Regulation of S-adenosylmethionine synthetase in Escherichia coli

The structure of the SAM/SAH-binding riboswitch

S-adenosylmethionine (SAM) is a central metabolite since it is used as a methyl group donor in many different biochemical reactions. Many bacteria control intracellular SAM concentrations using riboswitch-based mechanisms. A number of structurally different riboswitch families specifically bind to SAM and mainly regulate the transcription or the translation of SAM-biosynthetic enzymes. In addition, a highly specific riboswitch class recognizes S-adenosylhomocysteine (SAH)—the product of SAM-dependent methyl group transfer reactions—and regulates enzymes responsible for SAH hydrolysis. High-resolution structures are available for many of these riboswitch classes and illustrate how they discriminate between the two structurally similar ligands SAM and SAH. The so-called SAM/SAH riboswitch class binds both ligands with similar affinities and is structurally not yet characterized. Here, we present a high-resolution nuclear magnetic resonance structure of a member of the SAM/SAH-riboswitch class in complex with SAH. Ligand binding induces pseudoknot formation and sequestration of the ribosome binding site. Thus, the SAM/SAH-riboswitches are translational ‘OFF’-switches. Our results establish a structural basis for the unusual bispecificity of this riboswitch class. In conjunction with genomic data our structure suggests that the SAM/SAH-riboswitches might be an evolutionary late invention and not a remnant of a primordial RNA-world as suggested for other riboswitches.

Two-carbon folate cycle of commensal Lactobacillus reuteri 6475 gives rise to immunomodulatory ethionine, a source for histone ethylation

Colonization of the gut by certain probiotic Lactobacillus reuteri strains has been associated with reduced risk of inflammatory diseases and colorectal cancer. Previous studies pointed to a functional link between immunomodulation, histamine production, and folate metabolism, the central 1-carbon pathway for the transfer of methyl groups. Using mass spectrometry and NMR spectroscopy, we analyzed folate metabolites of L. reuteri strain 6475 and discovered that the bacterium produces a 2-carbon-transporting folate in the form of 5,10-ethenyl-tetrahydrofolyl polyglutamate. Isotopic labeling permitted us to trace the source of the 2-carbon unit back to acetate of the culture medium. We show that the 2C folate cycle of L. reuteri is capable of transferring 2 carbon atoms to homocysteine to generate the unconventional amino acid ethionine, a known immunomodulator. When we treated monocytic THP-1 cells with ethionine, their transcription of TNF-α was inhibited and cell proliferation reduced. Mass spectrometry of THP-1 histones revealed incorporation of ethionine instead of methionine into proteins, a reduction of histone-methylation, and ethylation of histone lysine residues. Our findings suggest that the microbiome can expose the host to ethionine through a novel 2-carbon transporting variant of the folate cycle and modify human chromatin via ethylation.-Röth, D., Chiang, A. J., Hu, W., Gugiu, G. B., Morra, C. N., Versalovic, J., Kalkum, M. The two-carbon folate cycle of commensal Lactobacillus reuteri 6475 gives rise to immunomodulatory ethionine, a source for histone ethylation.

Methionine

This review focuses on the steps unique to methionine biosynthesis, namely the conversion of homoserine to methionine. The past decade has provided a wealth of information concerning the details of methionine metabolism and the review focuses on providing a comprehensive overview of the field, emphasizing more recent findings. Details of methionine biosynthesis are addressed along with key cellular aspects, including regulation, uptake, utilization, AdoMet, the methyl cycle, and growing evidence that inhibition of methionine biosynthesis occurs under stressful cellular conditions. The first unique step in methionine biosynthesis is catalyzed by the metA gene product, homoserine transsuccinylase (HTS, or homoserine O-succinyltransferase). Recent experiments suggest that transcription of these genes is indeed regulated by MetJ, although the repressor-binding sites have not yet been verified. Methionine also serves as the precursor of S-adenosylmethionine, which is an essential molecule employed in numerous biological processes. S-adenosylhomocysteine is produced as a consequence of the numerous AdoMet-dependent methyl transfer reactions that occur within the cell. In E. coli and Salmonella, this molecule is recycled in two discrete steps to complete the methyl cycle. Cultures challenged by oxidative stress appear to experience a growth limitation that depends on methionine levels. E. coli that are deficient for the manganese and iron superoxide dismutases (the sodA and sodB gene products, respectively) require the addition of methionine or cysteine for aerobic growth. Modulation of methionine levels in response to stressful conditions further increases the complexity of its regulation.

LuxS influences Escherichia coli biofilm formation through autoinducer-2-dependent and autoinducer-2-independent modalities

Escherichia coli produces biofilms in response to the small molecule autoinducer-2 (AI-2), a product of the LuxS enzyme. LuxS is part of the activated methyl cycle and could also affect biofilm development by AI-2-independent effects on metabolism. A luxS deletion mutant of E. coli W3110 and an inducible plasmid-luxS-complemented strain were used to identify AI-2-independent phenotypes. Differential interference contrast microscopy revealed distinct surface colonization patterns. Confocal microscopy followed by quantitative image analysis determined differences in biofilm topography correlating with luxS expression; deletion mutant biofilms had a 'spreading' phenotype, whereas the complement had a 'climbing' phenotype. Addition of exogenous 4,5-dihydroxy-2,3-pentanedione (DPD), an AI-2 precursor, to the deletion mutant increased biofilm height and biomass, whereas addition of the methyl donor S-adenosyl methionine or aspartate prevented the luxS-complemented strain from producing a thick biofilm. The luxS-complemented strain autoaggregated, indicating that fimbriae production was inhibited, which was confirmed by transmission electron microscopy. DPD could not induce autoaggregation in the deletion mutant, demonstrating that fimbriation was an AI-2-independent phenotype. Carbon utilization was affected by LuxS, potentially contributing to the observed phenotypic differences. Overall, the work demonstrated that LuxS affected E. coli biofilm formation independently of AI-2 and could assist in adapting to diverse conditions.

Regulation of methionine synthesis in Escherichia coli: Effect of metJ gene product and S-adenosylmethionine on the expression of the metF gene

The regulation of the expression of the Escherichia coli metF gene, which codes for 5,10-methylenetet-rahydrofolate reductase (EC 1.1.99.15), has been investigated by using a simplified DNA-directed in vitro system that measures the formation of the first dipeptide (fMet-Ser) of the gene product. The synthesis of fMet-Ser directed by a plasmid containing the metF gene is specifically inhibited by metJ protein (repressor protein). S-Adenosylmethionine enhances the inhibition by the metJ protein of metF gene expression. The inhibition by the metJ protein is at the level of transcription and the results suggest that S-adenosylmethionine is functioning as an allosteric effector.

Functional analysis of luxS in the probiotic strain Lactobacillus rhamnosus GG reveals a central metabolic role important for growth and biofilm formation

Quorum sensing is involved in the regulation of multicellular behavior through communication via small molecules. Given the high number and diversity of the gastrointestinal microbiota, it is postulated that members of this community communicate to coordinate a variety of adaptive processes. AI-2 is suggested to be a universal bacterial signaling molecule synthesized by the LuxS enzyme, which forms an integral part of the activated methyl cycle. We have previously reported that the well-documented probiotic strain Lactobacillus rhamnosus GG, a human isolate, produces AI-2-like molecules. In this study, we identified the luxS homologue of L. rhamnosus GG. luxS seems to be located in an operon with a yxjH gene encoding a putative cobalamin-independent methionine synthase. In silico analysis revealed a methionine-specific T box in the leader sequence of the putative yxjH-luxS operon. However, transcriptional analysis showed that luxS is expressed mainly as a monocistronic transcript. Construction of a luxS knockout mutant confirmed that the luxS gene is responsible for AI-2 production in L. rhamnosus GG. However, this mutation also resulted in pleiotropic effects on the growth of this fastidious strain. Cysteine, pantothenate, folic acid, and biotin could partially complement growth, suggesting a central metabolic role for luxS in L. rhamnosus GG. Interestingly, the luxS mutant also showed a defect in monospecies biofilm formation. Experiments with chemically synthesized (S)-4,5-dihydroxy-2,3-pentanedione, coculture with the wild type, and nutritional complementation suggested that the main cause of this defect has a metabolic nature. Moreover, our data indicate that suppressor mutations are likely to occur in luxS mutants of L. rhamnosus GG. Therefore, results of luxS-related studies should be carefully interpreted.

In vivo hydrolysis of S-adenosylmethionine induces the met regulon of Escherichia coli

Regulation of methionine biosynthesis inEscherichia coliinvolves a complex of the MetJ aporepressor protein andS-adenosylmethionine (SAM) repressing expression of most genes in themetregulon. To test the role of SAM in the regulation ofmetgenes directly, SAM pools were depleted by thein vivoexpression of the cloned plasmid vector-based coliphage T3 SAM hydrolase (SAMase) gene. Cultures within vivoSAMase activity were assayed for expression of themetA,B,C,E,F,H,J,KandRgenes in cells grown in methionine-rich complete media as well as in defined media with and withoutl-methionine.In vivoSAMase activity dramatically induced expression between 11- and nearly 1000-fold depending on the gene assayed for all butmetJandmetH, and these genes were induced over twofold.metJ : : Tn5(aporepressor defective) andmetK : : Tn5(SAM synthetase impaired; produces <5 % of wild-type SAM) strains containingin vivoSAMase activity produced even highermetgene activity than that seen in comparably prepared cells with wild-type genes for all butmetJin a MetJ-deficient background. The SAMase-mediated hyperinduction ofmetHin wild-type cells and of themetgenes assayed inmetJ : : Tn5andmetK : : Tn5cells provokes questions about how other elements such as the MetR activator protein or factors beyond themetregulon itself might be involved in the regulation of genes responsible for methionine biosynthesis.

Studies on the role of the metK gene product of Escherichia coli K-12

We show here that the metK gene is essential to the growth of Escherichia coli K-12 and can be deleted only in the presence of a rescue plasmid carrying a functional metK gene. When metK expression was limited, genomic DNA methylation decreased and cell division was hampered. Through primer extension, the transcription start site of metK was located at 140 bp upstream of the translation start site. The frequently used metK84 mutant has been shown to carry an A(r)G transition in the -10 region of the metK promoter. This accounts for its low level of S-adenosylmethionine (SAM) synthetase and SAM deficiency.

Comparison of repressor and transcriptional attenuator systems for control of amino acid biosynthetic operons

In bacteria, expression from amino acid biosynthetic operons is transcriptionally controlled by two main mechanisms with principally different modes of action. When the supply of an amino acid is in excess over demand, its concentration will be high and when the supply is deficient the amino acid concentration will be low. In repressor control, such concentration variations in amino acid pools are used to regulate expression from the corresponding amino acid synthetic operon; a high concentration activates and a low concentration inactivates repressor binding to the operator site on DNA so that initiation of transcription is down or up-regulated, respectively. Excess or deficient supply of an amino acid also speeds or slows, respectively, the rate by which the ribosome translates mRNA base triplets encoding this amino acid. In attenuation of transcription, it is the rate by which the ribosome translates such "own" codons in the leader of an amino acid biosynthetic operon that decides whether the RNA polymerase will continue into the operon, or whether transcription will be aborted (attenuated). If the ribosome rate is fast (excess synthesis of amino acid), transcription will be terminated and if the rate is slow (deficient amino acid supply) transcription will continue and produce more messenger RNAs. Repressor and attenuation control systems have been modelled mathematically so that their behaviour in living cells can be predicted and their system properties compared. It is found that both types of control systems are unexpectedly sensitive when they operate in the cytoplasm of bacteria. In the repressor case, this is because amino acid concentrations are hypersensitive to imbalances between supply and demand. In the attenuation case, the reason is that the rate by which ribosomes translate own codons is hypersensitive to the rate by which the controlled amino acid is synthesised. Both repressor and attenuation mechanisms attain close to Boolean properties in vivo: gene expression is either fully on or fully off except in a small interval around the point where supply and demand of an amino acid are perfectly balanced.Our results suggest that repressors have significantly better intracellular performance than attenuator mechanisms. The reason for this is that repressor, but not attenuator, mechanisms can regulate expression from biosynthetic operons also when transfer RNAs are fully charged with amino acids so that the ribosomes work with maximal speed.

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.

Development of a system for genetic manipulation of Bartonella bacilliformis

Lack of a system for site-specific genetic manipulation has severely hindered studies on the molecular biology of all Bartonella species. We report the first site-specific mutagenesis and complementation for a Bartonella species. A highly transformable strain of B. bacilliformis, termed JB584, was isolated and found to exhibit a significant increase in transformation efficiency with the broad-host-range plasmid pBBR1MCS-2, relative to wild-type strains. Restriction analyses of genomic preparations with the methylation-sensitive restriction enzymes ClaI and StuI suggest that strain JB584 possesses a dcm methylase mutation that contributes to its enhanced transformability. A suicide plasmid, pUB1, which contains a polylinker, a pMB1 replicon, and a nptI kanamycin resistance cassette, was constructed. An internal 508-bp fragment of the B. bacilliformis flagellin gene (fla) was cloned into pUB1 to generate pUB508, a fla-targeting suicide vector. Introduction of pUB508 into JB584 by electroporation generated eight Kan(r) clones of B. bacilliformis. Characterization of one of these strains, termed JB585, indicated that allelic exchange between pUB508 and fla had occurred. Analysis by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, immunoblotting, and electron microscopy showed that synthesis of flagellin encoded by fla and secretion/assembly of flagella were abolished. Complementation of fla in trans was accomplished with a pBBR1MCS recombinant containing the entire wild-type fla gene (pBBRFLAG). These data conclusively show that inactivation of fla results in a bald, nonmotile phenotype and that pMB1 and REP replicons make suitable B. bacilliformis suicide and shuttle vectors, respectively. When used in conjunction with the highly transformable strain JB584, this system for site-specific genetic manipulation and complementation provides a new venue for studying the molecular biology of B. bacilliformis.

A family of S-methylmethionine-dependent thiol/selenol methyltransferases. Role in selenium tolerance and evolutionary relation

Several plant species can tolerate high concentrations of selenium in the environment, and they accumulate organoselenium compounds. One of these compounds is Se-methylselenocysteine, synthesized by a number of species from the genus Astragalus (Fabaceae), like A. bisulcatus. An enzyme has been previously isolated from this organism that catalyzes methyl transfer from S-adenosylmethionine to selenocysteine. To elucidate the role of the enzyme in selenium tolerance, the cDNA coding for selenocysteine methyltransferase from A. bisulcatus was cloned and sequenced. Data base searches revealed the existence of several apparent homologs of hitherto unassigned function. The gene for one of them, yagD from Escherichia coli, was cloned, and the protein was overproduced and purified. A functional analysis showed that the YagD protein catalyzes methylation of homocysteine, selenohomocysteine, and selenocysteine with S-adenosylmethionine and S-methylmethionine as methyl group donors. S-Methylmethionine was now shown to be also the physiological methyl group donor for the A. bisulcatus selenocysteine methyltransferase. A model system was set up in E. coli which demonstrated that expression of the plant and, although to a much lesser degree, of the bacterial methyltransferase gene increases selenium tolerance and strongly reduces unspecific selenium incorporation into proteins, provided that S-methylmethionine is present in the medium. It is postulated that the selenocysteine methyltransferase under selective pressure developed from an S-methylmethionine-dependent thiol/selenol methyltransferase.

S-methylmethionine metabolism in Escherichia coli

Selenium-accumulating Astragalus spp. contain an enzyme which specifically transfers a methyl group from S-methylmethionine to the selenol of selenocysteine, thus converting it to a nontoxic, since nonproteinogenic, amino acid. Analysis of the amino acid sequence of this enzyme revealed that Escherichia coli possesses a protein (YagD) which shares high sequence similarity with the enzyme. The properties and physiological role of YagD were investigated. YagD is an S-methylmethionine: homocysteine methyltransferase which also accepts selenohomocysteine as a substrate. Mutants in yagD which also possess defects in metE and metH are unable to utilize S-methylmethionine for growth, whereas a metE metH double mutant still grows on S-methylmethionine. Upstream of yagD and overlapping with its reading frame is a gene (ykfD) which, when inactivated, also blocks growth on methylmethionine in a metE metH genetic background. Since it displays sequence similarities with amino acid permeases it appears to be the transporter for S-methylmethionine. Methionine but not S-methylmethionine in the medium reduces the amount of yagD protein. This and the existence of four MET box motifs upstream of yfkD indicate that the two genes are members of the methionine regulon. The physiological roles of the ykfD and yagD products appear to reside in the acquisition of S-methylmethionine, which is an abundant plant product, and its utilization for methionine biosynthesis.

Lack of S-adenosylmethionine results in a cell division defect in Escherichia coli

The enzyme S-adenosylmethionine (SAM) synthetase, the Escherichia coli metK gene product, produces SAM, the cell's major methyl donor. We show here that SAM synthetase activity is induced by leucine and repressed by Lrp, the leucine-responsive regulatory protein. When SAM synthetase activity falls below a certain critical threshold, the cells produce long filaments with regularly distributed nucleoids. Expression of a plasmid-carried metK gene prevents filamentation and restores normal growth to the metK mutant. This indicates that lack of SAM results in a division defect.

A dominant negative effect of eth-1r, a mutant allele of the Neurospora crassa S-adenosylmethionine synthetase-encoding gene conferring resistance to the methionine toxic analogue ethionine

eth-1r, a thermosensitive allele of the Neurospora crassa S-adenosylmethionine (AdoMet) synthetase gene that confers ethionine resistance, has been cloned and sequenced. Replacement of an aspartic amino acid residue (D48-->N48), perfectly conserved in prokaryotic, fungal and higher eukaryotic AdoMet synthetases, was found responsible for both thermosensitivity and ethionine resistance conferred by eth-1r. Gene fusion constructs, designed to overexpress eth-1r in vivo, render transformant cells resistant to ethionine. Dominance of ethionine resistance was further demonstrated in eth-1+/eth-1r partial diploids carrying identical gene doses of both alleles. Heterozygous eth-1+/eth-1r cells have, at the same time, both the thermotolerance conferred by eth-1+ and the ethionine-resistant phenotype conferred by eth-1r. AdoMet levels and AdoMet synthetase activities were dramatically decreased in heterozygous eth-1+/ eth-1r cells. We propose that this negative effect exerted by eth-1r results from the in vivo formation of heteromeric eth-1+/eth-1r AdoMet synthetase molecules.

Cloning and characterization of the metE gene encoding S-adenosylmethionine synthetase from Bacillus subtilis

The metE gene, encoding S-adenosylmethionine synthetase (EC 2.5.1.6) from Bacillus subtilis, was cloned in two steps by normal and inverse PCR. The DNA sequence of the metE gene contains an open reading frame which encodes a 400-amino-acid sequence that is homologous to other known S-adenosylmethionine synthetases. The cloned gene complements the metE1 mutation and integrates at or near the chromosomal site of metE1. Expression of S-adenosylmethionine synthetase is reduced by only a factor of about 2 by exogenous methioinine. Overproduction of S-adenosylmethionine synthetase from a strong constitutive promoter leads to methionine auxotrophy in B. subtilis, suggesting that S-adenosylmethionine is a corepressor of methionine biosynthesis in B. subtilis, as others have already shown for Escherichia coli.

Methionine inhibits developmental aggregation of Myxococcus xanthus by blocking the biosynthesis of S-adenosyl methionine

Previous studies showed that high concentrations of methionine (> 1 mM) inhibited aggregation and fruiting body formation in Myxococcus xanthus (E. Rosenberg, D. Filer, D. Zafriti, and S. H. Kindler, J. Bacteriol. 115: 29-34, 1973, and J. M. Campos and D. R. Zusman, Proc. Natl. Acad. Sci. USA 72:518-522, 1975). However, the mechanism for the inhibition was unclear. In this study, we found that high levels of methionine inhibited the biosynthesis of S-adenosylmethionine (SAM) and that reduced intracellular levels of SAM are correlated with defective chemotactic movements and reduced developmental gene expression. In addition, we found that methionine analogs and high concentrations of amino acids which are known to affect SAM synthesis in other bacteria, such as threonine, lysine, and isoleucine, also caused reduced cellular levels of SAM and blocked fruiting body formation in M. xanthus. These results indicate that SAM is required for development of M. xanthus and the inhibitory effect of methionine on development results, at least in part, from its blocking of the biosynthesis of SAM.

Isozymes of S-adenosylmethionine synthetase are encoded by tandemly duplicated genes in Escherichia coli

The sole biosynthetic route to S-adenosylmethionine, the primary biological alkylating agent, is catalysed by S-adenosylmethionine synthetase (ATP:L-methionine S-adenosyltransferase). In Escherichia coli and Salmonella typhimurium numerous studies have located a structural gene (metK) for this enzyme at 63 min on the chromosomal map. We have now identified a second structural gene for S-adenosylmethionine synthetase in E. coli by DNA hybridization experiments with metK as the probe; we denote this gene as metX. The metX gene is located adjacent to metK with the gene order speA metK metX speC. The metK and metX genes are separated by approximately 0.8 kb. The metK and the metX genes are oriented convergently as indicated by DNA hybridization experiments using sequences from the 5' and 3' ends of metK. The metK gene product is detected immunochemically only in cells growing in minimal media, whereas the metX gene product is detected immunochemically in cells grown in rich media at all growth phases and in stationary phase in minimal media. Mutants in metK or metX were obtained by insertion of a kanamycin resistance element into the coding region of the cloned metK gene (metK::kan) followed by use of homologous recombination to disrupt the chromosomal metK or metX gene. The metK::kan mutant thus prepared does not grow on minimal media but does grow normally on rich media, while the corresponding metX::kan mutant does not grow on rich media although it grows normally on minimal media. These results indicate that metK expression is essential for growth of E. coli on minimal media and metX expression is essential for growth on rich media. Our results demonstrate that AdoMet synthetase has an essential cellular and/or metabolic function. Furthermore, the growth phenotypes, as well as immunochemical studies, demonstrate that the two genes that encode S-adenosylmethionine synthetase isozymes are differentially regulated. The mutations in metK and metX are highly unstable and readily yield kanamycin-resistant cells in which the chromosomal location of the kanamycin-resistance element has changed.

Regulation of methionine synthesis in Escherichia coli

The biosynthesis of methionine in Escherichia coli is under complex regulation. The repression of the biosynthetic pathway by methionine is mediated by a repressor protein (MetJ protein) and S-adenosyl-methionine which functions as a corepressor for the MetJ protein. Recently, a new regulatory locus, metR, has been identified. The MetR protein is required for both metE and metH gene expression, and functions as a transactivator of transcription of these genes. MetR is a unique prokaryotic transcription activator in that it possesses a leucine zipper motif, first described for eukaryotic DNA-binding proteins. The transcriptional activity of MetR is modulated by homocysteine, the metabolic precursor of methionine. Finally, it is known that vitamin B12 can repress expression of the metE gene. This effect is mediated by the MetH holoenzyme, which contains a cobamide prosthetic group.

Novel Escherichia coli K-12 mutants impaired in S-adenosylmethionine synthesis

S-Adenosylmethionine (AdoMet) plays a myriad of roles in cellular metabolism. One of the many roles of AdoMet in Escherichia coli and Salmonella typhimurium is as a corepressor of genes encoding enzymes of methionine biosynthesis. To investigate the metabolic effects of large reductions in intracellular AdoMet concentrations in growing cells, we constructed and examined mutants of E. coli which are conditionally defective in AdoMet synthesis. Temperature-sensitive mutants in metK, the structural gene for the S-adenosylmethionine synthetase (AdoMet synthetase) expressed in minimal medium, were constructed by in vitro mutagenesis of a plasmid-borne copy of metK. By homologous recombination, the chromosomal copy was replaced with the mutated metK gene. Both heat- and cold-sensitive mutants were examined. At the nonpermissive temperature, two such mutants had 200-fold-reduced intracellular AdoMet levels and required either methionine or vitamin B12 for growth. In the presence of methionine or vitamin B12, the mutants grew at normal rates even though the AdoMet levels remained 0.5% of wild type. A third mutant when placed at nonpermissive temperature had less than 0.2% of the normal AdoMet level and did not grow on minimal medium even in the presence of methionine or vitamin B12. All of these mutants grew normally on yeast-extract-based medium in which an alternate form of S-adenosylmethionine synthetase was expressed.

An ethA mutation in Bacillus subtilis 168 permits induction of sporulation by ethionine and increases DNA modification of bacteriophage phi 105

In contrast to Escherichia coli and Salmonella typhimurium, Bacillus subtilis could convert ethionine to S-adenosylethionine (SAE), as can Saccharomyces cerevisiae. This conversion was essential for growth inhibition by ethionine because metE mutants which were deficient in S-adenosylmethionine synthetase activity, were resistant to 10 mM ethionine and converted only a small amount of ethionine to SAE. Another mutation (ethA1) produced partial resistance to ethionine (2 mM) and enabled continual sporulation in glucose medium containing 4 mM DL-ethionine. This sporulation induction probably resulted from the effect of SAE, since it was abolished by the addition of a metE1 mutation. The induction of sporulation was not simply controlled by the ratio of SAE to S-adenosylmethionine, but apparently depended on another effect of the ethA1 mutation, which could be demonstrated by comparing the restriction of clear plaque mutants of bacteriophage phi 105 grown in an ethA1 strain with the restriction of those grown in the standard strain. The phages grown in the ethA1 strain showed increased protection against BsuR restriction. We propose that SAE induces sporulation through the inhibition of a key methylation reaction.

Evolution in biosynthetic pathways: two enzymes catalyzing consecutive steps in methionine biosynthesis originate from a common ancestor and possess a similar regulatory region

The metC gene of Escherichia coli K-12 was cloned and the nucleotide sequence of the metC gene and its flanking regions was determined. The translation initiation codon was identified by sequencing the NH2-terminal part of beta-cystathionase, the MetC gene product. The metC gene (1185 nucleotides) encodes a protein having 395 amino acid residues. The 5' noncoding region was found to contain a "Met box" homologous to sequences suggestive of operator structures upstream from other methionine genes that are controlled by the product of the pleiotropic regulatory metJ gene. The deduced amino acid sequence of beta-cystathionase showed extensive homology with that of the MetB protein (cystathionine gamma-synthase) that catalyzes the preceding step in methionine biosynthesis. The homology strongly suggests that the structural genes for the MetB and MetC proteins evolved from a common ancestral gene.

Cloning and expression of the metE gene in Escherichia coli

A lambda-transducing phage was isolated that contains the metE gene. This gene codes for N5-methyl-H4-folate:homocysteine methyltransferase (EC 2.1.1.14), an enzyme that catalyzes the terminal reaction in methionine biosynthesis. A 9.1-kb EcoR1 fragment of this phage, containing the metE gene, was then cloned into pBR325. This plasmid, pJ19, was used to transform Escherichia coli strain 2276, a metE mutant, and restore the MetE+ phenotype. Although the transformed cells produced large amounts of the metE protein in vivo, in vitro studies using pJ19 as template showed low synthesis of the metE protein.

Biosynthesis of fredericamycin A, a new antitumor antibiotic

Fredericamycin A (FM A), produced by a strain of Streptomyces griseus, represents a new structural class of antitumor antibiotics containing a spiro ring system. Studies on the producer organism showed that glucose in the fermentation medium is not utilized until late in the growth stage, just prior to synthesis of FM A. [14C]Glucose tracer experiments demonstrated that glucose is incorporated into FM A by catabolism to acetate. Biosynthetic enrichment of FM A with single- and double-labeled [13C]acetate showed that the entire carbon skeleton of the spiro ring system is derived from acetate. L-Methionine was shown to provide the only nonskeletal carbon in FM A, the methoxy carbon at position C-6. The direction of the polyketide chain and the position of the carbon lost during biosynthesis were established by using stable isotope experiments. A general model for FM A biosynthesis is proposed, and a possible scheme for the formation of the spiro carbon center is presented.

Insertion mutagenesis of the metJBLF gene cluster of Escherichia coli K-12: evidence for an metBL operon

The effects of Mu or transposon 5 insertions on the expression of genes of the metJBLF cluster show that metB and metL form an operon, transcribed from metB to metL, and that metF and metJ are independently transcribed.

Physical organization of the metJB component of the Escherichia coli K-12 metJBLF gene cluster

The structures of a series of plaque-forming metJB transducing phage were studied by restriction endonuclease mapping and enzyme activity assay. One of these phage, lambda pmet100, was inactivated by heat shock in the presence of EDTA, and deletion mutants were selected from the survivors. Two of these mutants, lambda pmet100 delta 1 and lambda pmet100 delta 2, were used to confirm the gene order metJ metB when moving clockwise on the linkage map of Escherichia coli K-12. Additional results indicate that the metB gene can be expressed independently of any other component of the met regulon and that the metJ gene also forms a separate transcription unit.

Localization of the metJBLF gene cluster of Escherichia coli in lambda met transducing phage

The position of the metJBLF gene cluster in the transducing phage lambda met102 was determined by ligation of its leftmost EcoRI fragment (102-1) to the lambda BCDEF (nin5) EcoRI fragment of lambda gtl (lambda BC) and characterization of the resultant recombinant phage. The new transducing phage carries about 6kb of bacterial DNA which contains the entire met gene cluster including the promoter of its rightmost member metF. Reasonable estimates of the coding capacity required for the four genes indicate that most of the bacterial DNA of the recombinant phage is occupied by the met gene cluster.

Mutations affecting regulation of methionine biosynthetic genes isolated by use of met-lac fusions

Fusions of the lac genes to the promoters of four structural genes in the methionine biosynthetic pathway, metA, metB, metE, and metF, were obtained by the use of the Mu d(Ap lac) bacteriophage. The levels of beta-galactosidase in these strains could be derepressed by growth under methionine-limiting conditions. Furthermore, growth in the presence of vitamin B12 repressed the synthesis of beta-galactosidase in strains containing a fusion of lacZ to the metE promoter, phi(metE'-lacZ+). Mutations affecting the regulation of met-lac fusions were generated by the insertion of Tn5. Tn5 insertions were obtained at the known regulatory loci metJ and metK. Interestingly, a significant amount of methionine adenosyltransferase activity remained in the metK mutant despite the fact that the mutation was generated by an insertion. Several Tn5-induced regulatory mutations were isolated by screening for high-level beta-galactosidase expression in a phi(metE'-lacZ+) strain in the presence of vitamin B12. Tn5 insertions mapping at the btuB (B12 uptake), metH (B12 dependent tetrahydropteroylglutamate methyltransferase), and metF (5,10-methylenetetrahydrofolate reductase) loci were obtained. The isolation of the metH mutant was consistent with previous suggestions that the metH gene product is required for the repression of metE by vitamin B12. The metF::Tn5 insertion was of particular interest since it suggested that a functional metf gene product was also needed for repression of metE by vitamin B12.

Structural studies of lambda transducing bacteriophage carrying bacterial deoxyribonucleic acid from the metBJLF region of the Escherichia coli chromosome

The structures of several lambda dmet and related lambda darg transducing phage were studied by restriction fragment mapping and electron microscopic measurements of homoduplexes and heteroduplexes. A new transducing phage (lambda dmet141), in which metF is the only functional gene of the cluster, was isolated. In contrast, lambda dmet117, which expresses the entire metBJLF cluster, has only 3 kilobases more bacterial deoxyribonucleic acid (DNA) than lambda dmet141. An EcoRI restriction fragment of lambda dmet117, which carries the leftmost 6 kilobases of the bacterial DNA insert, was isolated and shown to contain a functional copy of metB. Small structural differences at the attachment sites of some of the phage were shown to result from different sites of lambda integration in the two parent insertion lysogens.

Inhibition of leucine transport in Saccharomyces by S-adenosylmethionine

S-Adenoxyl-L-methionine (SAM) inhibited leucine transport in Saccharomyces cerevisiae. By using a mutant defective in the active transport of SAM, we demonstrated that the inhibitory effect was exerted at an extracellular site. Cells preincubated wtih SAM for 120 min became refractory to its inhibitory effect, which was not a result of either the active transport or the metabolism of SAM. The quantitative recovery of labeled SAM from the incubation medium indicated that SAM, and not a metabolite, was the true inhibitory molecule. S-Adenosyl-L-homocysteine and S-adenosyl-L-ethionine also functioned as inhibitors of leucine transport, whereas S-adenosyl-D-methionine, S-adenosyl-D-homocystein, 5'-methylthioadenosine, 5'-dimethylthioadenosine, and adenosine lacked this property. Kinetic studies demonstrated that SAM was a competitive inhibitor of leucine transport.

In vitro synthesis of cystathionine gamma-synthetase in Escherichia coli K-12

Synthesis of cystathionine gamma-synthetase directed by DNA from a lambdadmet transducing phage has been achieved in cell extracts from Escherichia coli K-12. Enzyme synthesis was stimulated two- to threefold by the addition of guanosine 3'-diphosphate 5'-diphosphate to the incubation mixtures. Kinetic studies showed a 1.5- to 2.0-min lag between initiation of transcription and completion of a translatable message. This lag is shorter than that observed for beta-galactosidase synthesis with DNA from a lac transducing phage known to initiate transcription at the lac promoter. This result, together with information on the structure of the transducing phage, shows that pL is not used for initiation of in vitro metB transcription. Attempts to demonstrate repression were not successful, and unexpectedly, extracts from metJ+ strains were found to be more effective at enzyme synthesis than those from their metJ derivatives.

Isolation and characterization of specialized lambda transducing bacteriophage carrying the metBJF methionine gene cluster

Secondary attachment site lysogens of Deltaatt(lambda)Deltappc-argECBH strains of Escherichia coli with lambdacI857 integrated into the bfe gene (88 min) were isolated. Of 20 such lysogens examined, 2 produce lysates with transducing phage containing the metBJF gene cluster (87 min). Reintroduction of the ppc-argECBH chromosome segment (which lies between the bfe and met genes) into these strains virtually abolishes the production of met transducing phage. All of the phage examined have lost essential genes from the left arm of the lambda chromosome. Approximately 85% of the phage appear to have the same genetic composition, containing the metBJF gene cluster, but not the closely linked gene cytR, and having lost phage genes G and J. Analytical CsCl density gradient centrifugation of five representatives of this major class of phage shows four of them to have identical densities (lighter than lambda), while the fifth cannot be resolved from lambda. The four apparently identical phage were isolated from three separate lysates, which suggests the existence of preferred sites for illegitimate recombination on the bacterial and phage chromosomes. Three specialized transducing phage that carry cytR in addition to metB, metJ, and metF have also been studied. Each of these viruses has a different amount of phage deoxyribonucleic acid. Two of them have less deoxyribonucleic acid than lambda, whereas the third has about the same amount. The metB, metF, and cytR genes of the transducing phage have been shown to function in vivo. The phage-borne metB and metF genes are subject to metJ-mediated repression.

Influence of methionine biosynthesis on serine transhydroxymethylase regulation in Salmonella typhimurium LT2

The enzyme serine transhydroxymethylase (EC 2.1.2.1; L-serine:tetrahydrofolate-5,10-hydroxymethyltransferase) is responsible both for the synthesis of glycine from serine and production of the 5,10-methylenetetrahydrofolate necessary as a methyl donor for methionine synthesis. Two mutants selected for alteration in serine transhydroxymethylase regulation also have phenotypes characteristic of metK (methionine regulatory) mutants, including ethionine, norleucine, and alpha-methylmethionine resistance and reduced levels of S-adenosylmethionine synthetase (EC 2.5.1.6; adenosine 5'-triphosphate:L-methionine S-adenosyltransferase) activity. Because this suggested the existence of a common regulatory component, the regulation of serine transhydroxymethylase was examined in other methionine regulatory mutants (metK and metJ mutants). Normally, serine transhydroxymethylase levels are repressed three- to sixfold in cells grown in the presence of serine, glycine, methionine, adenine, guanine, and thymine. This does not occur in metK and metJ mutants; thus, these mutations do affect the regulation of both serine transhydroxymethylase and the methionine biosynthetic enzymes. Lesions in the metK gene have been reported to reduce S-adenosylmethionine synthetase levels. To determine whether the metK gene actually encodes for S-adenosylmethionine synthetase, a mutant was characterized in which this enzyme has a 26-fold increased apparent Km for methionine. This mutation causes a phenotype associated with metK mutants and is cotransducible with the serA locus at the same frequency as metK lesions. Thus, the affect of metK mutations on the regulation of glycine and methionine synthesis in Salmonella typhimurium appears to be due to either an altered S-adenosylmethionine synthetase or altered S-adenosylmethionine pools.