1 A. The crystals diffract to about 3.2 A resolution. Native data sets were collected for both crystal forms.

How a protein prepares for B12 binding: structure and dynamics of the B12-binding subunit of glutamate mutase from Clostridium tetanomorphum.

Glutamate mutase is an adenosylcobamide (coenzyme B12) dependent enzyme that catalyzes the reversible rearrangement of (2S)-glutamate to (2S,3S)-3-methylaspartate. The enzyme from Clostridium tetanomorphum comprises two subunits (of 53.7 and 14.8 kDa) and in its active form appears to be an alpha 2 beta 2 tetramer. The smaller subunit, termed MutS, has been characterized as the B12-binding component. Knowledge on the structure of a B12-binding apoenzyme does not exist. The solution structure and important dynamical aspects of MutS have been determined from a heteronuclear NMR study. The global fold of MutS in solution resembles that determined by X-ray crystallography for the B12-binding domains of Escherichia coli methionine synthase and Propionibacterium shermanii methylmalonyl CoA mutase. In these two proteins a histidine residue displaces the endogenous cobalt-coordinating ligand of the B12 cofactor. In MutS, however, the segment of the protein containing the conserved histidine residue forms part of an unstructured and mobile extended loop. A comparison of the crystal structures of two B12-binding domains, with bound B12 cofactor, and the solution structure of the apoprotein MutS has helped to clarify the mechanism of B12 binding. The major part of MutS is preorganized for B12 binding, but the B12-binding site itself is only partially formed. Upon binding B12, important elements of the binding site appear to become structured, including an alpha helix that forms one side of the cleft accommodating the nucleotide 'tail' of the cofactor.

Coupling of cobalt-carbon bond homolysis and hydrogen atom abstraction in adenosylcobalamin-dependent glutamate mutase.

Adenosylcobalamin-dependent glutamate mutase catalyzes an unusual carbon skeleton rearrangement that proceeds through the formation of free radical intermediates generated by the substrate-induced cleavage of the coenzyme cobalt-carbon bond. The reaction was studied at 10 degrees C with various concentrations of L-glutamate and L-threo-3-methylaspartate and with use of stopped-flow spectroscopy to follow the formation of cob(II)alamin. Either substrate induces rapid formation of cob(II)alamin, which accumulates to account for about 25% of the total enzyme species in the steady state when substrate is saturating. Measurements of the rate constant for the formation of cob(II)alamin demonstrate that the enzyme accelerates the rate of homolysis of the cobalt-carbon bond by at least 10(12)-fold. Very large isotope effects on cob(II)alamin formation, of 28 and 35, are observed with deuterated L-glutamate and deuterated L-threo-3-methylaspartate, respectively. This implies a mechanism in which Co-C bond homolysis is kinetically coupled to substrate hydrogen abstraction. Therefore, adenosyl radical can only be formed as a high-energy intermediate only at very low concentrations on the enzyme. The magnitude of the isotope effects suggests that hydrogen tunneling may play an important role catalysis.

Non-fatty acyl polyketide starter in the biosynthesis of vicenistatin, an antitumor macrolactam antibiotic

Abstract A biosynthetic pathway of an antitumor antibiotic vicenistatin was investigated by feeding experiments of [1- 13 C] and [1,2- 13 C 2 ]acetate, [1- 13 C]propionate, [2,3,3- 2 H 3 ]glutamate, and d -[6,6- 2 H 2 ]glucose. The elongating units of the aglycon of vicenistatin are derived from standard acetate-propionate, whereas the starter unit appears to be derived from a 3-amino-2-methylpropionate equivalent through the glutamate mutase reaction.

Identification of the 4-Glutamyl Radical as an Intermediate in the Carbon Skeleton Rearrangement Catalyzed by Coenzyme B12-Dependent Glutamate Mutase from Clostridium cochlearium

A series of 2H- and 13C-labeled glutamates were used as substrates for coenzyme B12-dependent glutamate mutase, which equilibrates (S)-glutamate with (2S,3S)-3-methylaspartate. These compounds contained the isotopes at C-2, C-3, or C-4 of the carbon chain: [2-2H], [3,3-2H2], [4,4-2H2], [2,3,3,4,4-2H5], [2-13C], [3-13C], and [4-13C]glutamate. Each reaction was monitored by electron paramagnetic resonance (EPR) spectroscopy and revealed a similar signal characterized by g'xy = 2.1, g'z = 1.985, and A' = 5.0 mT. The interpretation of the spectral data was aided by simulations which gave close agreement with experiment. This approach underpinned the idea of the formation of a radical pair, consisting of cob(II)alamin interacting with an organic radical at a distance of 6.6 +/- 0.9 A. Comparison of the hyperfine couplings observed with unlabeled glutamate with those from the labeled glutamates enabled a principal contributor to the radical pair to be identified as the 4-glutamyl radical. These findings support the currently accepted mechanism for the glutamate mutase reaction, i.e., the process is initiated through hydrogen atom abstraction from C-4 of glutamate by the 5'-deoxyadenosyl radical, which is derived by homolysis of the Co-C sigma-bond of coenzyme B12.

3-Methylaspartate ammonia-lyase as a marker enzyme of the mesaconate pathway for (S)-glutamate fermentation in Enterobacteriaceae.

The enzyme 3-methylaspartase (3-methylaspartate ammonia-lyase, EC 4. 3.1.2) was found in the cells of enteric bacteria, especially in the genera Citrobacter and Morganella, that were grown under anoxic and oxygen-limited conditions. The enzymes were purified to homogeneity from the cell-free extracts of 18 active strains and had similar enzymological properties such as action on columns, specific activity, molecular weight, subunit structure, and N-terminal amino acid sequence similarity. The production of the enzyme was dependent on the limitation of oxygen during growth and was arrested by aeration. The addition of external electron acceptors such as dimethylsulfoxide could support cell growth and production of the enzyme. Activities of glutamate mutase (EC 5.4.99.1) and (S)-citramalate hydrolyase (EC 4.2.1.34), key enzymes of the mesaconate pathway of (S)-glutamate fermentation in the genus Clostridium, were detected in the cells of the active strains grown under oxygen-limited conditions. Based on the results, the mesaconate pathway is proposed to explain the (S)-glutamate fermentation process observed in Enterobacteriaceae, and 3-methylaspartase could be a marker enzyme for this pathway.

Adenosylcobalamin-dependent glutamate mutase: examination of substrate and coenzyme binding in an engineered fusion protein possessing simplified subunit structure and kinetic properties.

Glutamate mutase is comprised of two weakly associating subunits; E and S, that combine to form the coenzyme binding site. The active holoenzyme assembles in a kinetically complex process in which both the stoichiometry and apparent Kd for adenosylcobalamin (AdoCbl) are dependent upon the relative concentrations of the two subunits, as is the enzyme's specific activity. To facilitate mechanistic and structural studies on this enzyme we have genetically fused the S subunit to the C-terminus of the E subunit through an 11 amino acid (Gly-Gln)5-Gly linker segment. This protein, GlmES, binds AdoCbl stoichiometrically and neither the affinity for AdoCbl nor the turnover number depends upon protein concentration. The kcat and Km for both substrate and coenzyme, together with the deuterium isotope effects on Vmax and Vmax/Km, have been determined for the GlmES-catalyzed reaction proceeding in both directions. Compared with wild type, the affinity for AdoCbl is unchanged, but for the conversion of L-glutamate to (2S,3S)-3-methylaspartate both kcat and Km for L-glutamate are decreased by about a third and the isotope effects are reduced, suggesting product release to be more rate-limiting. To test hypotheses concerning the activation of the coenzyme, we examined the binding of adenosylcobalamin, methylcobalamin, and cob(II)alamin to the enzyme. Each of these is bound with essentially the same affinity (2 microM), suggesting that, contrary to expectations, interactions between the protein and the adenosyl moiety do not serve to weaken the cobalt-carbon bond in the ground state.

How enzymes control the reactivity of adenosylcobalamin: effect on coenzyme binding and catalysis of mutations in the conserved histidine-aspartate pair of glutamate mutase.

Glutamate mutase is one of a group of adenosylcobalamin-dependent enzymes that catalyze unusual isomerizations that proceed through the formation of radical intermediates. It shares a structurally similar cobalamin-binding domain with methylcobalamin-dependent methionine synthase. In particular, both proteins contain the "DXHXXG" cobalamin-binding motif, in which the histidine provides the axial ligand to cobalt. The effects of mutating the conserved histidine and aspartate residues in methionine synthase have recently been described [Jarrett, J. T., Amaratunga, M., Drennan, C. L., Scholten, J. D., Sands, R. H., Ludwig, M. L., & Matthews, R. G. (1996) Biochemistry 35, 2464-2475]. Here, we describe how similar mutations in the "DXHXXG" motif of glutamate mutase affect coenzyme binding and catalysis in an adenosylcobalamin-dependent reaction. The mutations made in the MutS subunit of glutamate mutase were His16Gly, His16Gln, Asp14Asn, Asp14Glu, and Asp14Ala. All the mutations affect, in varying degrees, the rate of catalysis, the affinity of the protein for the coenzyme, and the coordination of cobalt. Mutations of either Asp14 or His16 decrease k(cat) by 1000-fold, and whereas cob(II)alamin accumulates as an intermediate in the wild-type enzyme, it does not accumulate in the mutants, suggesting the rate-determining step is altered. The apparent Kd for adenosylcobalamin is raised by about 50-fold when His16 is mutated and by 5-10-fold when Asp16 is mutated. There are extensive differences between the UV-visible spectra of wild-type and mutant holoenzymes, indicating that the mutant enzymes coordinate cobalt less well. Overall, the properties of these mutants differ quite markedly from those observed when similar mutations were introduced into methionine synthase.

Adenosylcobalamin-dependent glutamate mutase: properties of a fusion protein in which the cobalamin-binding subunit is linked to the catalytic subunit.

Adenosylcobalamin-dependent glutamate mutase (EC 5.4.99.1) from Clostridium tetanomorphum comprises two protein components, MutE and MutS. The formation of the holoenzyme is a kinetically complex process that involves the co-operative association of MutS, MutE and adenosylcobalamin. The MutS portion of the cobalamin-binding site is conserved within a group of adenosylcobalamin-dependent enzymes that catalyse similar isomerizations. However, in contrast with glutamate mutase, in these other enzymes the cobalamin-binding region represented by MutS is present as a C-terminal domain. We have investigated the effect on the structural and kinetic properties of glutamate mutase of linking MutS to the C-terminus of MutE. Kinetic analysis of this protein, MutES, showed, unexpectedly, that enzyme activity was still co-operatively dependent on protein concentration. The Km for L-glutamate was unchanged from the wild type, whereas Vmax was decreased to approx. one-thirtieth and the Km for coenzyme increased approx. 10-fold. Investigation of the quaternary structure of MutES by equilibrium ultra-centrifugation indicated that the protein existed in equilibrium between monomeric and dimeric forms. Thus linking MutE and MutS together seems to substantially weaken the contacts that are responsible for the dimerization of MutE. The two domains of the MutES monomer seem unable to communicate, so that active enzyme is formed by the intermolecular association of two MutES subunits in a co-operative manner.

Carboxymethylation of MutS-Cysteine-15 Specifically Inactivates Adenosylcobalamin-dependent Glutamate Mutase: EXAMINATION OF THE ROLE OF THIS RESIDUE IN COENZYME-BINDING AND CATALYSIS

The sensitivity of adenosylcobalamin (AdoCbl)-dependent glutamate mutase toward thiol-directed reagents has been investigated. Iodoacetate specifically alkylates one cysteine residue, Cys-15, in MutS with concomitant irreversible loss of enzyme activity. Cys-15 lies between the conserved residues Asp-14 and His-16, that are believed to coordinate cobalt to form a Co-His-Asp hydrogen-bonded "triad" when AdoCbl is bound by the enzyme. Although inactive, carboxymethylated MutS still bound AdoCbl with only a 5-fold increase in apparent Kd. To determine whether Cys-15 plays an essential role in catalysis, it was mutated to serine and to alanine. These mutants were active, but both exhibited decreased Vmax and increased apparent Km and Kd for AdoCbl. To mimic the effect of carboxymethylation, Cys15 was mutated to aspartate and, as an isosteric control, to asparagine. Neither of these mutants was active: MutS-C15N bound AdoCbl approximately 10-fold weaker than wild type, whereas MutS-C15N bound AdoCbl over 100 times less strongly than wild type. The results demonstrate both coenzyme-binding and catalysis to be very sensitive to mutations at position 15 that could potentially perturb the Co-His-Asp hydrogen-bonding network.