Pathways of Assimilative Sulfur Metabolism in Pseudomonas putida

Cysteine and methionine biosynthesis was studied in Pseudomonas putida S-313 and Pseudomonas aeruginosa PAO1. Both these organisms used direct sulfhydrylation of O-succinylhomoserine for the synthesis of methionine but also contained substantial levels of O-acetylserine sulfhydrylase (cysteine synthase) activity. The enzymes of the transsulfuration pathway (cystathionine gamma-synthase and cystathionine beta-lyase) were expressed at low levels in both pseudomonads but were strongly upregulated during growth with cysteine as the sole sulfur source. In P. aeruginosa, the reverse transsulfuration pathway between homocysteine and cysteine, with cystathionine as the intermediate, allows P. aeruginosa to grow rapidly with methionine as the sole sulfur source. P. putida S-313 also grew well with methionine as the sulfur source, but no cystathionine gamma-lyase, the key enzyme of the reverse transsulfuration pathway, was found in this species. In the absence of the reverse transsulfuration pathway, P. putida desulfurized methionine by the conversion of methionine to methanethiol, catalyzed by methionine gamma-lyase, which was upregulated under these conditions. A transposon mutant of P. putida that was defective in the alkanesulfonatase locus (ssuD) was unable to grow with either methanesulfonate or methionine as the sulfur source. We therefore propose that in P. putida methionine is converted to methanethiol and then oxidized to methanesulfonate. The sulfonate is then desulfonated by alkanesulfonatase to release sulfite for reassimilation into cysteine.     

Corynebacterium glutamicum utilizes both transsulfuration and direct sulfhydrylation pathways for methionine biosynthesis

A direct sulfhydrylation pathway for methionine biosynthesis in Corynebacterium glutamicum was found. The pathway was catalyzed by metY encoding O-acetylhomoserine sulfhydrylase. The gene metY, located immediately upstream of metA, was found to encode a protein of 437 amino acids with a deduced molecular mass of 46,751 Da. In accordance with DNA and protein sequence data, the introduction of metY into C. glutamicum resulted in the accumulation of a 47-kDa protein in the cells and a 30-fold increase in O-acetylhomoserine sulfhydrylase activity, showing the efficient expression of the cloned gene. Although disruption of the metB gene, which encodes cystathionine gamma-synthase catalyzing the transsulfuration pathway of methionine biosynthesis, or the metY gene was not enough to lead to methionine auxotrophy, an additional mutation in the metY or the metB gene resulted in methionine auxotrophy. The growth pattern of the metY mutant strain was identical to that of the metB mutant strain, suggesting that both methionine biosynthetic pathways function equally well. In addition, an Escherichia coli metB mutant could be complemented by transformation of the strain with a DNA fragment carrying corynebacterial metY and metA genes. These data clearly show that C. glutamicum utilizes both transsulfuration and direct sulfhydrylation pathways for methionine biosynthesis. Although metY and metA are in close proximity to one another, separated by 143 bp on the chromosome, deletion analysis suggests that they are expressed independently. As with metA, methionine could also repress the expression of metY. The repression was also observed with metB, but the degree of repression was more severe with metY, which shows almost complete repression at 0.5 mM methionine in minimal medium. The data suggest a physiologically distinctive role of the direct sulfhydrylation pathway in C. glutamicum.     

Methionine Biosynthesis in Lemna: STUDIES ON THE REGULATION OF CYSTATHIONINE gamma-SYNTHASE, O-PHOSPHOHOMOSERINE SULFHYDRYLASE, AND O-ACETYLSERINE SULFHYDRYLASE

Regulation of enzymes of methionine biosynthesis was investigated by measuring the specific activities of O-phosphohomoserine-dependent cystathionine gamma-synthase, O-phosphohomoserine sulfhydrylase, and O-acetylserine sulfhydrylase in Lemna paucicostata Hegelm. 6746 grown under various conditions. For cystathionine gamma-synthase, it was observed that (a) adding external methionine (2 mum) decreased specific activity to 15% of control, (b) blocking methionine synthesis with 0.05 muml-aminoethoxyvinylglycine or with 36 mum lysine plus 4 mum threonine (Datko, Mudd 1981 Plant Physiol 69: 1070-1076) caused a 2- to 3-fold increase in specific activity, and (c) blocking methionine synthesis and adding external methionine led to the decreased specific activity characteristic of methionine addition alone. Activity in extracts from control cultures was unaffected by addition of methionine, lysine, threonine, lysine plus threonine, S-adenosylmethionine, or S-methylmethionine sulfonium to the assay mixture. Parallel studies of O-phosphohomoserine sulfhydrylase and O-acetylserine sulfhydrylase showed that O-phosphohomoserine sulfhydrylase activity responded to growth conditions identically to cystathionine gamma-synthase activity, whereas O-acetylserine sulfhydrylase activity remained unaffected. Lemna extracts did not catalyze lanthionine formation from O-acetylserine and cysteine. Estimates of kinetic constants for the three enzyme activities indicate that O-acetylserine sulfhydrylase has much higher activity and affinity for sulfide than O-phosphohomoserine sulfhydrylase.The results suggest that (a) methionine, or one of its products, regulates the amount of active cystathionine gamma-synthase in Lemna, (b) O-phosphohomoserine sulfhydrylase and cystathionine gamma-synthase are probably activities of one enzyme that has low specificity for its sulfur-containing substrate, and (c) O-acetylserine sulfhydrylase is a separate enzyme. The relatively high activity and affinity for sulfide of O-acetylserine sulfhydrylase provides an explanation in molecular terms for transsulfuration, and not direct sulfhydration, being the dominant pathway for homocysteine biosynthesis.     

Homocysteine biosynthesis pathways of Streptococcus anginosus

A gene (cgs) encoding cystathionine gamma-synthase was cloned from Streptococcus anginosus, and its protein was purified and characterized. The cgs gene and the immediately downstream lcd gene were shown to be cotranscribed as an operon. High-performance liquid chromatography analyses showed that the S. anginosus Cgs not only has cystathionine gamma-synthase activity, but also expresses O-acetylhomoserine sulfhydrylase activity. These results suggest that S. anginosus has the capacity to utilize both the transsulfuration and direct sulfhydrylation pathways for homocysteine biosynthesis.     

Properties of the Corynebacterium glutamicum metC gene encoding cystathionine beta-lyase

The metC gene encoding the cystathionine beta-lyase, the third enzyme in the methionine biosynthetic pathway, was isolated from Corynebacterium glutamicum by heterologous complementation of the Escherichia coli metC mutant. A DNA-sequence analysis of the cloned DNA identified two open-reading frames (ORFs) of ORF1 and ORF2 that consisted of 1,107 and 978 bp, respectively. A SDS-PAGE analysis identified a putative cystathionine beta-lyase band with approximate Mr of 41,000 that consisted of 368 amino acids encoded from ORF1. The translational product of the gene showed no significant homology with that of the metC gene from other organisms. Introduction of the plasmid containing the metC gene into C. glutamicum resulted in a 5-fold increase in the activity of the cystathionine beta-lyase. The putative protein product of ORF2, encoding a protein product of 35,574 Da, consisted of 325 amino acids and was identical to the previously reported aecD gene product, except for the existence of two different amino acids. Like the aecD gene, when present in multiple copies, the metC gene conferred resistance to S-(betaaminoethyl)-cysteine, which is a toxic lysine analog. However, genetic and biochemical evidence suggests that the natural activity of the metC gene product is to mediate methionine biosynthesis in C. glutamicum. Mutant strains of metC were constructed, and the strains showed methionine prototrophy. The mutant strains completely lost their ability to show resistance to the S-(beta-aminoethyl)-cysteine. These results suggest that, in addition to the transsulfuration, other biosynthetic pathway(s), such as a direct sulfhydrylation pathway, may be functional in C. glutamicum as a parallel biosynthetic route for methionine.     

Methionine biosynthesis and its regulation in Corynebacterium glutamicum: parallel pathways of transsulfuration and direct sulfhydrylation

There are two alternative pathways leading to methionine synthesis in microorganisms: The transsulfuration pathway involves cystathionine as the intermediate and utilizes cysteine as the sulfur source, but the direct sulfhydrylation pathway bypasses cystathionine and uses inorganic sulfur instead. While most microorganisms synthesize methionine via either one of these pathways, Corynebacterium glutamicum utilizes both pathways, which appear to be fully functional. In C. glutamicum, each pathway is catalyzed by independent enzymes and is tightly regulated by methionine. Although the physiological significance of parallel pathways remains to be elucidated, their presence suggests metabolic flexibility and efficient adaptation of the organism to its environment.     

Analysis of Corynebacterium glutamicum methionine biosynthetic pathway: isolation and analysis of metB encoding cystathionine gamma-synthase.

The metB gene encoding cystathionine y-synthase, the second enzyme of methionine biosynthetic pathway, was isolated from a pSL109-based Corynebacterium glutamicum gene library via complementation of an Escherichia coli metB mutant. A DNA-sequence analysis of the cloned DNA identified an open-reading frame of 1161 bp which encodes a protein with the molecular weight of 41,655 comprising of 386 amino acids. The putative protein product showed good amino acid-sequence homology to its counterpart in other organisms. Introduction of a plasmid carrying the cloned metB into the C. glutamicum resulted in a 10-fold increase in cystathionine gamma-synthase activities, demonstrating the identity of the cloned gene. The C. glutamicum metB mutant which was generated by the site-specific integration of the cloned DNA into its chromosome did not lose the ability to grow on glucose minimal medium lacking supplemental methionine. The growth rate of the mutant strain was also comparable to that of the parental strain. These data indicate that, in addition to the transsulfuration pathway, other methionine biosynthetic pathways may be present in C. glutamicum.     

The Mode of Action of a Carboxypeptidase from Malt

Certain methionine auxotrophs of Arthrobacter paraffineus and Bacillus species produce large amounts of O-acetylhomoserine (OAH). The methionine requirement of these auxotrophs could be satisfied by either cystathionine or homocysteine but not by homoserine. The cell-free extacts from the auxotrophs were found to be deficient in cystathionine ?-synthase activity. OAH and O-succinylhomoserine (OSH) could replace methionine in the auxotrophs which are deficient in homoserine-O-transacetylase. A methionine auxotroph of Corynebacterium glutamicum also produced OAH, and the blocked step in the auxotroph appeared to be between cystathionine and homocysteine.

Cell-free extracts of A. paraffineus, C. glutamicum and Bacillus species catalyzed the formation of OAH from acetyl-CoA and homoserine, while a corresponding reaction with succinyl-CoA was not detected. Cystathionine γ-synthases in extracts of C. glutamicum and Bacillus species were specific for OAH, while the enzyme in extract of A. paraffineus was rather specific for OSH though it reacted with OAH to a certain extent.

These results indicate that the biosynthesis of l-methionine in these bacteria involves OAH.     

Direct Sulfhydrylation for Methionine Biosynthesis in Leptospira meyeri

A gene library of the Leptospira meyeri serovar semaranga strain Veldrat S.173 DNA has been constructed in a mobilizable cosmid with inserts of up to 40 kb. It was demonstrated that a Leptospira DNA fragment carrying metY complemented Escherichia coli strains carrying mutations in metB. The latter gene encodes cystathionine γ-synthase, an enzyme which catalyzes the second step of the methionine biosynthetic pathway. The metY gene is 1,304 bp long and encodes a 443-amino-acid protein with a molecular mass of 45 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The deduced amino acid sequence of the Leptospira metY product has a high degree of similarity to those of O-acetylhomoserine sulfhydrylases from Aspergillus nidulans and Saccharomyces cerevisiae. A lower degree of sequence similarity was also found with bacterial cystathionine γ-synthase. The L. meyeri metY gene was overexpressed under the control of the T7 promoter. MetY exhibits an O-acetylhomoserine sulfhydrylase activity. Genetic, enzymatic, and physiological studies reveal that the transsulfuration pathway via cystathionine does not exist in L. meyeri, in contrast to the situation found for fungi and some bacteria. Our results indicate, therefore, that the L. meyeri MetY enzyme is able to perform direct sulfhydrylation for methionine biosynthesis by using O-acetylhomoserine as a substrate.     

Biochemical analysis on the parallel pathways of methionine biosynthesis in Corynebacterium glutamicum

Two alternative pathways for methionine biosynthesis are known in Corynebacterium glutamicum: one involving transsulfuration (mediated by metB and metC) and the other involving direct sulthydrylation (mediated by metY). In this study, MetB (cystathionine gamma-synthase) and MetY (O-acetylhomoserine sulfhydrylase) from C. glutamicum were purified to homogeneity and the biochemical parameters were compared to assess the functional and evolutionary importance of each pathway. The molecular masses of the native MetB and MetY proteins were measured to be approximately 170 and 280 kDa, respectively, showing that MetB was a homotetramer of 40-kDa subunits and MetY was a homohexamer of 45-kDa subunits. The Km values for the O-acetylhomoserine catalysis effected by MetB and MetY were 3.9 and 6.4 mM, and the maximum catalysis rates were 7.4 (kcat = 21 s(-1)) and 6.0 (kcat=28 s(-1)) micromol mg(-1) min(-1), respectively. This suggests that both MetB and MetY can be comparably active in vivo. Nevertheless, the Km value for sulfide ions by MetY was 8.6 mM, which was too high, considering the physiological condition. Moreover, MetB was active at a broad range of temperatures (30 and 65 degrees C) and pH (6.5 and 10.0), as compared with MetY, which was active in a range from 30 to 45 degrees C and at pH values from 7.0 to 8.5. In addition, MetY was inhibited by methionine, but MetB was not. These biochemical data may provide insight on the role of the parallel pathways of methionine biosynthesis in C. glutamicum with regard to cell physiology and evolution.     

O-Acetylhomoserine sulfhydrylase of the fission yeast Schizosaccharomyces pombe: partial purification, characterization, and its probable role in homocysteine biosynthesis

A crude extract of Schizosaccharomyces pombe cells catalyzed sulfhydrylation of both O-acetyl-L-serine and O-acetyl-L-homoserine with H2S, but did not synthesize cystathionine from O-acetyl-L-homoserine and L-cysteine. The O-acetylhomoserine sulfhydrylase [EC 4.2.99.10] was very unstable; however, it could be stabilized by the addition of 25% (w/w) sucrose or glycerol. The optimal pH for activity was 8.0 and that for stability was 7.0. The enzyme was purified approximately 300-fold from an ammonium sulfate-precipitated fraction. L-Methionine was the most effective inhibitor among the amino acids examined. It inhibited the enzyme competitively with respect to OAH with a Ki value of 2.6 mM. Sulfhydrylase activity was inhibited to various extents by some carbonyl reagents, but sulfhydryl reagents such as p-chloromercuribenzoic acid, 5,5'-dithio-bis(2-nitrobenzoic acid), and monoiodoacetic acid had no inhibitory effect. The enzyme also reacted with O-succinylhomoserine and L-homoserine to synthesize homocysteine directly, but could not utilize cysteine as a co-substrate in place of H2S. In the sulfhydrylation reactions, Km values for the substrates ranged from 10.4-12.5 mM. The enzyme was resolved to the apoenzyme by incubation with phenylhydrazine and reactivated by the addition of pyridoxal 5'-phosphate, whose Km value was 0.083 microM. The molecular weight of the enzyme was estimated to be approximately 186,000 by gel filtration and 170,000 by ultracentrifugation in sucrose density gradients. The isolectric point of the protein was pH 4.1. The characteristics of this enzyme are compared with those of physiologically functional sulfhydrylases reported for other organisms, and the possibility of the enzyme functioning as a homocysteine synthase is discussed.     

Mutation in the threonine synthase gene results in an over-accumulation of soluble methionine in Arabidopsis

In higher plants, O-phosphohomoserine (OPH) represents a branch point between the methionine (Met) and threonine (Thr) biosynthetic pathways. It is believed that the enzymes Thr synthase (TS) and cystathionine gamma-synthase (CGS) actively compete for the OPH substrate for Thr and Met biosynthesis, respectively. We have isolated a mutant of Arabidopsis, designated mto2-1, that over-accumulates soluble Met 22-fold and contains markedly reduced levels of soluble Thr in young rosettes. The mto2-1 mutant carries a single base pair mutation within the gene encoding TS, resulting in a leucine-204 to arginine change. Accumulation of TS mRNA and protein was normal in young rosettes of mto2-1, whereas functional complementation analysis of an Escherichia coli thrC mutation suggested that the ability of mto2-1 TS to synthesize Thr is impaired. We concluded that the mutation within the TS gene is responsible for the mto2-1 phenotype, resulting in decreased Thr biosynthesis and a channeling of OPH to Met biosynthesis in young rosettes. Analysis of the mto2-1 mutant suggested that, in vivo, the feedback regulation of CGS is not sufficient alone for the control of Met biosynthesis in young rosettes and is dependent on TS activity. In addition, developmental analysis of soluble Met and Thr concentrations indicated that the accumulation of these amino acids is regulated in a temporal and spatial manner.     

Occurrence of transsulfuration in synthesis of L-homocysteine in an extremely thermophilic bacterium, Thermus thermophilus HB8

A cell extract of an extremely thermophilic bacterium, Thermus thermophilus HB8, cultured in a synthetic medium catalyzed cystathionine gamma-synthesis with O-acetyl-L-homoserine and L-cysteine as substrates but not beta-synthesis with DL-homocysteine and L-serine (or O-acetyl-L-serine). The amounts of synthesized enzymes metabolizing sulfur-containing amino acids were estimated by determining their catalytic activities in cell extracts. The syntheses of cystathionine beta-lyase (EC 4.4.1.8) and O-acetyl-L-serine sulfhydrylase (EC 4.2.99.8) were markedly repressed by L-methionine supplemented to the medium. L-Cysteine and glutathione, both at 0.5 mM, added to the medium as the sole sulfur source repressed the synthesis of O-acetylserine sulfhydrylase by 55 and 73%, respectively, confirming that this enzyme functions as a cysteine synthase. Methionine employed at 1 to 5 mM in the same way derepressed the synthesis of O-acetylserine sulfhydrylase 2.1- to 2.5-fold. A method for assaying a low concentration of sulfide (0.01 to 0.05 mM) liberated from homocysteine by determining cysteine synthesized with it in the presence of excess amounts of O-acetylserine and a purified preparation of the sulfhydrylase was established. The extract of cells catalyzed the homocysteine gamma-lyase reaction, with a specific activity of 5 to 7 nmol/min/mg of protein, but not the methionine gamma-lyase reaction. These results suggested that cysteine was also synthesized under the conditions employed by the catalysis of O-acetylserine sulfhydrylase using sulfur of homocysteine derived from methionine. Methionine inhibited O-acetylserine sulfhydrylase markedly. The effects of sulfur sources added to the medium on the synthesis of O-acetylhomoserine sulfhydrylase and the inhibition of the enzyme activity by methionine were mostly understood by assuming that the organism has two proteins having O-acetylhomoserine sulfhydrylase activity, one of which is cystathionine gamma-synthase. Although it has been reported that homocysteine is directly synthesized in T. thermophilus HB27 by the catalysis of O-acetylhomoserine sulfhydrylase on the basis of genetic studies (T. Kosuge, D. Gao, and T. Hoshino, J. Biosci. Bioeng. 90:271-279, 2000), the results obtained in this study for the behaviors of related enzymes indicate that sulfur is first incorporated into cysteine and then transferred to homocysteine via cystathionine in T. thermophilus HB8.     

Cystathionine Synthesis in Yeast: an Alternative Pathway for Homocysteine Biosynthesis

Cystathionine synthesis from O-acetylhomoserine and cysteine has been demonstrated in yeast extracts for the first time. The activity is less than that of O-acetylhomoserine sulfhydrylase, but it is higher than that reported for homoserine O-transacetylase and therefore should not be growth limiting. Cystathionine synthase seems to share the regulatory properties of the sulfhydrylase, and both activities are missing from the methionine auxotroph Saccharomyces cerevisiae EY9, suggesting that both reactions are catalyzed by the same enzyme. However, cystathionine synthase activity was lost during purification of the sulfhydrylase, suggesting that the two reactions may be catalyzed by separate enzymes. Since previous studies have shown that yeast extracts can catalyze the cleavage of cystathionine to homocysteine, our results show the existence of two complete alternate pathways for homocysteine biosynthesis in yeast. Which of these is the major physiological pathway remains to be determined.     

O-acetylserine and O-acetylhomoserine sulfhydrylase of yeast; studies with methionine auxotrophs.

The nutritional requirements of three yeast mutants, previously shown to possess low O-acetyl-L-serine (OAS) and O-acetyl-L-homoserine (OAH) sulfhydrylase activities, were reinvestigated. It was thus found that one mutant (strain No. 16), previously identified as a homocysteine auxotroph, is in fact a double mutant requiring both cysteine and OAH. In agreement with the previous assignment, the other two strains (strains No. 13 and 17) were shown to be true cysteine auxotrophs. These results can best be explained by assuming the cystathionine pathway to be the main route of homocysteine synthesis in this organism. It was further found that extracts of the three mutants contain genetically modified OAS-OAH sulfhydrylases with much reduced catalytic activities. Modified sulfhydrylase was partially purified from strain No. 16 by the same procedure as for the wild-type enzyme. Both OAS and OAH sulfhydrylase activities of the mutant enzyme were copurified and behaved identically on polyacrylamide gel electrophoresis. The enzymatic and physicochemical properties of the purified mutant enzyme were shown to be very similar to those of the wild-type enzyme, except that the catalytic activities of the former were only 3-5% of those of the latter, and that the ratio of OAH sulfhydrylase to OAS sulfhydrylase activity was somewhat lower in the former than in the latter.     

The crystal structure of cystathionine gamma-synthase from Nicotiana tabacum reveals its substrate and reaction specificity.

Cystathionine gamma-synthase catalyses the committed step of de novo methionine biosynthesis in micro-organisms and plants, making the enzyme an attractive target for the design of new antibiotics and herbicides. The crystal structure of cystathionine gamma-synthase from Nicotiana tabacum has been solved by Patterson search techniques using the structure of Escherichia coli cystathionine gamma-synthase. The model was refined at 2.9 A resolution to a crystallographic R -factor of 20.1 % (Rfree25.0 %). The physiological substrates of the enzyme, L-homoserine phosphate and L-cysteine, were modelled into the unliganded structure. These complexes support the proposed ping-pong mechanism for catalysis and illustrate the dissimilar substrate specificities of bacterial and plant cystathionine gamma-synthases on a molecular level. The main difference arises from the binding modes of the distal substrate groups (O -acetyl/succinyl versusO -phosphate). Central in fixing the distal phosphate of the plant CGS substrate is an exposed lysine residue that is strictly conserved in plant cystathionine gamma-synthases whereas bacterial enzymes carry a glycine residue at this position. General insight regarding the reaction specificity of transsulphuration enzymes is gained by the comparison to cystathionine beta-lyase from E. coli, indicating the mechanistic importance of a second substrate binding site for L-cysteine which leads to different chemical reaction types.     

A kinetic model of the branch-point between the methionine and threonine biosynthesis pathways in Arabidopsis thaliana.

This work proposes a model of the metabolic branch-point between the methionine and threonine biosynthesis pathways in Arabidopsis thaliana which involves kinetic competition for phosphohomoserine between the allosteric enzyme threonine synthase and the two-substrate enzyme cystathionine gamma-synthase. Threonine synthase is activated by S-adenosylmethionine and inhibited by AMP. Cystathionine gamma-synthase condenses phosphohomoserine to cysteine via a ping-pong mechanism. Reactions are irreversible and inhibited by inorganic phosphate. The modelling procedure included an examination of the kinetic links, the determination of the operating conditions in chloroplasts and the establishment of a computer model using the enzyme rate equations. To test the model, the branch-point was reconstituted with purified enzymes. The computer model showed a partial agreement with the in vitro results. The model was subsequently improved and was then found consistent with flux partition in vitro and in vivo. Under near physiological conditions, S-adenosylmethionine, but not AMP, modulates the partition of a steady-state flux of phosphohomoserine. The computer model indicates a high sensitivity of cystathionine flux to enzyme and S-adenosylmethionine concentrations. Cystathionine flux is sensitive to modulation of threonine flux whereas the reverse is not true. The cystathionine gamma-synthase kinetic mechanism favours a low sensitivity of the fluxes to cysteine. Though sensitivity to inorganic phosphate is low, its concentration conditions the dynamics of the system. Threonine synthase and cystathionine gamma-synthase display similar kinetic efficiencies in the metabolic context considered and are first-order for the phosphohomoserine substrate. Under these conditions outflows are coordinated.     

Functional demonstration of reverse transsulfuration in the Mycobacterium tuberculosis complex reveals that methionine is the preferred sulfur source for pathogenic Mycobacteria

Methionine can be used as the sole sulfur source by the Mycobacterium tuberculosis complex although it is not obvious from examination of the genome annotation how these bacteria utilize methionine. Given that genome annotation is a largely predictive process, key challenges are to validate these predictions and to fill in gaps for known functions for which genes have not been annotated. We have addressed these issues by functional analysis of methionine metabolism. Transport, followed by metabolism of (35)S methionine into the cysteine adduct mycothiol, demonstrated the conversion of exogenous methionine to cysteine. Mutational analysis and cloning of the Rv1079 gene showed it to encode the key enzyme required for this conversion, cystathionine gamma-lyase (CGL). Rv1079, annotated metB, was predicted to encode cystathionine gamma-synthase (CGS), but demonstration of a gamma-elimination reaction with cystathionine as well as the gamma-replacement reaction yielding cystathionine showed it encodes a bifunctional CGL/CGS enzyme. Consistent with this, a Rv1079 mutant could not incorporate sulfur from methionine into cysteine, while a cysA mutant lacking sulfate transport and a methionine auxotroph was hypersensitive to the CGL inhibitor propargylglycine. Thus, reverse transsulfuration alone, without any sulfur recycling reactions, allows M. tuberculosis to use methionine as the sole sulfur source. Intracellular cysteine was undetectable so only the CGL reaction occurs in intact mycobacteria. Cysteine desulfhydrase, an activity we showed to be separable from CGL/CGS, may have a role in removing excess cysteine and could explain the ability of M. tuberculosis to recycle sulfur from cysteine, but not methionine.     

Suicide inactivation of bacterial cystathionine gamma-synthase and methionine gamma-lyase during processing of L-propargylglycine.

L-Propargylglycine, a naturally occurring gamma, delta-acetylenic alpha-amino acid, induces mechanism-based inactivation of two pyridoxal phosphate dependent enzymes of methionine metabolism: (1) cystathionine gamma-synthease, which catalyzes a gamma-replacement reaction in methionine biosynthesis, and (2) methionine gamma-lyase, which catalyzes a gamma-elimination reaction in methionine breakdown. Biphasic pseudo-first-order inactivation kinetics were observed for both enzymes. Complete inactivation is achieved with a minimum molar ratio ([propargylglycine]/[enzyme monomer]) of 4:1 for cystathionine gamma-synthase and of 8:1 for methionine gamma-lyase, consistent with a small number of turnovers per inactivation event. Partitioning ratios were determined directly from observed primary kinetic isotope effects. [alpha-2H]Propargylglycine displays kH/kD values of about 3 on inactivation half-times. [alpha-3H]-Propargylglycine gives release of tritium to solvent nominally stoichiometric with inactivation but, on correction for the calculated tritium isotope discrimination, partition ratios of four and six turnovers per monomer inactivated are indicated for cystathionine gamma-synthase and methionine gamma-lyase, respectively. The inactivation stoichiometry, using [alpha-14C]-propargylglycine, is four labels per tetramer of cystathionine gamma-synthase but usually only two labels per tetramer of methionine gamma-lyase (half-of-the-sites reactivity). Two-dimensional urea isoelectrofocusing/NaDodSO4 electrophoresis suggests (1) that both native enzymes are alpha 2 beta 2 tetramers where the subunits are distinguishable by charge but not by size and (2) that, while each subunit of a cystathionine gamma-synthase tetramer becomes modified by propargylglycine, only one alpha and one beta subunit may be labeled in an inactive alpha 2 beta 2 tetramer of methionine gamma-lyase. Steady-state spectroscopic analyses during inactivation indicated that modified cystathionine gamma-synthase may reprotonate C2 of the enzyme--inactivator adduct, so that the cofactor is still in the pyridoxaldimine oxidation state. Fully inactivated methionine gamma-lyase has lambda max values at 460 and 495 nm, which may represent conjugated pyridoximine paraquinoid that does not reprotonate at C2 of the bound adduct. Either species could arise from Michael-type addition of an enzymic nucleophile to an electrophilic 3,4-allenic paraquinoid intermediate, generated initially by propargylic rearrangement upon a 4,5-acetylenic pyridoximine structure, as originally proposed for propargylglycine inactivation of gamma-cystathionase [Abeles, R., & Walsh, C. (1973) J. Am. Chem. Soc. 95, 6124]. It is reasonable that cystathionine gamma-synthase is the major in vivo target for this natural acetylenic toxin, the growth-inhibitory effects of which are reversed by methionine.