On the mechanism of action of methylmalonyl-CoA mutase. Change of the steric course on isotope substitution

Emerging Roles of Vitamin B12 in Aging and Inflammation

Vitamin B12 (cobalamin) is an essential nutrient for humans and animals. Metabolically active forms of B12-methylcobalamin and 5-deoxyadenosylcobalamin are cofactors for the enzymes methionine synthase and mitochondrial methylmalonyl-CoA mutase. Malfunction of these enzymes due to a scarcity of vitamin B12 leads to disturbance of one-carbon metabolism and impaired mitochondrial function. A significant fraction of the population (up to 20%) is deficient in vitamin B12, with a higher rate of deficiency among elderly people. B12 deficiency is associated with numerous hallmarks of aging at the cellular and organismal levels. Cellular senescence is characterized by high levels of DNA damage by metabolic abnormalities, increased mitochondrial dysfunction, and disturbance of epigenetic regulation. B12 deficiency could be responsible for or play a crucial part in these disorders. In this review, we focus on a comprehensive analysis of molecular mechanisms through which vitamin B12 influences aging. We review new data about how deficiency in vitamin B12 may accelerate cellular aging. Despite indications that vitamin B12 has an important role in health and healthy aging, knowledge of the influence of vitamin B12 on aging is still limited and requires further research.

Cofactor Editing by the G-protein Metallochaperone Domain Regulates the Radical B12 Enzyme IcmF

IcmF is a 5'-deoxyadenosylcobalamin (AdoCbl)-dependent enzyme that catalyzes the carbon skeleton rearrangement of isobutyryl-CoA to butyryl-CoA. It is a bifunctional protein resulting from the fusion of a G-protein chaperone with GTPase activity and the cofactor- and substrate-binding mutase domains with isomerase activity. IcmF is prone to inactivation during catalytic turnover, thus setting up its dependence on a cofactor repair system. Herein, we demonstrate that the GTPase activity of IcmF powers the ejection of the inactive cob(II)alamin cofactor and requires the presence of an acceptor protein, adenosyltransferase, for receiving it. Adenosyltransferase in turn converts cob(II)alamin to AdoCbl in the presence of ATP and a reductant. The repaired cofactor is then reloaded onto IcmF in a GTPase-gated step. The mechanistic details of cofactor loading and offloading from the AdoCbl-dependent IcmF are distinct from those of the better characterized and homologous methylmalonyl-CoA mutase/G-protein chaperone system.

Optimization and validation of a reversed-phase high performance liquid chromatography method for the measurement of bovine liver methylmalonyl-coenzyme a mutase activity

Background

Methylmalonyl-CoA mutase (MCM) is an adenosylcobalamin-dependent enzyme that catalyses the interconversion of (2R)-methylmalonyl-CoA to succinyl-CoA. In humans, a deficit in activity of MCM, due to an impairment of intracellular formation of adenosylcobalamin and methylcobalamin results in a wide spectrum of clinical manifestations ranging from moderate to fatal. Consequently, MCM is the subject of abundant literature. However, there is a lack of consensus on the reliable method to monitor its activity. This metabolic pathway is highly solicited in ruminants because it is essential for the utilization of propionate formed during ruminal fermentation. In lactating dairy cows, propionate is the major substrate for glucose formation. In present study, a reversed-phase high performance liquid chromatography (RP-HPLC) was optimized and validated to evaluate MCM activity in bovine liver. The major aim of the study was to describe the conditions to optimize reproducibility of the method and to determine stability of the enzyme and its product during storage and processing of samples.

Results

Specificity of the method was good, as there was no interfering peak from liver extract at the retention times corresponding to methylmalonyl-CoA or succinyl-CoA. Repeatability of the method was improved as compared to previous RP-HPLC published data. Using 66 μg of protein, intra-assay coefficient of variation (CV) of specific activities, ranged from 0.90 to 8.05% and the CV inter-day was 7.40%. Storage and processing conditions (frozen homogenate of fresh tissue vs. fresh homogenate of tissue snapped in liquid nitrogen) did not alter the enzyme activity. The analyte was also stable in liver crude extract for three frozen/thawed cycles when stored at -20°C and thawed to room temperature.

Conclusions

The improved method provides a way for studying the effects of stages of lactation, diet composition, and physiology in cattle on MCM activity over long periods of time, such as a complete lactation period. Interestingly, this sensitive and accurate method could benefit the study of the cobalamin status in experimental studies and clinical cases.

Protection of radical intermediates at the active site of adenosylcobalamin-dependent methylmalonyl-CoA mutase

Adenosylcobalamin-dependent methylmalonyl-CoA mutase catalyzes the interconversion of methylmalonyl-CoA and succinyl-CoA via radical intermediates generated by substrate-induced homolysis of the coenzyme carbon-cobalt bond. From the structure of methylmalonyl-CoA mutase it is evident that the deeply buried active site is completely shielded from solvent with only a few polar contacts made between the protein and the substrate. Site-directed mutants of amino acid His244, a residue close to the inferred site of radical chemistry, were engineered to investigate its role in catalysis. Two mutants, His244Ala and His244Gln, were characterized using kinetic and spectroscopic techniques. These results confirmed that His244 is not an essential residue. However, compared with that of the wild type, k(cat) was lowered by 10(2)- and 10(3)-fold for the His244Gln and His244Ala mutants, respectively, while the K(m) for succinyl-CoA was essentially unchanged in both cases. The primary kinetic tritium isotope effect (k(H)/k(T)) for the His244Gln mutant was 1.5 +/- 0.3, and tritium partitioning was now found to be dependent on the substrate used to initiate the reaction, indicating that the rearrangement of the substrate radical to the product radical was extremely slow. The His244Ala mutant underwent inactivation under aerobic conditions at a rate between 1 and 10% of the initial rate of turnover. The crystal structure of the His244Ala mutant, determined at 2.6 A resolution, indicated that the mutant enzyme is unaltered except for a cavity in the active site which is occupied by an ordered water molecule. Molecular oxygen reaching this cavity may lead directly to inactivation. These results indicate that His244 assists directly in the unusual carbon skeleton rearrangement and that alterations in this residue substantially lower the protection of reactive radical intermediates during catalysis.

Evidence for a 1,2 Shift of a Hydrogen Atom in a Radical Intermediate of the Methylmalonyl-CoA Mutase Reaction

An excellent substrate of methylmalonyl-CoA mutase, methylmalonyl-carba-(dethia) coenzyme A (methylmalonyl-CH(2)-CoA), was synthesized by a chemoenzymatic method and its alpha-proton was exchanged with deuterium by long-term incubation in deuterium oxide at pH 6.9. After addition of highly purified epimerase-free methylmalonyl-CoA mutase the enzymatic rearrangement was monitored by 1H NMR spectroscopy. Already in the initial phases of the reaction only 72% of the produced succinyl-CH(2)-CoA was monodeuterated, while unlabeled and geminally dideuterated species, 14% of each, were also formed. After the addition of more enzyme the equilibrium (methylmalonyl-CoA:succinyl-CoA = 1:20) was quickly established, while the proportion of unlabeled succinyl-CH(2)-CoA rose to 30% and the geminally dideuterated species were slowly transformed to vicinally dideuterated ones. After 19 h of incubation the ratio of the unlabeled, monodeuterated, and dideuterated species was roughly 1:1:1 while no appreciable deuterium incorporation from the solvent occurred. The unexpected disproportionation of deuterium can be best explained by a 1,2 shift of a hydrogen atom in the succinyl-CH(2)-CoA radical intermediate competing with the hydrogen transfer from 5'-deoxyadenosine. A precedence for such a hydrogen shift in a radical was previously observed only in the mass spectrometer and was supported by ab initio calculations. Copyright 2000 Academic Press.

Crystal structure of substrate complexes of methylmalonyl-CoA mutase

X-ray crystal structures of methylmalonyl-CoA mutase in complexes with substrate methylmalonyl-CoA and inhibitors 2-carboxypropyl-CoA and 3-carboxypropyl-CoA (substrate and product analogues) show that the enzyme-substrate interactions change little during the course of the rearrangement reaction, in contrast to the large conformational change on substrate binding. The substrate complex shows a 5'-deoxyadenine molecule in the active site, bound weakly and not attached to the cobalt atom of coenzyme B12, rotated and shifted from its position in the substrate-free adenosylcobalamin complex. The position of Tyralpha89 close to the substrate explains the stereochemical selectivity of the enzyme for (2R)-methylmalonyl-CoA.

Stabilization of radical intermediates by an active-site tyrosine residue in methylmalonyl-CoA mutase

The adenosylcobalamin-dependent methylmalonyl-CoA mutase catalyzes the reversible rearrangement of methylmalonyl-CoA into succinyl-CoA by a free-radical mechanism. The recently solved X-ray crystal structure of methylmalonyl-CoA mutase from Propionibacterium shermanii has shown that tyrosine 89 is an active-site residue involved in substrate binding. The role of tyrosine 89, a conserved residue among methylmalonyl-CoA mutases, has been investigated by using site-directed mutagenesis to replace this residue with phenylalanine. The crystal structure of the Tyr89Phe mutant was determined to 2.2 A resolution and was found to be essentially superimposable on that of wild-type. Mutant and wild-type enzyme have very similar KM values, but kcat for the Tyr89Phe mutant is 580-fold lower than for wild-type. The rate of release of tritium from 5'-[3H]adenosylcobalamin during the enzymatic reaction and its rate of appearance in substrate and product were measured. The tritium released was found to partition unequally between methylmalonyl-CoA and succinyl-CoA, in a ratio of 40:60 when the reaction was initiated by addition of methylmalonyl-CoA and in a ratio of 10:90 when the reaction was initiated by addition of succinyl-CoA. The overall release of tritium was four times faster when succinyl-CoA was used as substrate. The tritium isotope effect on the enzyme catalyzed hydrogen transfer, measured with methylmalonyl-CoA as a substrate, was kH/kT = 30, which is within the expected range for a full primary kinetic tritium isotope effect. The different partitioning of tritium, dependent upon which substrate was used, and the normal value for the kinetic tritium isotope effect contrast markedly with the behavior of wild-type mutase. It appears that the loss of a single interaction involving the hydroxyl group of tyrosine 89 both affects the stability of radical intermediates and decreases the rate of interconversion of the substrate- and product-derived radicals.

Structure-based perspectives on B12-dependent enzymes

Two X-ray structures of cobalamin (B12) bound to proteins have now been determined. These structures reveal that the B12 cofactor undergoes a major conformational change on binding to the apoenzymes of methionine synthase and methylmalonyl-coenzyme A mutase: The dimethylbenzimidazole ligand to the cobalt is displaced by a histidine residue from the protein. Two methyltransferases from archaebacteria that catalyze methylation of mercaptoethanesulfonate (coenzyme M) during methanogenesis have also been shown to contain histidine-ligated cobamides. In corrinoid iron-sulfur methyltransferases from acetogenic and methanogenic organisms, benzimidazole is dissociated from cobalt, but without replacement by histidine. Thus, dimethylbenzimidazole displacement appears to be an emerging theme in cobamide-containing methyltransferases. In methionine synthase, the best studied of the methyltransferases, the histidine ligand appears to be required for competent methyl transfer between methyl-tetrahydrofolate and homocysteine but dissociates for reductive reactivation of the inactive oxidized enzyme. Replacement of dimethylbenzimidazole by histidine may allow switching between the catalytic and activation cycles. The best-characterized B12-dependent mutases that catalyze carbon skeleton rearrangement, for which methylmalonyl-coenzyme A mutase is the prototype, also bind cobalamin cofactors with histidine as the cobalt ligand, although other cobalamin-dependent mutases do not appear to utilize histidine ligation. It is intriguing to find that mutases, which catalyze homolytic rather than heterolytic cleavage of the carbon-cobalt bond, can use this structural motif. In methylmalonylCoA mutase a significant feature, which may be important in facilitating homolytic cleavage, is the long cobalt-nitrogen bond linking histidine to the co-factor. The intermediate radical species generated in catalysis are sequestered in the relatively hydrophilic core of an alpha/beta barrel domain of the mutase.

Tritium isotope effects in adenosylcobalamin-dependent methylmalonyl-CoA mutase

Methylmalonyl-CoA mutase from Propionibacterium shermanii is an adenosylcobalamin-dependent enzyme which catalyzes the reversible isomerization of methylmalonyl-CoA and succinyl-CoA. The rate of tritium loss from 5'-[3H]adenosylcobalamin during the enzymic reaction and the relative rates of tritium appearance in substrate and product were examined. Upon the addition of methylmalonyl-CoA to a solution of holoenzyme, tritium was completely released from the cofactor within about 500 ms. No tritium was found either bound to the enzyme or released into the water. The radioactivity was found in methylmalonyl-CoA and succinyl-CoA in a constant ratio of 1 to 3, which did not change during the first 300 ms of the reaction. Upon the addition of succinyl-CoA to a solution of holoenzyme, tritium was released at essentially the same rate, and the radioactivity was found in methylmalonyl-CoA and succinyl-CoA in the identical constant ratio of 1 to 3. The tritium isotope effect on the enzyme-catalyzed hydrogen transfer, measured using 14C-labeled methylmalonyl-CoA as substrate, was kH/kT = 4.9. This low value shows that hydrogen transfer is only partly rate limiting and that at least one subsequent slow step, such as product release, contributes substantially to the overall reaction velocity. The identical partitioning of tritium, regardless of the substrate used, shows that the rearrangement of the substrate radical into the product radical is not rate limiting. The very low tritium isotope effect and the fact that all the tritium is found bound either to the CoA esters or to the cofactor make it very unlikely that a protein radical is an intermediate in the methylmalonyl-CoA mutase-catalyzed rearrangement.

How coenzyme B12 radicals are generated: the crystal structure of methylmalonyl-coenzyme A mutase at 2 A resolution

BACKGROUND

The enzyme methylmalonyl-coenzyme A (CoA) mutase, an alphabeta heterodimer of 150 kDa, is a member of a class of enzymes that uses coenzyme B12 (adenosylcobalamin) as a cofactor. The enzyme induces the formation of an adenosyl radical from the cofactor. This radical then initiates a free-radical rearrangement of its substrate, succinyl-CoA, to methylmalonyl-CoA.

RESULTS

Reported here is the crystal structure at 2 A resolution of methylmalonyl-CoA mutase from Propionibacterium shermanii in complex with coenzyme B12 and with the partial substrate desulpho-CoA (lacking the succinyl group and the sulphur atom of the substrate). The coenzyme is bound by a domain which shares a similar fold to those of flavodoxin and the B12-binding domain of methylcobalamin-dependent methionine synthase. The cobalt atom is coordinated, via a long bond, to a histidine from the protein. The partial substrate is bound along the axis of a (beta/alpha)8 TIM barrel domain.

CONCLUSIONS

The histidine-cobalt distance is very long (2.5 A compared with 1.95-2.2 A in free cobalamins), suggesting that the enzyme positions the histidine in order to weaken the metal-carbon bond of the cofactor and favour the formation of the initial radical species. The active site is deeply buried, and the only access to it is through a narrow tunnel along the axis of the TIM barrel domain.

Electron paramagnetic resonance studies of the methylmalonyl-CoA mutase reaction. Evidence for radical intermediates using natural and artificial substrates as well as the competitive inhibitor 3-carboxypropyl-CoA

The substrate-dependent homolysis of the cobalt-carbon bond and generation of organic radicals in the coenzyme-B12-methylmalonyl-CoA-mutase complex have been demonstrated by EPR measurements. Both the natural substrate methylmalonyl-CoA, its 13C-substituted analogue and the non-hydrolysable synthetic substrates succinyl-dethia(carba)-CoA, succinyl-dethia(dicarba)-CoA and 4-carboxy-2-oxo-butyl-CoA induced similar but not identical EPR signals. 3-Carboxypropyl-CoA, a novel competitive inhibitor, has been synthesised. Its Ki value of 89 +/- 6 microM was in the same range as the Km of succinyl-CoA. Using [5'-3H]adenosylcobalamin, an enzyme-dependent tritium transfer to the inhibitor has been shown. The enzyme-coenzyme-inhibitor complex also exhibited EPR signals that were less structured and less intensive than the corresponding signals with active substrates. These results prove that the inhibitor also induces cobalt-carbon bond homolysis and undergoes reversible hydrogen transfer but not rearrangement.

Adenosylcobalamin-dependent methylmalonyl-CoA mutase from Propionibacterium shermanii. Active holoenzyme produced from Escherichia coli

The linked structural genes coding for both subunits of adenosylcobalamin-dependent methylmalonyl-CoA mutase from the Gram-positive bacterium Propionibacterium shermanii have been altered by site-directed mutagenesis and placed under the control of an inducible phage-T7-specific plasmid promoter in Escherichia coli. Conditions have been found under which both alpha- and beta-subunits are produced in soluble form, in near 1:1 ratio, and assemble to form apo-mutase totalling about 5% of the total cellular protein. Methylmalonyl-CoA mutase purified from these cells could be readily converted into the holoenzyme by addition of adenosylcobalamin. The active holoenzyme apparently crystallizes in the same space group as an inactive corrinoid-containing form of the enzyme obtained previously.

Cloning and structural characterization of the genes coding for adenosylcobalamin-dependent methylmalonyl-CoA mutase from Propionibacterium shermanii

The structural genes coding for both subunits of adenosylcobalamin-dependent methylmalonyl-CoA mutase from the Gram-positive bacterium Propionibacterium shermanii have been cloned, with the use of synthetic oligonucleotides as primary hybridization probes. The genes are closely linked and are transcribed in the same direction. Nucleotide sequence analysis of 4.5 kb of DNA encompassing both genes allowed us to infer the complete amino acid sequence of the two subunits: the beta-subunit is the product of the upstream gene, and consists of 638 amino acid residues (Mr 69465) and the alpha-subunit consists of 728 amino acid residues (Mr 80,147). There is a very close structural homology between the two subunits, reflecting the probable duplication of a common ancestral gene. A sequence present only in the alpha-subunit is significantly homologous to a portion of the sequence of the methylmalonyl-CoA-binding subunit of transcarboxylase from P. shermanii [Samols, Thornton, Murtif, Kumar, Haase & Wood (1988) J. Biol. Chem. 263, 6461-6464], and this homologous region may form part of the CoA ester-binding site in both enzymes.

The error in the cryptic stereospecificity of methylmalonyl-CoA mutase. The use of carba-(dethia)-coenzyme A substrate analogues gives new insight into the enzyme mechanism

A preparation containing 80.0 +/- 0.5% (2RS)-methylmalonyl-carba-(dethia)-CoA and 20.0 +/- 0.5% propionyl-carba-(dethia)-CoA was reacted in buffered deuterium oxide with catalytic amounts of coenzyme B12, methylmalonyl-CoA mutase and methylmalonyl-CoA epimerase. The rearrangement of the methylmalonyl-carba-(dethia)-CoA to succinyl-carba-(dethia)-CoA was monitored by recording 500-MHz 1H-NMR spectra in short time intervals. After reaching equilibrium (approximately equal to 28 min) the products showed chemical stability for about 17 h, i.e. succinyl species did not undergo the spontaneous hydrolysis encountered with normal succinyl-CoA. In the pre-equilibrium stage only about 66% of the produced succinyl-CH2CoA was the expected monodeuterated species. The remainder was 15.5% unlabelled and 18.3% 3,3-dideuterated. After reaching equilibrium a continuous deuterium incorporation (washing-in) from the solvent to the products was observed and quantified. The time course of the appearance of unlabelled, mono-, di- and trideuterated succinyl-CH2CoA species was determined by assigning and integrating the isotope-shifted 1H signals from the various species. Furthermore, mutase catalyses slow deuterium incorporation into first the methylene and then the methyl group of propionyl-CH2CoA. On the basis of these data it was concluded that methylmalonyl-CoA mutase and epimerase are responsible for continuous deuterium incorporation and multiple incorporation occurs when the backward reaction (succinyl-CH2CoA----methylmalonyl-CH2CoA) becomes important. To account for all of the results obtained with dethia and natural substrates we propose a new mutase mechanism whereby the enzyme can retain full stereospecificity at C-3 of succinyl while an internal 1,2-H shift to give a C-2 succinyl radical is responsible for partial scrambling of diastereotopic protons at C-3. This mechanism successfully predicts the observed deuterium disproportionation in succinyl species and the order of appearance of di- and trideuterated products via the washing-in process.

Crystallization and preliminary diffraction data for adenosylcobalamin-dependent methylmalonyl-CoA mutase from Propionibacterium shermanii

Pink crystals of methylmalonyl-CoA mutase from Propionibacterium shermanii, a coenzyme B12 (5'-deoxyadenosylcobalamin)-dependent enzyme, have been obtained by the hanging-drop method in two different forms. One form lies in the space group P21, with unit cell dimensions a = 122 A, b = 160 A and c = 90 A, with beta = 104 degrees (1 A = 0.1 nm). There are two alpha beta dimers in the asymmetric unit. The crystals diffract to 3.2 A resolution and are suitable for high resolution X-ray diffraction studies.

Quantitative measurement of the error in the cryptic stereospecificity of methylmalonyl-CoA mutase

1. Samples of methylmalonyl-CoA and (2H3)methylmalonyl-CoA were prepared by a combination of chemical and enzymic methods. After ion-exchange chromatography the unlabelled methylmalonyl-CoA was pure, the deuterated substance contained 11-12% dephospho-CoA derivative. 2. The sample of unlabelled methylmalonyl-CoA was incubated in deuterated buffer with catalytic amounts of methylmalonyl-CoA mutase, epimerase, and coenzyme B12. The progress of the reaction was monitored directly by 1H-NMR spectroscopy at 500 MHz. After equilibrium was established, a slow mutase-catalysed deuterium incorporation into migratable positions of succinyl-CoA was observed. 3. The sample of (2H3)methylmalonyl-CoA was incubated in unlabelled buffer with a mixture of methylmalonyl-CoA mutase, epimerase and coenzyme B12. In withdrawn aliquots, the reaction was interrupted by acidification and the lyophilised samples were examined by 1H-NMR spectroscopy in deuterium oxide. Both rearrangement and protium incorporation into migratable positions of succinyl-CoA were monitored. 4. At comparable methylmalonyl-CoA to succinyl-CoA conversion rates, deuterium loss from migratable positions was 4-6 times faster than the corresponding protium loss. It is confirmed that the stereochemical error of the mutase is amplified by isotope discrimination when deuterium is in migratable positions, whereas it is diminished when protium is in migratable positions.