Heterogeneity in cblG: differential retention of cobalamin on methionine synthase.

Cultured fibroblasts from patients with functional methionine synthase deficiency have been shown to belong to two complementation classes, cblE and cblG. Both are associated with decreased intracellular levels of methylcobalamin (MeCbl) and decreased incorporation of label from 5-methyltetrahydrofolate into macromolecules. Methionine synthase specific activity is normal or near normal in cell extracts from cblE patients under standard reducing conditions, whereas specific activity is low in cblG extracts. Seven of 10 cblG cell lines accumulated [57Co]CN-Cbl equivalent to control cells and showed similar proportions of label associated with the two intracellular cobalamin binders, methionine synthase and methylmalonyl-CoA mutase. The remaining three cblG lines showed reduced accumulation of labeled Cbl and virtually none associated with methionine synthase. The specific activity of methionine synthase was decreased in cell extracts from both cblG subgroups, being almost undetectable in extracts from the latter three lines. Incorporation of label from [14C]MeTHF into either macromolecules or into methionine was decreased in both cblG groups, but was paradoxically higher in the three lines with very low in vitro methionine synthase activity. These results demonstrate further heterogeneity within cblG and suggest that the defect in the three variant lines affects the ability of methionine synthase to retain Cbl.     

Human ATP:Cob(I)alamin adenosyltransferase and its interaction with methionine synthase reductase

The final step in the conversion of vitamin B(12) into coenzyme B(12) (adenosylcobalamin, AdoCbl) is catalyzed by ATP:cob(I)alamin adenosyltransferase (ATR). Prior studies identified the human ATR and showed that defects in its encoding gene underlie cblB methylmalonic aciduria. Here two common polymorphic variants of the ATR that are found in normal individuals are expressed in Escherichia coli, purified, and partially characterized. The specific activities of ATR variants 239K and 239M were 220 and 190 nmol min(-1) mg(-1), and their K(m) values were 6.3 and 6.9 mum for ATP and 1.2 and 1.6 mum for cob(I)alamin, respectively. These values are similar to those obtained for previously studied bacterial ATRs indicating that both human variants have sufficient activity to mediate AdoCbl synthesis in vivo. Investigations also showed that purified recombinant human methionine synthase reductase (MSR) in combination with purified ATR can convert cob(II)alamin to AdoCbl in vitro. In this system, MSR reduced cob(II)alamin to cob(I)alamin that was adenosylated to AdoCbl by ATR. The optimal stoichiometry for this reaction was approximately 4 MSR/ATR and results indicated that MSR and ATR physically interacted in such a way that the highly reactive reaction intermediate [cob(I)alamin] was sequestered. The finding that MSR reduced cob(II)alamin to cob(I)alamin for AdoCbl synthesis (in conjunction with the prior finding that MSR reduced cob(II)alamin for the activation of methionine synthase) indicates a dual physiological role for MSR.     

Protein interactions in the human methionine synthase-methionine synthase reductase complex and implications for the mechanism of enzyme reactivation

Methionine synthase (MS) is a cobalamin-dependent enzyme. It transfers a methyl group from methyltetrahydrofolate to homocysteine forming methionine and tetrahydrofolate. On the basis of sequence similarity with Escherichia coli cobalamin-dependent MS (MetH), human MS comprises four discrete functional modules that bind from the N- to C-terminus, respectively, homocysteine, methyltetrahydrofolate, cobalamin, and S-adenosylmethionine (AdoMet). The C-terminal activation domain also interacts with methionine synthase reductase (MSR), a NADPH-dependent diflavin oxidoreductase required for the reductive regeneration of catalytically inert cob(II)alamin (which is formed every 200-1000 catalytic cycles of MS) to cob(I)alamin. We have investigated complex formation between the (i) MS activation domain and MSR and (ii) MS activation domain and the isolated FMN-binding domain of MSR. We show that the MS activation domain interacts directly with the FMN-binding domain of MSR. Binding is weakened at high ionic strength, emphasizing the importance of electrostatic interactions at the protein-protein interface. Mutagenesis of conserved lysine residues (Lys1071 and Lys987) in the human activation domain weakens this protein interaction. Chemical cross-linking demonstrates complex formation mediated by acidic residues (FMN-binding domain) and basic residues (activation domain). The activation domain and isolated FMN-domain form a 1:1 complex, but a 1:2 complex is formed with activation domain and MSR. The midpoint reduction potentials of the FAD and FMN cofactors of MSR are not perturbed significantly on forming this complex, implying that electron transfer to cob(II)alamin is endergonic. The kinetics of electron transfer in MSR and the MSR-activation domain complex are similar. Our studies indicate (i) conserved binding determinants, but differences in protein stoichiometry, between human MS and bacterial MetH in complex formation with redox partners; (ii) a substantial endergonic barrier to electron transfer in the reactivation complex; and (iii) a lack of control on the thermodynamics and kinetics of electron transfer in MSR exerted by complex formation with activation domain. The structural and functional consequences of complex formation are discussed in light of the known crystal structure of human activation domain and the inferred conformational heterogeneity of the multidomain MSR-MS complex.     

The metabolism of cobalamin bound to transcobalamin II and to glycoproteins that bind Cbl in HepG2 cells (human hepatoma)

The binding, internalization, processing and release of labeled cyanocobalamin (CN[57Co]Cbl) bound to human transcobalamin II (TC II) were studied in HepG2 cells, a line of hepatocytes derived from a human hepatoma. The cells bound the TC II-Cbl by specific, high affinity receptors. Within the cell, the CN-Cbl was promptly freed from TC II and the CN-Cbl converted to more active forms including adenosyl Cbl (AdoCbl) and methyl Cbl (MeCbl). Whereas free labeled Cbl was still present at 72 hours after entry, the cells also bound Cbl to an intracellular binder (ICB) presumed to represent the holo enzymes dependent on Cbl. At levels of TC II that saturated the receptors for TC II-Cbl, much of the Cbl entering the cells remained free and was converted to AdoCbl. Under these circumstances the cells released free Cbl, mostly AdoCbl. Human R type binders of Cbl, which are glycoproteins and some having a terminal galactose, were bound by the HepG2 cells. The binding was characteristic of the receptor system responsive to a terminal galactose, or asialoglycoproteins, but was inconsistent and of low affinity. Cbl bound to R binder was internalized and converted to coenzyme forms of Cbl, but the process was much less effective than when the Cbl entered via the TC II receptor system. It was concluded that the receptors for R-Cbl were unlikely to contribute to the physiologic transport of Cbl in man, but may function in some yet unknown way.     

Participation of cob(I) alamin in the reaction catalyzed by methionine synthase from Escherichia coli: a steady-state and rapid reaction kinetic analysis

The kinetic mechanism of the reaction catalyzed by cobalamin-dependent methionine synthase from Escherichia coli K12 has been investigated by both steady-state and pre-steady-state kinetic analyses. The reaction catalyzed by methionine synthase involves the transfer of a methyl group from methyltetrahydrofolate to homocysteine to generate tetrahydrofolate and methionine. The postulated reaction mechanism invokes an initial transfer of the methyl group to the enzyme to generate enzyme-bound methylcobalamin and tetrahydrofolate. Enzyme-bound methylcobalamin then donates its methyl group to homocysteine to generate methionine and cob(I)alamin. The key questions that were addressed in this study were the following: (1) Does the reaction involve a sequential or ping-pong mechanism? (2) Is enzyme-bound cob(I)alamin a kinetically competent intermediate? (3) If the reaction does involve a sequential mechanism, what is the nature of the "free" enzyme to which the substrates bind; i.e., is the prosthetic group in the cob(I)alamin or methylcobalamin state? Both the steady-state and rapid reaction studies were conducted at 25 degrees C under anaerobic conditions. Initial velocity analysis under steady-state conditions revealed a family of parallel lines suggesting either a ping-pong mechanism or an ordered sequential mechanism. Steady-state product inhibition studies provided evidence for an ordered sequential mechanism in which the first substrate to bind is methyltetrahydrofolate and the last product to be released is tetrahydrofolate. Pre-steady-state kinetic studies were then conducted to determine the rate constants for the various reactions. Enzyme-bound cob(I)alamin was shown to react very rapidly with methyltetrahydrofolate (with an observed rate constant of 250 s-1 versus a turnover number under maximal velocity conditions of 19 s-1).(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of flavodoxin with cobalamin-dependent methionine synthase

Cobalamin-dependent methionine synthase catalyzes the transfer of a methyl group from methyltetrahydrofolate to homocysteine, forming tetrahydrofolate and methionine. The Escherichia coli enzyme, like its mammalian homologue, is occasionally inactivated by oxidation of the cofactor to cob(II)alamin. To return to the catalytic cycle, the cob(II)alamin forms of both the bacterial and mammalian enzymes must be reductively remethylated. Reduced flavodoxin donates an electron for this reaction in E. coli, and S-adenosylmethionine serves as the methyl donor. In humans, the electron is thought to be provided by methionine synthase reductase, a protein containing a domain with a significant degree of homology to flavodoxin. Because of this homology, studies of the interactions between E. coli flavodoxin and methionine synthase provide a model for the mammalian system. To characterize the binding interface between E. coli flavodoxin and methionine synthase, we have employed site-directed mutagenesis and chemical cross-linking using carbodiimide and N-hydroxysuccinimide. Glutamate 61 of flavodoxin is identified as a cross-linked residue, and lysine 959 of the C-terminal activation domain of methionine synthase is assigned as its partner. The mutation of lysine 959 to threonine results in a diminished level of cross-linking, but has only a small effect on the affinity of methionine synthase for flavodoxin. Identification of these cross-linked residues provides evidence in support of a docking model that will be useful in predicting the effects of mutations observed in mammalian homologues of E. coli flavodoxin and methionine synthase.     

The role of transcobalamin II in the methionine dependency of human lymphocytes

Neither normal human B lymphoblasts (RPMI 6410) transformed by the EB virus nor human peripheral blood lymphocytes (PBL) stimulated by a mitogen replicated well when the methionine (Met) of the medium was replaced with homocysteine (Hcy). Cbl bound to human transcobalamin II (TC II) substantially increased cell division over that observed when the Cbl of the medium was in the free form. Although, as expected, the TC II enhanced the cell entry of Cbl 1000-fold, this was not the basis of the TC II effect. Through adjustment of the respective concentrations of free Cbl and TC II-Cbl in the medium, equal amounts of Cbl entered the cell, yet the TC II effect persisted. TC II-Cbl did not restore cell division in the absence of Met by virus-transformed lymphoblasts from a child with defective Met synthesis from Hcy. The TC II did not act by enhanced induction of the Cbl-dependent methionine synthase activity of cell extracts but the ability of intact cells to produce Met from Hcy by the Cbl-dependent process appeared to have a role in the TC II effect.     

Mutual inhibition of cobalamin and siderophore uptake systems suggests their competition for TonB function.

Vitamin B12 (CN-Cbl) and iron-siderophore complexes are transported into Escherichia coli in two energy-dependent steps. The first step is mediated by substrate-specific outer membrane transport proteins and the energy-coupling TonB protein complex, and the second step uses separate periplasmic permeases for transport across the cytoplasmic membrane. Genetic and biochemical evidence suggests that the TonB-dependent outer membrane transporters contact TonB directly, and thus they might compete for limiting amounts of functional TonB. The transport of iron-siderophore complexes, such as ferrichrome, causes a partial decrease in the rate of CN-Cbl transport. Although CN-Cbl uptake does not inhibit ferrichrome uptake in wild-type cells, in which the amount of the outer membrane ferrichrome transporter FhuA far exceeds that of the cobalamin transporter BtuB, CN-Cbl does inhibit ferrichrome uptake when BtuB is overexpressed from a multicopy plasmid. This inhibition by CN-Cbl is increased when the expression of FhuA and TonB is repressed by growth with excess iron and is eliminated when BtuB synthesis is repressed by CN-Cbl. The mutual inhibition of CN-Cbl and ferrichrome uptake is overcome by increased expression of TonB. Additional evidence for interaction of the Cbl and iron transport systems is provided by the strong stimulation of the BtuB- and TonB-dependent transport of CN-Cbl into a nonexchangeable, presumably cytoplasmic pool by preincubation of cells with the iron(II) chelator 2,2'-dipyridyl. Other metal ion chelators inhibited CN-Cbl uptake across the outer membrane. Although the effects of chelators are multiple and complex, they indicate competition or interaction among TonB-dependent transport systems.     

Human methionine synthase reductase, a soluble P-450 reductase-like dual flavoprotein, is sufficient for NADPH-dependent methionine synthase activation

Methionine synthase is a key enzyme in the methionine cycle that catalyzes the transmethylation of homocysteine to methionine in a cobalamin-dependent reaction that utilizes methyltetrahydrofolate as a methyl group donor. Cob(I)alamin, a supernucleophilic form of the cofactor, is an intermediate in this reaction, and its reactivity renders the enzyme susceptible to oxidative inactivation. In bacteria, an NADPH-dependent two-protein system comprising flavodoxin reductase and flavodoxin, transfers electrons during reactivation of methionine synthase. Until recently, the physiological reducing system in mammals was unknown. Identification of mutations in the gene encoding a putative methionine synthase reductase in the cblE class of patients with an isolated functional deficiency of methionine synthase suggested a role for this protein in activation (Leclerc, D., Wilson, A., Dumas, R., Gafuik, C., Song, D., Watkins, D., Heng, H. H. Q., Rommens, J. M., Scherer, S. W., Rosenblatt, D. S., and Gravel, R. A. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 3059-3064). In this study, we have cloned and expressed the cDNA encoding human methionine synthase reductase and demonstrate that it is sufficient for supporting NADPH-dependent activity of methionine synthase at a level that is comparable with that seen in the in vitro assay that utilizes artificial reductants. Methionine synthase reductase is a soluble, monomeric protein with a molecular mass of 78 kDa. It is a member of the family of dual flavoproteins and is isolated with an equimolar concentration of FAD and FMN. Reduction by NADPH results in the formation of an air stable semiquinone similar to that observed with cytochrome P-450 reductase. Methionine synthase reductase reduces cytochrome c in an NADPH-dependent reaction at a rate (0.44 micromol min(-1) mg(-1) at 25 degrees C) that is comparable with that reported for NR1, a soluble dual flavoprotein of unknown function, but is approximately 100-fold slower than that of P-450 reductase. The K(m) for NADPH is 2.6 +/- 0.5 microm, and the K(act) for methionine synthase reductase is 80.7 +/- 13.7 nm for NADPH-dependent activity of methionine synthase.     

Cobalamin metabolism in cultured human chorionic villus cells

Cobalamin (Cbl, vitamin B₁₂) metabolism was analyzed in cultures of human chorionic villus (CV) cells obtained at 9–10 weeks of gestation. CV cells were shown to synthesize transcobalamin II (TCII) and to possess a high affinity receptor for that molecule. The cells bound and internalized radioactive cyanocobalamin (CN[⁵⁷Co]Cbl) complexed to TCII. This internalized CN[⁵⁷Co]Cbl was found to be converted to both methylCbl and adenosylCbl, the two intracellular coenzyme forms of Cbl, and bound to the two known intracellular Cbl requiring enzymes, methionine synthase (MS) and methylmalonyl-CoA mutase. Both enzyme systems were found to be functional in the intact cell by demonstrating the incorporation of the radioactive label from both [¹⁴C]CH₃-tetrahydrofolate and [¹⁴C]propionate into acid insoluble products. MS activity was also detected in lysed cell material. CV cells were shown not to be auxotrophic for methionine since they were able to utilize homocysteine in place of methionine for cell division. Since CV cells are capable of performing many of the complex events associated with Cbl metabolism, it may be possible to use these cells to diagnose genetic defects of Cbl metabolism. © 1993 Wiley-Liss, Inc.     

The Escherichia coli outer membrane cobalamin transporter BtuB: structural analysis of calcium and substrate binding, and identification of orthologous transporters by sequence/structure conservation

Gram-negative bacteria possess specialized active transport systems that function to transport organometallic cofactors or carriers, such as cobalamins, siderophores, and porphyrins, across their outer membranes. The primary components of each transport system are an outer membrane transporter and the energy-coupling protein TonB. In Escherichiacoli, the TonB-dependent outer membrane transporter BtuB carries out active transport of cobalamin (Cbl) substrates across its outer membrane. Cobalamins bind to BtuB with nanomolar affinity. Previous studies implicated calcium in high-affinity binding of cyanocobalamin (CN-Cbl) to BtuB. We previously solved four structures of BtuB or BtuB complexes: an apo-structure of a methionine-substitution mutant (used to obtain experimental phases by selenomethionine single-wavelength anomalous diffraction studies); an apo-structure of wild-type BtuB; a binary complex of calcium and wild-type BtuB; and a ternary complex of calcium, CN-Cbl and wild-type BtuB. We present an analysis of the binding of calcium in the binary and ternary complexes, and show that calcium coordination changes upon substrate binding. High-affinity CN-Cbl binding and calcium coordination are coupled. We also analyze the binding mode of CN-Cbl to BtuB, and compare and contrast this binding to that observed in other proteins that bind Cbl. BtuB binds CN-Cbl in a manner very different from Cbl-utilizing enzymes and the periplasmic Cbl binding protein BtuF. Homology searches of bacterial genomes, structural annotation based on the presence of conserved Cbl-binding residues identified by analysis of our BtuB structure, and detection of homologs of the periplasmic Cbl-binding binding protein BtuF enable identification of putative BtuB orthologs in enteric and non-enteric bacterial species.     

Reaction of alkylcobalamins with thiols

Carbon-13 NMR spectroscopy and phosphorus-31 NMR spectroscopy have been used to study the reaction of several alkylcobalamins with 2-mercaptoethanol. At alkaline pH, when the thiol is deprotonated, the alkyl-transfer reactions involve a nucleophilic attack of the thiolate anion on the Co-methylene carbon of the cobalamins, yielding alkyl thioethers and cob(II)alamin. In these nucleophilic displacement reactions cob(I)alamin is presumably formed as an intermediate. The higher alkylcobalamins react more slowly than methylcobalamin. The lower reactivity of ethyl- and propylcobalamin is probably the basis of the inhibition of the corrinoid-dependent methyl-transfer systems by propyl iodide. The transfer of the upper nucleoside ligand of adenosylcobalamin to 2-mercaptoethanol is a very slow process; S-adenosyl-mercaptoethanol and cob(II)alamin are the final products of the reaction. The dealkylation of (carboxymethyl)cobalamin is a much more facile reaction. At alkaline pH S-(carboxymethyl)mercaptoethanol and cob(II)alamin are produced, while at pH values below 8 the carbon-cobalt bond is cleaved reductively to acetate and cob(II)alamin. The reductive cleavage of the carbon-cobalt bond of (carboxymethyl)cobalamin by 2-mercaptoethanol is extremely fast when the cobalamin is in the "base-off" form. Because we have been unable to detect trans coordination of 2-mercaptoethanol, we favor a mechanism that involves a hydride attack on the Co-methylene carbon of (carboxymethyl)cobalamin rather than a trans attack of the thiol on the cobalt atom.     

Mechanism of reductive activation of cobalamin-dependent methionine synthase: an electron paramagnetic resonance spectroelectrochemical study

The mechanism of reductive methylation of cobalamin-dependent methionine synthase (5-methyltetrahydrofolate:homocysteine methyltransferase, EC 2.1.1.13) has been investigated by electron paramagnetic resonance (EPR) spectroelectrochemistry. The enzyme as isolated is inactive, and its UV/visible absorbance and EPR spectra are characteristic of cob(II)alamin. There is an absolute requirement for catalytic amounts of AdoMet and a reducing system for the formation and maintenance of active enzyme during in vitro turnover. The midpoint potentials of the enzyme-bound cob(II)alamin/cob(I)alamin and cob(III)alamin/cob(II)alamin couples have been determined to be -526 +/- 5 and +273 +/- 4 mV (versus the standard hydrogen electrode), respectively. The presence of either CH3-H4folate or AdoMet shifts the equilibrium distribution of cobalamin species observed during reduction by converting cob(I)alamin to methylcobalamin. The magnitude of these shifts is however vastly different, with AdoMet lowering the concentration of cob(II)alamin at equilibrium by a factor of at least 3 X 10(7), while CH3-H4folate lowers it by a factor of 19. These studies of coupled reduction/methylation reactions elucidate the absolute requirement for AdoMet in the in vitro assay system, in which the ambient potential is approximately -350 mV versus the standard hydrogen electrode. At this potential, the equilibrium distribution of cobalamin in the presence of CH3-H4folate would be greatly in favor of the cob(II)alamin species, whereas in the presence of AdoMet the equilibrium favors methylated enzyme. In these studies, a base-on form of cob(II)alamin in which the dimethylbenzimidazole substituent of the corrin ring is the lower axial ligand for the cobalt has been observed for the first time on methionine synthase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxidation of 5-methyltetrahydrofolate in cobalamin-inactivated rats.

Rats were exposed to nitrous oxide, which inactivates cob(I)alamin (Cbl). As in air-breathing rats methionine administration led to the conversion of hepatic 5-methyltetrahydrofolate (MeH4 folate) into formyltetrahydrofolate. The recovery of MeH4 folate levels in liver after its oxidation initiated by methionine was noted and the rate compared with that for air-breathing rats. Oxidation of MeH4 folate was less complete and occurred more slowly in Cbl-inactivated rats as compared with controls. However, recovery of MeH4 folate levels was more rapid in Cbl inactivation. S-Adenosylmethionine did not produce a significant change in MeH4 folate levels in Cbl-inactivated rats, whereas it did so in air-breathing animals.     

Electron transfer in the substrate-dependent suicide inactivation of lysine 5,6-aminomutase

The lysine 5,6-aminomutase (5,6-LAM) purified from Clostridium sticklandii was found to undergo rapid inactivation in the absence of the activating enzyme E(2) and ATP. In the presence of substrate, inactivation was also seen for the recombinant 5,6-LAM. This adenosylcobalamin-dependent enzyme is postulated to generate cob(II)alamin and the 5'-deoxyadenosyl radical through enzyme-induced homolytic scission of the Co-C bond. However, the products cob(III)alamin and 5'-deoxyadenosine were observed upon inactivation of 5,6-LAM. Cob(III)alamin production, as monitored by the increase in A(358), proceeds at the same rate as the loss of enzyme activity, suggesting that the activity loss is related to the adventitious generation of cob(III)alamin during enzymatic turnover. The cleavage of adenosylcobalamin to cob(III)alamin is accompanied by the formation of 5'-deoxyadenosine at the same rate, and the generation of cob(III)alamin proceeds at the same rate both aerobically and anaerobically. Suicide inactivation requires the presence of substrate, adenosylcobalamin, and PLP. We have ruled out the involvement of either the putative 5'-deoxyadenosyl radical or dioxygen in suicide inactivation. We have shown that one or more reaction intermediates derived from the substrate or/and the product, presumably a radical, participate in suicide inactivation of 5,6-LAM through electron transfer from cob(II)alamin. Moreover, L-lysine is found to be a slowly reacting substrate, and it induces inactivation at a rate similar to that of D-lysine. The alternative substrate beta-lysine induces inactivation at least 25 times faster than DL-lysine. The inactivation mechanism is compatible with the radical isomerization mechanism proposed to explain the action of 5,6-LAM.     

Glutathione-dependent One-electron Transfer Reactions Catalyzed by a B12 Trafficking Protein

CblC is involved in an early step in cytoplasmic cobalamin processing following entry of the cofactor into the cytoplasm. CblC converts the cobalamin cargo arriving from the lysosome to a common cob(II)alamin intermediate, which can be subsequently converted to the biologically active forms. Human CblC exhibits glutathione (GSH)-dependent alkyltransferase activity and flavin-dependent reductive decyanation activity with cyanocobalamin (CNCbl). In this study, we discovered two new GSH-dependent activities associated with the Caenorhabditis elegans CblC for generating cob(II)alamin: decyanation of CNCbl and reduction of aquocobalamin (OH₂Cbl). We subsequently found that human CblC also catalyzes GSH-dependent decyanation of CNCbl and reduction of OH₂Cbl, albeit efficiently only under anaerobic conditions. The air sensitivity of the human enzyme suggests interception by oxygen during the single-electron transfer step from GSH to CNCbl. These newly discovered GSH-dependent single-electron transfer reactions expand the repertoire of catalytic activities supported by CblC, a versatile B₁₂-processing enzyme.     

Cobalamin-dependent methionine synthase: probing the role of the axial base in catalysis of methyl transfer between methyltetrahydrofolate and exogenous cob(I)alamin or cob(I)inamide

Cobalamin-dependent methionine synthase (MetH) catalyzes the transfer of methyl groups between methyltetrahydrofolate (CH(3)-H(4)folate) and homocysteine, with the enzyme-bound cobalamin serving as an intermediary in the methyl transfers. An MetH fragment comprising residues 2-649 contains modules that bind and activate CH(3)-H(4)folate and homocysteine and catalyze methyl transfers to and from exogenous cobalamin. Comparison of the rates of reaction of cobalamin, which contains a dimethylbenzimidazole nucleotide coordinated to the cobalt in the lower axial position, and cobinamide, which lacks the dimethylbenzimidazole nucleotide, allows assessment of the degree of stabilization the dimethylbenzimidazole base provides for methyl transfer between CH(3)-H(4)folate bound to MetH(2-649) and exogenous cob(I)alamin. When the reactions of cob(I)alamin or cob(I)inamide with CH(3)-H(4)folate are compared, the observed second-order rate constants are 2.7-fold faster for cob(I)alamin; in the reverse direction, methylcobinamide reacts 35-fold faster than methylcobalamin with enzyme-bound tetrahydrofolate. These measurements can be used to estimate the influence of the dimethylbenzimidazole ligand on both the thermodynamics and kinetics of methyl transfer between methyltetrahydrofolate and cob(I)alamin or cob(I)inamide. The free energy change for methyl transfer from CH(3)-H(4)folate to cob(I)alamin is 2.8 kcal more favorable than that for methyl transfer to cob(I)inamide. Dimethylbenzimidazole contributes approximately 0.6 kcal/mol of stabilization for the forward reaction and approximately 2.2 kcal/mol of destabilization for the reverse reaction. Binding of methylcobalamin to full-length methionine synthase is accompanied by ligand substitution, and switching between "base-on" and "base-off" states of the cofactor has been demonstrated [Bandarian, V., et al. (2003) Proc. Natl. Acad. Sci. U.S.A. 100, 8156-8163]. The present results disfavor a major role for such switching in catalysis of methyl transfer, and are consistent with the hypothesis that the primary role of the ligand triad in methionine synthase is controlling the distribution of enzyme conformations during catalysis.     

Ligand trans influence governs conformation in cobalamin-dependent methionine synthase

Cobalamin-dependent methionine synthase (MetH) of Escherichia coli is a large, modular enzyme that uses a cobalamin prosthetic group as a donor or acceptor in three separate methyl transfer reactions. The prosthetic group alternates between methylcobalamin and cob(I)alamin during catalysis as homocysteine is converted to methionine using a methyl group derived from methyltetrahydrofolate. Occasional oxidation of cob(I)alamin to cob(II)alamin inactivates the enzyme. Reductive methylation with flavodoxin and adenosylmethionine returns the enzyme to an active methylcobalamin state. At different points during the reaction cycle, the coordination state of the cobalt of the cobalamin changes. The imidazole side chain of His759 coordinates to cobalamin in a "His-on" state and dissociates to produce a "His-off" state. The His-off state has been associated with a conformation of MetH that is poised for reactivation of cobalamin by reductive methylation rather than catalysis. Our studies on cob(III)alamins bound to MetH, specifically aqua-, methyl-, and n-propylcobalamin, show a correlation between the accessibility of the reactivation conformation and the order of the established ligand trans influence. The trans influence also controls the affinity of MetH in the cob(III)alamin form for flavodoxin. Flavodoxin, which acts to shift the conformational equilibrium toward the reactivation conformation, binds less tightly to MetH when the cob(III)alamin has a strong trans ligand and therefore has less positive charge on cobalt. These results are compared to those for cob(II)alamin MetH, illustrating that access to the reactivation conformation is governed by the net charge on the cobalt as well as the trans influence in cob(III)alamins.     

In vitro inactivation of methionine synthase by nitrous oxide

Nitrous oxide (N2O) is commonly used as an anesthetic agent. Prolonged exposure to N2O leads to megaloblastic anemia in humans and to loss of methionine synthase activity in vertebrates. We now report that purified preparations of cobalamin-dependent methionine synthase (5-methyltetrahydrofolate-homocysteine methyltransferase, EC 2.1.1.13) from both Escherichia coli and pig liver are irreversibly inactivated during turnover in buffers saturated with N2O. Inactivation by N2O occurs only in the presence of all components required for turnover: homocysteine, methyltetrahydrofolate, adenosylmethionine, and a reducing system. Reisolation of the inactivated E. coli enzyme after turnover in the presence of N2O resulted in significant losses of bound cobalamin and of protein as compared to controls where the enzyme was subjected to turnover in N2-equilibrated buffers before reisolation. However, N2O inactivation was not associated with major changes in the visible absorbance spectrum of the remaining enzyme-bound cobalamin. We postulate that N2O acts by one-electron oxidation of the cob(I)alamin form of the enzyme which is generated transiently during turnover with the formation of cob(II)alamin, N2, and hydroxyl radical. Generation of hydroxyl radical at the active site of the enzyme could explain the observed irreversible loss of enzyme activity.