Proton Transfer from Histidine 244 May Facilitate the 1,2 Rearrangement Reaction in Coenzyme B12-dependent Methylmalonyl-CoA Mutase

Maiti, Nilesh; Widjaja, Lusiana; Banerjee, Ruma

doi:10.1074/jbc.274.46.32733

Cited by 38 publications

(59 citation statements)

References 32 publications

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“…The steady formation of OH 2 Cbl during IcmF turnover under aerobic conditions suggests that inactivation might result from oxidative interception of cob(II)alamin (27). An alternative possibility is that inactivation is associated with loss of 5Ј-de- oxyadenosine from the active site, and the uncoupled cob(II)alamin is subsequently oxidized to OH 2 Cbl.…”

Section: Loss Of 5ј-deoxyadenosine Leads To Inactivation Of Icmf-mentioning

confidence: 95%

Novel Coenzyme B12-dependent Interconversion of Isovaleryl-CoA and Pivalyl-CoA

Cracan

Banerjee

2012

Journal of Biological Chemistry

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Section: Loss Of 5ј-deoxyadenosine Leads To Inactivation Of Icmf-mentioning

confidence: 95%

Novel Coenzyme B12-dependent Interconversion of Isovaleryl-CoA and Pivalyl-CoA

Cracan

Banerjee

2012

Journal of Biological Chemistry

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“…Previous workers studying the Propionibacterium shermanii enzyme have shown that at ambient oxygen concentrations (ϳ200 M), oxygen reacts with the Cbl(II) generated during the enzymatic reaction, albeit at a slow rate (40). Other workers found no inhibition of the P. shermanii enzyme under ambient conditions, but enzyme activity was measured over only a 3-min interval (41). We found that at 200 M, oxygen had a small but statistically non-significant effect on the activity of mammalian methylmalonyl-CoA mutase during a 10-min incubation, but at 600 M oxygen significantly inhibited enzyme activity (Fig.…”

Section: Effect Of Oxygen On Methylmalonyl-coa Mutase Activity In Vitromentioning

confidence: 95%

“…However, this may not apply to non-polar diatomic molecules like oxygen or NO, as oxygen has been shown to react with Cbl(II) generated by the P. shermanii enzyme, albeit at a slow rate (40). Mutation of the P. shermanii mutase at histidine 244 markedly increases the sensitivity of the enzyme to oxygen, indicating that this residue is critical for protecting the Cbl(II) and deoxyadenosyl radical intermediates (40,41). Modeling the possible structure of the homodimeric human enzyme against the known structure of the heterodimeric P. shermanii enzyme using the Swiss Model program suggests that the active sites of the two enzymes are similar, but such modeling can overlook subtle structural differences that could lead to increased sensitivity to NO and oxygen (52).…”

Section: Effect Of Decreased Availability Of Endogenous No On Methylmmentioning

confidence: 99%

Nitric Oxide Inhibits Mammalian Methylmalonyl-CoA Mutase

Kambo¹,

Sharma

Casteel

et al. 2005

Journal of Biological Chemistry

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Methylmalonyl-CoA mutase is a key enzyme in intermediary metabolism, and children deficient in enzyme activity have severe metabolic acidosis. We found that nitric oxide (NO) inhibits methylmalonyl-CoA mutase activity in rodent cell extracts. The inhibition of enzyme activity occurred within minutes and was not prevented by thiols, suggesting that enzyme inhibition was not occurring via NO reaction with cysteine residues to form nitrosothiol groups. Enzyme inhibition was dependent on the presence of substrate, implying that NO was reacting with cobalamin(II) (Cbl(II)) and/or the deoxyadenosyl radical (⅐CH 2 -Ado), both of which are generated from the co-factor of the enzyme, 5-deoxyadenosyl-cobalamin (AdoCbl), on substrate binding. Consistent with this hypothesis was the finding that high micromolar concentrations (>600 M) of oxygen also inhibited enzyme activity. To study the mechanism of NO reaction with AdoCbl, we simulated the enzymatic reaction by photolyzing AdoCbl, and found that even at low NO concentrations, NO reacted with both the generated Cbl(II) and ⅐CH 2 -Ado indicating that NO could effectively compete with the back formation of AdoCbl. Thus, NO inhibition of methylmalonyl-CoA mutase appeared to be from the reaction of NO with both AdoCbl intermediates (Cbl(II) and ⅐CH 2 -Ado) generated during the enzymatic reaction. The inhibition of methylmalonyl-CoA mutase by NO was likely of physiological relevance because a NO donor inhibited enzyme activity in intact cells, and scavenging NO from cells or inhibiting cellular NO synthesis increased methylmalonyl-CoA mutase activity when measured subsequently in cell extracts.In mammalian cells only two enzymes are known to require cobalamin (vitamin B 12 ) as a cofactor: methionine synthase, which uses methylcobalamin, and methylmalonyl-coenzyme A (CoA) mutase, which uses 5Ј-deoxyadenosyl-cobalamin (AdoCbl).1 During the reaction catalyzed by methionine synthase, methylcobalamin is cleaved heterolytically generating cobalamin I (Cbl(I)) and a methyl carbocation, whereas during the reaction catalyzed by methylmalonyl-CoA mutase, AdoCbl is cleaved homolytically generating cobalamin II (Cbl(II)) and a deoxyadenosyl radical (⅐CH 2 -Ado) (1, 2). The latter serves to abstract a hydrogen atom from the substrate methylmalonylCoA, and after intramolecular migration of a thioester moiety, the hydrogen atom is transferred back to generate the product succinyl-CoA. In the final step of the reaction, the deoxyadenosyl radical recombines with Cbl(II) to regenerate AdoCbl (3). It should be noted that the homolytic cleavage of AdoCbl occurs essentially only on substrate binding to the enzyme (3). Nitric oxide (NO) is produced by a variety of mammalian cell types, and has a diverse array of cellular and physiological functions including regulation of cell growth, differentiation, and apoptosis, and modulation of blood pressure, platelet aggregation, and synaptic plasticity (4 -6). At pharmacological concentrations, NO reacts with several different chemical groups, but at phys...

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“…computational studies on methylmalonyl-CoA mutase have begun to provide insights into these issues (3)(4)(5)(6)(7)(8). They point to the critical role played by individual active site residues in labilizing the Co-carbon bond (7), and in shielding radical intermediates from unwanted side-reactions (4,6,8).…”

mentioning

confidence: 99%

“…They point to the critical role played by individual active site residues in labilizing the Co-carbon bond (7), and in shielding radical intermediates from unwanted side-reactions (4,6,8).…”

mentioning

confidence: 99%

Alternative Pathways for Radical Dissipation in an Active Site Mutant of B₁₂-Dependent Methylmalonyl-CoA Mutase

Padovani

Banerjee

2006

Biochemistry

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Methylmalonyl-CoA mutase catalyzes the adenosylcobalamin-dependent rearrangement of (2R)-methylmalonyl-CoA to succinyl-CoA. The crystal structure of the enzyme reveals that Y243 is in van der Waals contact with the methyl group of the substrate and suggests a possible role for it in the stereochemical control of the reaction. This hypothesis was tested by designing a molecular hole by replacing the phenolic side chain of Y243 with the methyl group of alanine. The Y243A mutation lowered the catalytic efficiency >4 × 10 4 -fold compared to wild type enzyme, the K Mapp for the cofactor ~4-fold, and the cob(II)alamin concentration under steady-state turnover conditions ~2-fold. However, the mutation did not appear to lead to loss of the stereochemical preference for the substrate. The Y243A mutation is expected to create a cavity and should in principle, allow accommodation of bulkier substrates. To test this, we used ethylmalonyl-CoA and allylmalonyl-CoA, as alternate substrates. Surprisingly, both analogs resulted in suicidal inactivation albeit in an O 2 -dependent and O 2 -independent fashion, respectively. The inactivation by allylmalonyl-CoA was further investigated and revealed formation of cob(II)alamin at a ~1.5-fold higher rate than with wild-type mutase under single turnover conditions. Product analysis revealed a stoichiometric mixture of 5′-deoxyadenosine, aquocobalamin and allylmalonyl-CoA. Taken together, these results are consistent with an internal electron transfer from cob(II)alamin to the substrate analog radical. These studies serve to emphasize the fine control exerted by Y243 in the vicinity of the substrate to minimize radical extinction in side reactions.Methylmalonyl-CoA mutase catalyzes the reversible isomerization of methylmalonyl-CoA to succinyl-CoA and is dependent on 5′-deoxyadenosylcobalamin (AdoCbl) 1 or coenzyme B 12 for activity (Figure 1) (1). In this reaction, the AdoCbl cofactor is used as a radical reservoir that generates via homolysis of theCo-carbon bond, a pair of radicals: cob(II)alamin and a reactive 5′-deoxyadenosyl radical (Ado•). The latter abstracts a hydrogen atom from the substrate generating a substrate-centered radical that, in turn, rearranges to a product-centered radical. The remainder of the catalytic cycle is completed by reversal of the sequence of steps in the first half of the reaction (Figure 1).Two questions of long-standing interest regarding AdoCbl-dependent enzymes are how the inherent kinetic inertness of the Co-carbon bond is overcome to effect a trillion-fold acceleration in the homolysis rate (2) and how the high reactivity of radical intermediates are controlled to minimize side reactions.

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Proton Transfer from Histidine 244 May Facilitate the 1,2 Rearrangement Reaction in Coenzyme B12-dependent Methylmalonyl-CoA Mutase

Cited by 38 publications

References 32 publications

Novel Coenzyme B12-dependent Interconversion of Isovaleryl-CoA and Pivalyl-CoA

Novel Coenzyme B12-dependent Interconversion of Isovaleryl-CoA and Pivalyl-CoA

Nitric Oxide Inhibits Mammalian Methylmalonyl-CoA Mutase

Alternative Pathways for Radical Dissipation in an Active Site Mutant of B₁₂-Dependent Methylmalonyl-CoA Mutase

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Proton Transfer from Histidine 244 May Facilitate the 1,2 Rearrangement Reaction in Coenzyme B12-dependent Methylmalonyl-CoA Mutase

Cited by 38 publications

References 32 publications

Novel Coenzyme B12-dependent Interconversion of Isovaleryl-CoA and Pivalyl-CoA

Novel Coenzyme B12-dependent Interconversion of Isovaleryl-CoA and Pivalyl-CoA

Nitric Oxide Inhibits Mammalian Methylmalonyl-CoA Mutase

Alternative Pathways for Radical Dissipation in an Active Site Mutant of B12-Dependent Methylmalonyl-CoA Mutase

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Alternative Pathways for Radical Dissipation in an Active Site Mutant of B₁₂-Dependent Methylmalonyl-CoA Mutase