The Escherichia coli Dga (MurI) protein shares biological activity and structural domains with the Pediococcus pentosaceus glutamate racemase.

The Pediococcus pentosaceus glutamate racemase gene product complemented the D-glutamate auxotrophy of Escherichia coli WM335. Amino acid sequence analysis of the two proteins revealed 28% identity, primarily in six clusters scattered throughout the sequence. Further analyses indicated secondary structure similarities between the two proteins. These data support a recent report that the dga (murI) gene product is a glutamate racemase.     

Staphylococcus haemolyticus contains two D-glutamic acid biosynthetic activities, a glutamate racemase and a D-amino acid transaminase.

Two D-glutamic acid biosynthetic activities, glutamate racemase and D-amino acid transaminase, have been described previously for bacteria. To date, no bacterial species has been reported to possess both activities. Genetic complementation studies using Escherichia coli WM335, a D-glutamic acid auxotroph, and cloned chromosomal DNA fragments from Staphylococcus haemolyticus revealed two distinct DNA fragments containing open reading frames which, when present, allowed growth on medium without exogenous D-glutamic acid. Amino acid sequences of the two open reading frames derived from the DNA nucleotide sequences indicated extensive identity with the amino acid sequence of Pediococcus pentosaceous glutamate racemase in one case and with that of the D-amino acid transaminase of Bacillus spp. in the second case. Enzymatic assays of lysates of E. coli WM335 strains containing either the cloned staphylococcal racemase or transminase verified the identities of these activities. Subsequent DNA hybridization experiments indicated that Staphylococcus aureus, in addition to S. haemolyticus, contained homologous chromosomal DNA for each of these genes. These data suggest that S. haemolyticus, and probably S. aureus, contains genes for two D-glutamic acid biosynthetic activities, a glutamate racemase (dga gene) and a D-amino acid transaminase (dat gene).     

Isolation of the murI gene from Brevibacterium lactofermentum ATCC 13869 encoding d-glutamate racemase

The murI gene encoding D-glutamate racemase plays an important role in the biosynthesis of D-glutamic acid, an essential component of cell wall peptidoglycan of almost all eubacteria. A DNA fragment that could rescue the auxotrophy of D-glutamic acid in the Escherichia coli murI mutant strain WM335 was isolated from Brevibacterium lactofermentum ATCC 13869 belonging to the coryneform bacteria. DNA sequencing reveals that it encodes a protein of 284 amino acid residues, which shows a high level of homology with D-glutamate racemases from several other bacteria.     

Characterization of yrpC gene product of Bacillus subtilis IFO 3336 as glutamate racemase isozyme.

Glr, the glutamate racemase of Bacillus subtilis (formerly Bacillus natto) IFO 3336 encoded by the glr gene, and YrpC, a protein encoded by the yrpC gene, which is located at a different locus from that of the glr gene in the B. subtilis genome, share a high sequence similarity. The yrpC gene complemented the D-glutamate auxotrophy of Escherichia coli WM335 cells defective in the glutamate racemase gene. Glutamate racemase activity was found in the extracts of E. coli WM335 clone cells harboring a plasmid, pYRPC1, carrying its gene. Thus, the yrpC gene encodes an isozyme of glutamate racemase of B. subtilis IFO 3336. YrpC is mostly found in an inactive inclusion body in E. coli JM109/pYRPC1 cells. YrpC was solubilized readily, but glutamate racemase activity was only slightly restored. We purified YrpC from the extracts of E. coli JM109/pYRPC2 cells using a Glutathione S-transferase Gene Fusion System to characterize it. YrpC is a monomeric protein and contains no cofactors, like Glr. Enzymological properties of YrpC, such as the substrate specificity and optimum pH, are also similar to those of Glr. The thermostability of YrpC, however, is considerably lower than that of Glr. In addition, YrpC showed higher affinity and lower catalytic efficiency for L-glutamate than Glr. This is the first example showing the occurrence and properties of a glutamate racemase isozyme.     

Genetic Analysis of the Glutamate Permease in Escherichia coli K-12

The glutamate permeation system in Escherichia coli K-12 consists of three genes: gltC, gltS, and gltR. The genes gltC and gltS are very closely linked, and are located between the pyrE and tna loci, in the following order: tna, gltC, gltS, pyrE; gltR is located near the metA gene. The three glt genes constitute a regulatory system in which gltR is the regulator gene responsible for the formation of repressor, gltS is the structural gene of the glutamate permease, and gltC is most probably the operator locus. The synthesis of glutamate permease is partially repressed in wild-type K-12 strains, resulting in the inability of these strains to utilize glutamate as the sole source of carbon. Derepression due to mutation at the gltC locus enables growth on glutamate as a carbon source both at 30 C and at 42 C. Temperature-sensitive gltR mutants capable of utilizing glutamate for growth at 42 C but not at 30 C were found to be derepressed for glutamate permease when grown at 42 C and partially repressed (wild-type phenotype) upon growth at 30 C. These mutants produce an altered thermolabile repressor which can be inactivated by mild heat treatment (10 min at 44 C) in the absence of growth.     

Glutamate racemase is an endogenous DNA gyrase inhibitor

Almost all bacteria possess glutamate racemase to synthesize d-glutamate as an essential component of peptidoglycans in the cell walls. The enforced production of glutamate racemase, however, resulted in suppression of cell proliferation. In the Escherichia coli JM109/pGR3 clone, the overproducer of glutamate racemase, the copy number (i.e. replication efficiency) of plasmid DNA declined dramatically, whereas the E. coli WM335 mutant that is defective in the gene of glutamate racemase showed little genetic competency. The comparatively low and high activities for DNA supercoiling were contained in the E. coli JM109/pGR3 and WM335 cells, respectively. Furthermore, we found that the DNA gyrase of E. coli was modulated by the glutamate racemase of E. coli in the presence of UDP-N-acetylmuramyl-l-alanine, which is a peptidoglycan precursor and functions as an absolute activator for the racemase. This is the first finding of the enzyme protein participating in both d-amino acid metabolism and DNA processing.     

Molecular cloning of gltS and gltP, which encode glutamate carriers of Escherichia coli B.

Two genes encoding distinct glutamate carrier proteins of Escherichia coli B were cloned into an E. coli K-12 strain by using a cosmid vector, pHC79. One of them was the gltS gene coding for a glutamate carrier of an Na+-dependent, binding protein-independent, and glutamate-specific transport system. The content of the glutamate carrier was amplified about 25-fold in the cytoplasmic membranes from a gltS-amplified strain. The gltS gene was located in a 3.2-kilobase EcoRI-MluI fragment, and the gene product was identified as a membrane protein with an apparent Mr of 35,000 in a minicell system. A gene designated gltP was also cloned. The transport activity of the gltP system in cytoplasmic membrane vesicles from a gltP-amplified strain was driven by respiratory substrates and was independent of the concentrations of Na+, K+, and Li+. An uncoupler, carbonylcyanide m-chlorophenylhydrazone, completely inhibited the transport activities of both systems, whereas an ionophore, monensin, inhibited only that of the gltS system. The Kt value for glutamate was 11 microM in the gltP system and 3.5 microM in the gltS system. L-Aspartate inhibited the glutamate transport of the gltP system but not that of the gltS system. Aspartate was taken up actively by membrane vesicles from the gltP-amplified strain, although no aspartate uptake activity was detected in membrane vesicles from a wild-type E. coli strain. These results suggest that gltP is a structural gene for a carrier protein of an Na+-independent, binding protein-independent glutamate-aspartate transport system.     

Genetic Analysis of the γ-Aminobutyrate Utilization Pathway in Escherichia coli K-12

The control mutation that results in a concomitant severalfold increase in the activities of gamma-aminobutyrate-alpha-ketoglutarate transaminase (GSST, EC 2.6.1.19) and succinic semialdehyde dehydrogenase (SSDH, EC 1.2.1.16), leading to the acquisition of the ability to utilize gamma-aminobutyrate (GABA) as the sole source of nitrogen by Escherichia coli K-12 mutants, was mapped by mating and transduction with P1kc. The locus affected, gabC, is approximately 48% co-transduced with the thyA gene, located at min 55 of the E. coli K-12 chromosome. The structural gene of the first enzyme in the GABA pathway, GSST, was mapped by interrupted mating, using one of the GSST-less mutants, DB742, isolated in this work. The mutated locus, gabT, is situated at about min 73 of the E. coli chromosome, close to the gltC gene. Genetic evidence concerning the sensitivity of the enzymes of the GABA pathway to catabolite repression under different physiological conditions suggests that the two structural genes of the GABA regulon do not constitute one operon.     

A Salmonella typhimurium genetic locus which confers copper tolerance on copper-sensitive mutants of Escherichia coli.

Three distinct clones from a Salmonella typhimurium genomic library were identified which suppressed the copper-sensitive (Cu(s)) phenotype of cutF mutants of Escherichia coli. One of these clones, pCUTFS2, also increased the copper tolerance of cutA, -C, and -E mutants, as well as that of a lipoprotein diacylglyceryl transferase (lgt) mutant of E. coli. Characterization of pCUTFS2 revealed that the genes responsible for suppression of copper sensitivity (scs) reside on a 4.36-kb DNA fragment located near 25.4 min on the S. typhimurium genome. Sequence analysis of this fragment revealed four open reading frames (ORF120, ORF627, ORF207, and ORF168) that were organized into two operons. One operon consisted of a single gene, scsA (ORF120), whereas the other operon contained the genes scsB (ORF627), scsC (ORF207), and scsD (ORF168). Comparison of the deduced amino acid sequences of the predicted gene products showed that ScsB, ScsC, and ScsD have significant homology to thiol-disulfide interchange proteins (CutA2, DipZ, CycZ, and DsbD) from E. coli and Haemophilus influenzae, to an outer membrane protein (Com1) from Coxiella burnetii, and to thioredoxin and thioredoxin-like proteins, respectively. The two operons were subcloned on compatible plasmids, and complementation analyses indicated that all four proteins are required for the increased copper tolerance of E. coli mutants. In addition, the scs locus also restored lipoprotein modification in lgt mutants of E. coli. Sequence analyses of the S. typhimurium scs genes and adjacent DNAs revealed that the scs locus is flanked by genes with high homology to the cbpA (predicted curved DNA-binding protein) and agp (acid glucose phosphatase) genes of E. coli located at 22.90 min (1,062.07 kb) and 22.95 min (1,064.8 kb) of the E. coli chromosome, respectively. However, examination of the E. coli chromosome revealed that these genes are absent at this locus and no evidence has thus been obtained for the occurrence of the scs locus elsewhere on the genome.     

chpA and chpB, Escherichia coli chromosomal homologs of the pem locus responsible for stable maintenance of plasmid R100.

The pem locus is responsible for stable maintenance of plasmid R100 and consists of two genes, pemI and pemK. The pemK gene product is a growth inhibitor, while the pemI gene product is a suppressor of this inhibitory function. We found that the PemI amino acid sequence is homologous to two open reading frames from Escherichia coli called mazE and orf-83, which are located at 60 and 100 min on the chromosome, respectively. We cloned and sequenced these loci and found additional open reading frames, one downstream of each pemI homolog, both of which encode proteins homologous to PemK. The pem locus homolog at 60 min was named chpA and consists of two genes, chpAI and chpAK; the other, at 100 min, was named chpB and consists of two genes, chpBI and chpBK. The distal portion of chpBK was found to be adjacent to the ppa gene that encodes pyrophosphatase, whose map position had not been previously determined. We then demonstrated that the chpAK and chpBK genes encode growth inhibitors, while the chpAI and chpBI genes encode suppressors for the inhibitory function of the ChpAK and ChpBK proteins, respectively. These E. coli pem locus homologs may be involved in regulation of cell growth.     

O acetylation of the enterobacterial common antigen polysaccharide is catalyzed by the product of the yiaH gene of Escherichia coli K-12

The carbohydrate component of the enterobacterial common antigen (ECA) of Escherichia coli K-12 occurs primarily as a water-soluble cyclic polysaccharide located in the periplasm (ECA(CYC)) and as a phosphoglyceride-linked linear polysaccharide located on the cell surface (ECA(PG)). The polysaccharides of both forms are comprised of the amino sugars N-acetyl-D-glucosamine (GlcNAc), N-acetyl-D-mannosaminuronic acid (ManNAcA), and 4-acetamido-4,6-dideoxy-D-galactose (Fuc4NAc). These amino sugars are linked to one another to form trisaccharide repeat units with the structure -->3-alpha-D-Fuc4NAc-(1-->4)-beta-D-ManNAcA-(1-->4)-alpha-D-GlcNAc-(1-->. The hydroxyl group in the 6 position of the GlcNAc residues of both ECA(CYC) and ECA(PG) are nonstoichiometrically esterified with acetyl groups. Random transposon insertion mutagenesis of E. coli K-12 resulted in the generation of a mutant defective in the incorporation of O-acetyl groups into both ECA(CYC) and ECA(PG). This defect was found to be due to an insertion of the transposon into the yiaH locus, a putative gene of unknown function located at 80.26 min on the E. coli chromosomal map. Bioinformatic analyses of the predicted yiaH gene product indicate that it is an integral inner membrane protein that is a member of an acyltransferase family of enzymes found in a wide variety of organisms. The results of biochemical and genetic experiments presented here strongly support the conclusion that yiaH encodes the O-acetyltransferase responsible for the incorporation of O-acetyl groups into both ECA(CYC) and ECA(PG). Accordingly, we propose that this gene be designated wecH.     

Use of homocysteic acid for selecting mutants at the gltS locus of Escherichia coli K12

L-Homocysteic acid is toxic to Escherichia coli K12. Sensitivity to this compound is higher in cells which can utilize glutamate as sole carbon source via the Na+-dependent glutamate transport system. Such cells become resistant by mutation at the gltS locus. Sensitivity of both wild-type and glutamate-utilizing strains is greater if cells are growing on acetate as compared with glucose as major carbon source.     

Identification of new genes regulated by the marRAB operon in Escherichia coli.

Random TnphoA and TnlacZ translational fusions were introduced into an Escherichia coli strain with a deletion of the multiple antibiotic resistance (mar) locus, complemented in trans by a temperature-sensitive plasmid bearing the mar locus with a constitutively expressed mar operon. Five gene fusions (two with lacZ and three with phoA) regulated by the mar operon were identified by increased or decreased marker enzyme activity following loss of the complementary plasmid at the restrictive temperature. Expression of LacZ from both lacZ fusions increased in the presence of the mar operon; expression from the three phoA fusions was represented by the mar operon. The lacZ fusions were mapped at 31.5 and 14 min on the Escherichia coli chromosome. One of the phoA fusions was located at 51.6 min while the two others mapped at 77 min. Cloning and sequencing of a portion of the fused genes showed all of them to be different. The phoA fusions at 77 min were located in a recently identified gene, slp, a lipoprotein of unknown function (D.M. Alexander and A. C. St. John, Mol. Microb. 11:1059-1071, 1994). The others showed no homology with any known genes of E. coli. The insertions caused small but reproducible changes in the antibiotic susceptibility profile. This approach has enabled the identification of new genes in E. coli which are regulated by the marRAB operon and involved in the Mar phenotype.     

The murI gene of Escherichia coli is an essential gene that encodes a glutamate racemase activity.

The murI gene of Escherichia coli was recently identified on the basis of its ability to complement the only mutant requiring D-glutamic acid for growth that had been described to date: strain WM335 of E. coli B/r (P. Doublet, J. van Heijenoort, and D. Mengin-Lecreulx, J. Bacteriol. 174:5772-5779, 1992). We report experiments of insertional mutagenesis of the murI gene which demonstrate that this gene is essential for the biosynthesis of D-glutamic acid, one of the specific components of cell wall peptidoglycan. A special strategy was used for the construction of strains with a disrupted copy of murI, because of a limited capability of E. coli strains grown in rich medium to internalize D-glutamic acid. The murI gene product was overproduced and identified as a glutamate racemase activity. UDP-N-acetylmuramoyl-L-alanine (UDP-MurNAc-L-Ala), which is the nucleotide substrate of the D-glutamic-acid-adding enzyme (the murD gene product) catalyzing the subsequent step in the pathway for peptidoglycan synthesis, appears to be an effector of the racemase activity.     

Mutations in the Escherichia coli fnr and tgt genes: control of molybdate reductase activity and the cytochrome d complex by fnr.

In eubacteria, the tRNA transglycosylase (Tgt) in specific tRNAs exchanges a guanine in the anticodon for 7-aminomethyl-7-deazaguanine, which is finally converted to queuosine. The tgt gene of Escherichia coli has been mapped at 9 min on the genome, and mutant pairs containing an intact or mutated tgt allele were obtained after transduction of the tgt locus by P1 bacteriophages into a genetically defined E. coli strain (S. Noguchi, Y. Nishimura, Y. Hirota, and S. Nishimura, J. Biol. Chem. 257:6544-6550, 1982). These tgt mutants grew anerobically with fumarate as an electron acceptor, while nitrate or trimethylamine N-oxide could not be reduced. Furthermore, molybdate reductase activity was almost lacking and the characteristic absorption maxima, corresponding to cytochrome a1 and the cytochrome d complex, were not detectable in low-temperature reduced-minus-oxidized difference spectra in anaerobically grown cells. Transduction of the mutated tgt locus into another E. coli recipient resulted in tgt mutants without anaerobic defects. Transformation of the original tgt mutants with an fnr gene-containing plasmid reversed the anaerobic defects. Clearly, the original tgt mutants harbor a second mutation, affecting the anaerobic regulator protein Fnr. The results suggest that fnr is involved in anaerobic control of components of the cytochrome d complex and of the redox system that transfers electrons to molybdate. F' plasmids containing a fused lacI-lacZ gene with the nonsense codon UAG at different positions in the lacI part were transferred to E. coli strains with a mutated or nonmutated tgt locus but intact in fnr. A twofold increase in the frequency of incorrect readthrough of the UAG codon, dependent on the codon context, was observed in the tgt mutant and is suggested to be caused by a tRNA(Tyr) with G in place of queuosine.     

Genetic Analysis of Diaminopimelic Acid- and Lysine-Requiring Mutants of Escherichia coli

Several diaminopimelic acid (DAP)- and lysine-requiring mutants of Escherichia coli were isolated and studied by genetic, physiological, and biochemical means. The genes concerned with DAP-lysine synthesis map at several different sites on the E. coli chromosome and, therefore, do not constitute a single operon. Three separate loci affecting DAP synthesis are located in the 0 to 2.5 min region of the genetic map. The order of the loci in this region is thr-dapB-pyrA-ara-leu-pan-dapC-tonA-dapD. Two additional DAP genes map in the region between min 47 and 48, with the gene order being gua-dapA-dapE-ctr. The lys locus at min 55 determines the synthesis of the enzyme DAP decarboxylase, which catalyzes the conversion of DAP into lysine. The order of the genes in this region is serA-lysA-thyA.     

A genetic locus for the GltII-glutamate transport system in Escherichia coli

Growth of Escherichia coli on glutamate as sole carbon source only occurs in strains carrying mutations that increase the expression of genes encoding glutamate transport systems. From an analysis of mutants able to grow on glutamate we have identified a genetic locus that when mutated elevates the expression of the GltII glutamate/aspartate transport system. The mutants exhibit increased sensitivity to the toxic aspartate analogues cysteate and DL-threo-beta-hydroxyaspartate. Data from the analysis of mutants that are impaired in this transport activity are consistent with the presence of the structural gene for the transport system at the same genetic locus. The locus was mapped by P1 transduction to a region of the E. coli chromosome lying at approximately 92.5 min on the E. coli genetic map.     

Multiple genes for membrane-bound phosphatases in Escherichia coli and their action on phospholipid precursors.

We have devised a coupled radiochemical assay for detecting phosphatidylglycerolphosphate (PGP) phosphatase activity in Escherichia coli colonies immobilized on filter paper. There appeared to be at least two enzymes capable of dephosphorylating PGP, as judged by the characterization of mutations in two genes designated pgpA and pgpB. The former is located near min 10 and is cotransducible with proC and dnaZ. The latter is situated near min 28 and is closely linked to cysB. The available mutant alleles of pgpA reduced the specific activity of PGP phosphatase in crude extracts by about 30%, but they had no effect on phosphatidic acid (or lysophosphatidic acid) phosphatase. Mutants altered in the pgpB locus inactivated most of the residual PGP phosphatase activity present in single-step pgpA mutants, and the level of phosphatidic acid phosphatase was also reduced 20-fold. The available mutations in pgpA and pgpB elevated the cellular PGP pool by 10- to 50-fold. The maximal PGP levels never exceeded 5%, and these strains were not conditionally lethal. The simplest interpretation of our findings is that there are at least two membrane-associated phosphatases in E. coli, both distinct from alkaline phosphatase. The pgpA gene product is specific for PGP, whereas the pgpB gene product also acts on phosphatidic acid and lysophosphatidic acid.