Kinetic and biochemical analysis of the mechanism of action of lysine 5,6-aminomutase

Lysine 5,6-aminomutase (5,6-LAM) catalyzes the reversible and nearly isoenergetic transformations of D-lysine into 2,5-diaminohexanoate (2,5-DAH) and of L-beta-lysine into 3,5-diaminohexanoate (3,5-DAH). The activity of 5,6-LAM depends on pyridoxal-5(')-phosphate (PLP) and adenosylcobalamin. The currently postulated multistep mechanism involves at least 12 steps, two of which involve hydrogen transfer. The deuterium kinetic isotope effects on k(cat) and k(cat)/K(m) have been found to be 10.4+/-0.3 and 8.3+/-1.9, respectively, in the reaction of DL-lysine-3,3,4,4,5,5,6,6-d(8). The corresponding isotope effects for reaction of DL-lysine-4,4,5,5-d(4) are 8.5+/-0.7 and 7.1+/-1.2, respectively. Neither cob(II)alamin nor a free radical can be detected in the steady state by UV-Vis spectrophotometry or electron paramagnetic resonance (EPR) spectroscopy. Therefore, hydrogen abstraction from carbon-5 of the substrate side chain is rate limiting in the mechanism. DL-4-Oxalysine is an alternative substrate for 5,6-LAM. DL-4-Oxalysine reacts irreversibly because the product breaks down into ammonia, acetaldehyde, and DL-serine. The value of K(m) for the reaction of DL-4-oxalysine is lower than that for DL-lysine and that of k(cat) for DL-4-oxalysine is slightly lower than that for DL-lysine. As measured by values of k(cat)/K(m), 5,6-LAM uses DL-4-oxalysine essentially as efficiently as the best substrates, D-lysine and L-beta-lysine, and more efficiently than DL-lysine. DL-4-Oxalysine induces the same suicide inactivation by electron transfer as do the biological substrates. The putative substrate-related radical intermediate is not sufficiently stabilized by the nonbonding 4-oxa electrons to be detectable by EPR spectroscopy.     

Identification of cis-ethanesemidione as the organic radical derived from glycolaldehyde in the suicide inactivation of dioldehydrase and of ethanolamine ammonia-lyase

The hydrate of glycolaldehyde is a substrate analogue that induces the formation of cob(II)alamin and 5'-deoxyadenosine from adenosylcobalamin at the active site of dioldehydrase, and the resulting complex is inactive. The carbon atoms of glycolaldehyde hydrate remain bound to this complex, and it has been postulated that the first step or steps of the catalytic process on glycolaldehyde hydrate generate an intermediate that undergoes a destructive side reaction leading to inactivation of the enzyme [Wagner, O. W., Lee, H. A., Jr., Frey, P. A., and Abeles, R. H. (1966) J. Biol. Chem. 249, 1751-1762]. All evidence suggests that dioldehydrase reaction proceeds by a radical mechanism, and the glycolaldehyde hydrate is expected to be converted initially into a radical. Electron paramagnetic resonance (EPR) spectroscopic analysis of the inactivated complex shows that glycolaldehyde is transformed into a cis-ethanesemidione radical that is weakly spin-coupled to the cob(II)alamin in the active site of the enzyme. This radical has been identified by analysis of EPR spectra obtained from samples with (13)C- and (2)H-labeled forms of glycolaldehyde. The analysis shows that the stable radical associated with the inactive complex is symmetrical and that it contains a single solvent-exchangeable proton, consistent with a cis-ethanesemidione. Glycolaldehyde also inactivates ethanolamine ammonia-lyase (EAL). EPR studies of ethanolamine ammonia-lyase reveal that treatment with glycolaldehyde also results in formation of an ethanesemidione radical bound in the active site. The suicide inactivation in both enzymatic reactions is postulated to result from formation of this stable radical, which cannot react further to abstract a hydrogen atom from 5'-deoxyadenosine. Analysis of the electron spin-spin coupling between the semidione radicals and cob(II)alamin in both enzymes indicates that the distance between the radical and Co(2+) is approximately 11 A in each case.     

Interactions of diol dehydrase and 3',4'-anhydroadenosylcobalamin: suicide inactivation by electron transfer

3',4'-Anhydroadenosylcobalamin (anAdoCbl) is an analogue of the adenosylcobalamin (AdoCbl) coenzyme (Magnusson, O.Th., and Frey, P. A. (2000) J. Am. Chem. Soc. 122, 8807-8813). This compound supports activity for diol dehydrase at 0.02% of that observed with AdoCbl. In a side reaction, however, anAdoCbl induces suicide inactivation by an electron-transfer mechanism. Homolytic cleavage of the Co-C bond of anAdoCbl at the active site of diol dehydrase was observed by spectrophotometric detection of cob(II)alamin. Anaerobic conversion of enzyme bound cob(II)alamin to cob(III)alamin, both in the absence and presence of substrate, indicates that the coenzyme derived 5'-deoxy-3',4'-anhydroadenosine-5'-yl serves as the oxidizing agent. This hypothesis is supported by the stoichiometric formation of 3',5'-dideoxyadenosine-4',5'-ene as the nucleoside cleavage product, as determined by high-performance liquid chromatography, mass spectrometry, and nuclear magnetic resonance spectroscopy. Experiments performed in deuterium oxide show that a single solvent exchangeable proton is incorporated into the product. These data are consistent with the intermediate formation of a transient allylic anion formed after one electron transfer from cob(II)alamin to the allylic 5'-deoxy-3',4'-anhydroadenosyl radical. Selective protonation at C3' was demonstrated by spectroscopic characterization of the purified product. This study provides an example of suicide inactivation of a radical enzyme brought about by a side reaction of an analogue of the radical intermediate.     

When a spectator turns killer: suicidal electron transfer from cobalamin in methylmalonyl-CoA mutase

Methylmalonyl-CoA mutase belongs to the class of adenosylcobalamin (AdoCbl)-dependent carbon skeleton isomerases and catalyzes the rearrangement of methylmalonyl-CoA to succinyl-CoA. In this study, we have evaluated the contribution of the active site residue, R207, in the methylmalonyl-CoA mutase-catalyzed reaction. The R207Q mutation results in a 10(4)-fold decrease in k(cat) and >30-fold increase in the K(M) for the substrate, methylmalonyl-CoA. R207 and the active site residue, Y89, are within hydrogen bonding distance to the carboxylate of the substrate. In the closely related isomerase, isobutyryl-CoA mutase the homologous residues are F80 and Q198, respectively. We therefore characterized the ability of the double mutant (Y89F/R207Q) of methylmalonyl-CoA mutase as well as of the single mutants (Y89F and R207Q) to catalyze the rearrangement of n-butyryl-CoA to isobutyryl-CoA. While none of the mutant enzymes is capable of isomerizing these substrates, the R207Q (single and double) mutants exhibited irreversible inactivation upon incubation with either n-butyryl-CoA or isobutyryl-CoA. The two products observed during inactivation under both aerobic and strictly anaerobic conditions were 5'-deoxyadenosine and hydroxocobalamin, which suggested internal electron transfer from cob(II)alamin to the substrate or the 5'-deoxyadenosyl radical. Deuterium transfer from substrate to deoxyadenosine demonstrated that the substrate radical is formed and is presumably the acceptor in the electron-transfer reaction from cob(II)alamin. These studies provide evidence for the critical role of active site residues in controlling radical reactivity and thereby suppressing inactivating side reactions.     

Dioldehydrase: an essential role for potassium ion in the homolytic cleavage of the cobalt-carbon bond in adenosylcobalamin

The complex of dioldehydrase with adenosylcobalamin (coenzyme B12) and potassium ion reacts with molecular oxygen in the absence of a substrate to oxidize coenzyme and inactivate the complex. In this article, high performance liquid chromatography and mass spectral analysis are used to identify the nucleoside products resulting from oxygen inactivation. The product profile indicates that oxygen inactivation proceeds by direct reaction of molecular oxygen with the 5'-deoxyadenosyl radical and cob(II)alamin. Formation of 5'-peroxyadenosine as the initial nucleoside product chemically correlates this reaction with aerobic, aqueous photoinduced homolytic cleavage of adenosylcobalamin (Schwartz, P. A., and Frey, P. A., (2007) Biochemistry, in press), indicating that both reactions proceed through similar chemical intermediates. The oxygen inactivation of the enzyme-coenzyme complex shows an absolute requirement for the same monocations required in catalysis by dioldehydrase. Measurements of the dissociation constants for adenosylcobalamin from potassium-free (Kd = 16 +/- 2 microM) or potassium-bound dioldehydrase (Kd = 0.8 +/- 0.2 microM) reveal that the effect of the monocation in stimulating oxygen sensitivity cannot be explained by an effect on the binding of coenzyme to the enzyme. Cross-linking experiments suggest that the full quaternary structure is assembled in the absence of potassium ion under the experimental conditions. The results indicate that dioldehydrase likely harvests the binding energy of the activating monocation to stimulate the homolytic cleavage of the Co-C5' bond in adenosylcobalamin.     

Hydrogen atom exchange between 5'-deoxyadenosine and hydroxyethylhydrazine during the single turnover inactivation of ethanolamine ammonia-lyase.

The early steps in the single turnover inactivation of ethanolamine ammonia-lyase (EAL) from Salmonella typhimurium by hydroxyethylhydrazine (HEH) have been probed by rapid-mixing sampling techniques, and the destiny of deuterium atoms, present initially in HEH, has been investigated by mass spectrometry. The inactivation reaction produces acetaldehyde, the hydrazine cation radical, 5'-deoxyadenosine, and cob(II)alamin (B(12r)) in amounts stoichiometric with active sites. Rapid-mix freeze-quench EPR spectroscopy and stopped-flow rapid-scan spectrophotometry revealed that the hydrazine cation radical and B(12r) appeared at a rate of approximately 3 s(-)(1) at 21 degrees C. Analysis of 5'-deoxyadenosine isolated from a reaction mixture prepared in (2)H(2)O did not contain deuterium-a result which demonstrates that solvent-exchangeable sites are not involved in the hydrogen-transfer processes. In contrast, all of the 5'-deoxyadenosine, isolated from inactivation reactions with [1,1,2,2-(2)H(4)]HEH, had acquired at least one (2)H from the labeled inactivator. Significant fractions of the 5'-deoxyadenosine acquired two and three deuteriums. These results indicate that hydrogen abstraction from HEH by a radical derived from the cofactor is reversible. The distribution of 5'-deoxyadenosine with one, two, and three deuteriums incorporated and the absence of unlabeled 5'-deoxyadenosine in the product are consistent with a model in which there is direct transfer of hydrogens between the inactivator and the 5'-methyl of 5'-deoxyadenosine. These results reinforce the concept that the 5'-deoxyadenosyl radical is the species that abstracts hydrogen atoms from the substrate in EAL.     

Mechanism-based inactivation of coenzyme B12-dependent diol dehydratase by 3-unsaturated 1,2-diols and thioglycerol

The reactions of diol dehydratase with 3-unsaturated 1,2-diols and thioglycerol were investigated. Holodiol dehydratase underwent rapid and irreversible inactivation by either 3-butene-1,2-diol, 3-butyne-1,2-diol or thioglycerol without catalytic turnovers. In the inactivation, the Co-C bond of adenosylcobalamin underwent irreversible cleavage forming unidentified radicals and cob(II)alamin that resisted oxidation even in the presence of oxygen. Two moles of 5'-deoxyadenosine per mol of enzyme was formed as an inactivation product from the coenzyme adenosyl group. Inactivated holoenzymes underwent reactivation by diol dehydratase-reactivating factor in the presence of ATP, Mg(2+) and adenosylcobalamin. It was thus concluded that these substrate analogues served as mechanism-based inactivators or pseudosubstrates, and that the coenzyme was damaged in the inactivation, whereas apoenzyme was not damaged. In the inactivation by 3-unsaturated 1,2-diols, product radicals stabilized by neighbouring unsaturated bonds might be unable to back-abstract the hydrogen atom from 5'-deoxyadenosine and then converted to unidentified products. In the inactivation by thioglycerol, a product radical may be lost by the elimination of sulphydryl group producing acrolein and unidentified sulphur compound(s). H(2)S or sulphide ion was not formed. The loss or stabilization of product radicals would result in the inactivation of holoenzyme, because the regeneration of the coenzyme becomes impossible.     

The binding site for the adenosyl group of coenzyme B12 in diol dehydrase

The binding of cob(II)alamin (CblII) and 5'-deoxyadenosine to diol dehydrase was studied spectroscopically and with [U-14C]5'-deoxyadenosine. CblII was bound to this enzyme forming a tight 1:1 complex which was resistant to oxidation by O2 even in the presence of CN-. An irreversible 1:1:1 ternary complex was formed between enzyme, CblII, and 5'-deoxyadenosine, when the enzyme was incubated first with the nucleoside and then with CblII. When this order of addition of the constituents was reversed, no 5'-deoxyadenosine was bound to the enzyme-CblII complex. Hydroxocobalamin could also bind to the enzyme together with the nucleoside, while other cob(III)alamins bearing a bulkier Co beta ligand displaced the nucleoside upon binding to the enzyme. The binding of [U-14C]5'-deoxyadenosine was strongly inhibited by unlabeled 5'-deoxy-ara-adenosine, 4',5'-anhydroadenosine, adenosine, adenine, and 5',8-cyclic adenosine, in this order, but not by 5'-deoxyuridine. These results constitute direct evidence for the presence of the binding site for the adenosyl group of adenosylcobalamin, which is spatially limited to and highly specific for adenine nucleosides. The binding of 5'-deoxyadenosine to the apoenzyme was reversible.     

Alternative pathways for radical dissipation in an active site mutant of B12-dependent methylmalonyl-CoA mutase

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 x 10(4))-fold compared to wild-type enzyme, the K(M)app for the cofactor approximately 4-fold, and the cob(II)alamin concentration under steady-state turnover conditions approximately 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 analogues 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 an approximately 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 analogue 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.     

Mechanism of action of adenosylcobalamin: glycerol and other substrate analogues as substrates and inactivators for propanediol dehydratase--kinetics, stereospecificity, and mechanism.

A number of vicinal diols were found to react with propanediol dehydratase, typically resulting in the conversion of enzyme-bound adenosylcobalamin to cob(II)alamin and formation of aldehyde or ketone derives from substrate. Moreover, all are capable of effecting the irreversible inactivation of the enzyme. The kinetics and mechanism of product formation and inactivation were investigated. Glycerol, found to be a very good substrate for diol dehydratase as well as a potent inactivator, atypically, did not induce cob(II)alamin formation to any detectable extent. With glycerol, the inactivation process was accompanied by conversion of enzyme-bound adenosylcobalamin to an alkyl or thiol cobalamin, probably by substitution of an amino acid chain near the active site for the 5'-deoxy-5'-adenosyl ligand on the cobalamin. The inactivation reaction with glycerol as the inactivator exhibits a deuterium isotope effect of 14, strongly implicating hydrogen transfer as an important step in the mechanism of inactivation. The isotope effect on the rate of product formation was found to be 8.0. Experiments with isotopically substituted glycerols indicate that diol dehydrase distinguishes between "R" and "S" binding conformations, the enzyme-(R)-glycerol complex being predominately responsible for the product-forming reaction, while the enzyme-(S)-glycerol complex results primarily in the activation reaction. Mechanistic implications are discussed. A method for removing enzyme-bound hydroxycobalamin that is nondestructive to the enzyme and a technique for measuring the binding constants of (R)- and (S)-1,2-propanediols are presented.     

Identification of a novel pyridoxal 5'-phosphate binding site in adenosylcobalamin-dependent lysine 5,6-aminomutase from Porphyromonas gingivalis

Lysine 5,6-aminomutase (5,6-LAM) catalyzes the interconversion of D-lysine with 2,5-diaminohexanoate and of L-beta-lysine with 3,5-diaminohexanoate. The coenzymes for 5,6-LAM are adenosylcobalamin (AdoCbl) and pyridoxal 5'-phosphate (PLP). In the proposed chemical mechanism, AdoCbl initiates the formation of substrate radicals, and PLP facilitates the radical rearrangement by forming an external aldimine linkage with the epsilon-amino group of a substrate, either D-lysine or L-beta-lysine. In the resting enzyme, an internal aldimine between PLP and an essential lysine in the active site facilitates productive PLP binding and catalysis. We present here biochemical, biophysical, and site-directed mutagenesis experiments, which document the existence of an essential lysine residue in the active site of 5,6-LAM from Porphyromonas gingivalis. Reduction of 5,6-LAM with NaBH(4) rapidly inactivates the enzyme and shifts the electronic absorption band from 420 to 325 nm. This is characteristic of the reduction of an aldimine linkage between the carbonyl group of PLP and the epsilon-amino group of a lysine residue. The reduced peptide was identified by Q-TOF/MS and further confirmed by Q-TOF/MS/MS sequencing. We show that lysine 144 in the small subunit of 5,6-LAM is the essential lysine residue. Lysine 144(beta) is separated by only 11 amino acids from histidine 133(beta), which forms a part of the "base-off"-AdoCbl binding motif. The sequence of the novel PLP-binding motif is conserved in 5,6-LAM from Clostridium sticklandii and P. gingivalis, and it is distinct from all known PLP-binding motifs. Mutation of lysine 144(beta) to glutamine led to K144Q(beta)-5,6-LAM, which displayed no enzymatic activity and no absorption band corresponding to an internal PLP-aldamine. In summary, we introduce a novel PLP-binding motif, the first to be discovered in an AdoCbl-dependent enzyme.     

Reduction of Cob(III)alamin to Cob(II)alamin in Salmonella enterica serovar typhimurium LT2

Reduction of the cobalt ion of cobalamin from the Co(III) to the Co(I) oxidation state is essential for the synthesis of adenosylcobalamin, the coenzymic form of this cofactor. A cob(II)alamin reductase activity in Salmonella enterica serovar Typhimurium LT2 was isolated to homogeneity. N-terminal analysis of the homogeneous protein identified NAD(P)H:flavin oxidoreductase (Fre) (EC 1.6.8.1) as the enzyme responsible for this activity. The fre gene was cloned, and the overexpressed protein, with a histidine tag at its N terminus, was purified to homogeneity by nickel affinity chromatography. His-tagged Fre reduced flavins (flavin mononucleotide [FMN] and flavin adenine dinucleotide [FAD]) and cob(III)alamin to cob(II)alamin very efficiently. Photochemically reduced FMN substituted for Fre in the reduction of cob(III)alamin to cob(II)alamin, indicating that the observed cobalamin reduction activity was not Fre dependent but FMNH(2) dependent. Enzyme-independent reduction of cob(III)alamin to cob(II)alamin by FMNH(2) occurred at a rate too fast to be measured. The thermodynamically unfavorable reduction of cob(II)alamin to cob(I)alamin was detectable by alkylation of the cob(I)alamin nucleophile with iodoacetate. Detection of the product, caboxymethylcob(III)alamin, depended on the presence of FMNH(2) in the reaction mixture. FMNH(2) failed to substitute for potassium borohydride in in vitro assays for corrinoid adenosylation catalyzed by the ATP:co(I)rrinoid adenosyltransferase (CobA) enzyme, even under conditions where Fre and NADH were present in the reaction mixture to ensure that FMN was always reduced. These results were interpreted to mean that Fre was not responsible for the generation of cob(I)alamin in vivo. Consistent with this idea, a fre mutant displayed wild-type cobalamin biosynthetic phenotypes. It is proposed that S. enterica serovar Typhimurium LT2 may not have a cob(III)alamin reductase enzyme and that, in vivo, nonadenosylated cobalamin and other corrinoids are maintained as co(II)rrinoids by reduced flavin nucleotides generated by Fre and other flavin oxidoreductases.     

Interaction of 3'-[3H]2'-Chloro-2'-deoxyuridine 5'-triphosphate with ribonucleotide reductase from Lactobacillus leichmannii

Incubation of [3'-3H]2'-chloro-2'-deoxyuridine 5'-triphosphate (CldUTP) with adenosylcobalamin (AdoCbl), reductant, and ribonucleotide reductase from Lactobacillus leichmannii results in the production of 3H2O, uracil, tripolyphosphate, 5'-deoxyadenosine, and cob(II)alamin. The rate of 3H2O release (0.19 mumol/min/mg) is almost identical with the rate of UTP reduction (0.24 mumol/min/mg). The amount of 3H2O release is dependent upon the enzyme to cofactor ratio. With a ribonucleotide reductase: AdoCbl ratio of 1:1000, approximately 500 eq of 3H2O are released. At this time the enzyme is still active, but further destruction of cofactor and turnover of CldUTP is prevented by competitive inhibition of Co(II) + 5'-deoxyadenosine with AdoCbl for binding to ribonucleotide reductase. The 5'-deoxyadenosine and AdoCbl reisolated during incubation of [3'-3H]CldUTP and ribonucleotide reductase contains no detectable radioactivity.     

A novel reaction between adenosylcobalamin and 2-methyleneglutarate catalyzed by glutamate mutase

We describe a novel reaction of adenosylcobalamin that occurs when adenosylcobalamin-dependent glutamate mutase is reacted with the substrate analogue 2-methyleneglutarate. Although 2-methyleneglutarate is a substrate for the closely related adenosylcobalamin-dependent enzyme 2-methyleneglutarate mutase, it reacts with glutamate mutase to cause time-dependent inhibition of the enzyme. Binding of 2-methyleneglutarate to glutamate mutase initiates homolysis of adenosylcobalamin. However, instead of the adenosyl radical proceeding to abstract a hydrogen from the substrate, which is the next step in all adenosylcobalamin-dependent enzymes, the adenosyl radical undergoes addition to the exo-methylene group to generate a tertiary radical at C-2 of methyleneglutarate. This radical has been characterized by EPR spectroscopy with regiospecifically (13)C-labeled methyleneglutarates. Irreversible inhibition of the enzyme appears to be a complicated process, and the detailed chemical and kinetic mechanism remains to be elucidated. The kinetics of this process suggest that cob(II)alamin may reduce the enzyme-bound organic radical so that stable adducts between the adenosyl moiety of the coenzyme and 2-methyleneglutarate are formed.     

Hydrazine cation radical in the active site of ethanolamine ammonia-lyase: mechanism-based inactivation by hydroxyethylhydrazine.

A study has been made of the mechanism of inactivation of the adenosylcobalamin-dependent enzyme, ethanolamine ammonia-lyase (EAL), by hydroxyethylhydrazine. Incubation of EAL with adenosylcobalamin and hydroxyethylhydrazine, an analogue of ethanolamine, leads to rapid and complete loss of enzymic activity. Equimolar quantities of 5'-deoxyadenosine, cob(II)alamin (B(12r)), hydrazine cation radical, and acetaldehyde are products of the inactivation. Inactivation is attributed to the tight binding of B(12r) in the active site. Removal of B(12r) from the protein by ammonium sulfate precipitation under acidic conditions, however, restores significant activity. This inactivation event has also been monitored by electron paramagnetic resonance (EPR) spectroscopy. In addition to EPR signals associated with B(12r), spectra of samples of inactivation mixtures reveal the presence of another radical. The other radical is bound in the active site where it undergoes weak magnetic interactions with the low spin Co(2+) in B(12r). The radical species was unambiguously identified as a hydrazine cation radical by using [(15)N(2)]hydroxyethylhydrazine, (2)H(2)O, and quantitative interpretation of the EPR spectra. Homolytic fragmentation of a hydroxyethylhydrazine radical to acetaldehyde and a hydrazine cation radical is consistent with all of the observations. All of the experiments indicate that the mechanism-based inactivation of EAL by hydroxyethylhydrazine results from irreversible cleavage of the cofactor and tight binding of B(12r) to the active site.     

The synthesis of adenine-modified analogs of adenosylcobalamin and their coenzymic function in the reaction catalyzed by diol dehydrase

Five analogs of adenosylcobalamin modified in the adenine moiety of the Co beta ligand were synthesized and tested for coenzymic function with diol dehydrase of Klebsiella pneumoniae ATCC 8724. 1-Deaza and 3-deaza analogs of adenosylcobalamin were active as coenzyme, whereas 7-deaza and N6,N6-dimethyl derivatives and guanosylcobalamin did not show detectable coenzymic activity. 7-Deaza and N6,N6-dimethyl analogs acted as strong competitive inhibitors with respect to adenosylcobalamin. The formation of cob(II)alamin as intermediate in the catalytic reaction was spectroscopically observed with catalytically active complexes of the enzyme with 1-deaza and 3-deaza analogs in the presence of 1,2-propanediol, but not with complexes with the inactive analogs. Oxygen sensitivity of the enzyme-analog complexes suggests that the carbon-cobalt bond of 1-deaza and 3-deaza analogs becomes activated by the enzyme even in the absence of substrate. These results indicate that the importance of the nitrogen atoms in the adenine moiety of the coenzyme for manifestation of catalytic function and for activation of the carbon-cobalt bond decreases in the following order: N-7 greater than 6-NH2 greater than N-3 greater than N-1. The dissociation constant for 5'-deoxyadenosine determined by equilibrium dialysis at 37 degrees C was about 23 microM.     

Adenosylcobalamin and cob(II)alamin as prosthetic groups of 2-methyleneglutarate mutase from Clostridium barkeri.

The ultraviolet/visible spectrum of the pure pink-orange 2-methyleneglutarate mutase from Clostridium barkeri between 300-600 nm showed the presence of cobalamins; notably the peaks at 470 and 528 nm were indicative of oxygen-stable cob(II)alamin and adenosylcobalamin (coenzyme B12), respectively. Using the absorption coefficients of the isosbestic points at 340, 393 and 489 nm, the total cobalamin content was estimated as 3.7 +/- 0.3 mol/mol tetrameric enzyme (m = 300 kDa). Denaturation with 8 M urea in the presence of 2 mM dithiothreitol followed by gel chromatography and renaturation afforded an inactive enzyme which contained 40-50% of the initially bound cobalamin. This preparation could be reactivated to 95-100% by addition of adenosylcobalamin. The cobalamins were removed to 85% from the mutase by denaturation with 8 M urea in the presence of 1 M cyanide (pH 12) with irreversible loss of activity. 2-Methyleneglutarate mutase was inactivated by incubation with aquo-, cyano- or methylcobalamin; up to 50% of the activity was recovered by addition of adenosylcobalamin. Upon incubation of the mutase with [5'-3H]adenosylcobalamin about 30% of the total cobalamin was exchanged by the tritium-labelled cofactor without loss of activity. During aerobic catalysis the enzyme became sensitive towards oxygen which was accompanied by loss of activity and formation of aquocobalamin from adenosylcobalamin. EPR spectroscopy demonstrated the presence of 0.8 mol base-on cob(II)alamin/mol enzyme. Upon addition of 2-methyleneglutarate a second EPR signal of about equal intensity at g = 2.13 arose. The question of whether the oxygen-stable cob(II)alamin participates in catalysis or its complex with the enzyme represents an inactive form is currently under investigation.     

Role of Arg100 in the active site of adenosylcobalamin-dependent glutamate mutase

Arginine-100 is involved in recognizing the gamma carboxylate of the substrate in glutamate mutase. To investigate its role in substrate binding and catalysis, this residue was mutated to lysine, tyrosine, and methionine. The effect of these mutations was to reduce k(cat) by 120-320-fold and to increase K(m(apparent)) for glutamate by 13-22-fold; K(m(apparent)) for adenosylcobalamin is little changed by these mutations. Even at saturating substrate concentrations, no cob(II)alamin could be detected in the UV-visible spectra of the Arg100Tyr and Arg100Met mutants. However, in the Arg100Lys mutant cob(II)alamin accumulated to concentrations similar to wild-type enzyme, which allowed the pre-steady-state kinetics of adenosylcobalamin homolysis to be investigated by stopped-flow spectroscopy. It was found that homolysis of the coenzyme is slower by an order of magnitude, compared with wild-type enzyme. Furthermore, glutamate binding is significantly weakened, so much so that the reaction exhibits second-order kinetics over the range of substrate concentrations used. The Arg100Lys mutant does not exhibit the very large deuterium isotope effects that are observed for homolysis of the coenzyme when the wild-type enzyme is reacted with deuterated substrates; this suggests that homolysis is slowed relative to hydrogen abstraction by this mutation.