Homology of lysS and lysU, the two Escherichia coli genes encoding distinct lysyl-tRNA synthetase species.

In Escherichia coli, two distinct lysyl-tRNA synthetase species are encoded by two genes: the constitutive lysS gene and the thermoinducible lysU gene. These two genes have been isolated and sequenced. Their nucleotide and deduced amino acid sequences show 79% and 88% identity, respectively. Codon usage analysis indicates the lysS product being more efficiently translated than the lysU one. In addition, the lysS sequence exactly coincides with the sequence of herC, a gene which is part of the prfB-herC operon. In contrast to the recent proposal of Gampel and Tzagoloff (1989, Proc. Natl. Acad. Sci. USA 86, 6023-6027), the lysU sequence is distinct from the open reading frame located adjacent to frdA, although large homologies are shared by these two genes.     

Roles of the two lysyl-tRNA synthetases of Escherichia coli: analysis of nucleotide sequences and mutant behavior.

The complete nucleotide sequence of lysU, the gene for the heat-inducible lysyl-tRNA synthetase of Escherichia coli, was determined and compared with the published sequence of lysS (herC), the gene for the constitutive lysyl-tRNA synthetase. These unlinked genes were found to be identical over 72% of their lengths. The deduced amino acid sequences of the respective gene products, LysU and LysS, were identical over 85% and similar over 92% of their lengths. Accumulation of high levels of LysU during growth of strains carrying the wild-type allele of lysU on multicopy plasmids had no observable effect on growth or on the synthesis of LysS. A lysU deletion strain was constructed and was shown to grow normally at low temperature (28 degrees C) but poorly at 44 degrees C; the slow growth (45% of normal) at elevated temperature was fully reversed by plasmids bearing wild-type lysU. The implications of these findings for the existence of two aminoacyl-tRNA synthetases for lysine are discussed.     

Differential translation of the genes encoding the proton-translocating ATPase of Escherichia coli

Translation of the gene for the b subunit of the Escherichia coli proton-translocating ATPase has been examined. Oligonucleotide-directed site-specific mutagenesis was used to mutate certain nucleotides in the intergenic region between uncE (c) and uncF (b). One of the changes was predicted to lower the stability of a proposed stem structure which blocked the ribosome binding site of the uncF mRNA segment. The result of the mutation is a nearly 3-fold increase in the rate of synthesis of the b polypeptide. Another mutation was introduced which changed the initiation codon for uncF from GUG to AUG. This change resulted in an approximately 2-fold increase in the synthesis rate of the b polypeptide. These results suggest that secondary structure in the mRNA and the use of a less efficient initiation codon play a role in restricting translation initiation of the uncF mRNA segment. These mechanisms may, in part, explain how the polypeptides of the ATPase complex are synthesized in approximately the same relative amounts as they appear in the assembled complex.     

Genetic analysis of mutations that compensate for loss of Escherichia coli DNA topoisomerase I

A transposon Tn10 insertion in topA, the structural gene of Escherichia coli DNA topoisomerase I, behaves as an excluded marker in genetic crosses with many strains of E. coli. However, derivative strains that accept this mutant topA allele are readily selected. We show that many of these topA mutant strains contain additional mutations that compensate for the loss of DNA topoisomerase I. Genetic methods for mapping and manipulating such compensatory mutations are described. These methods include a plate-mating test for the ability of strains to accept a topA::Tn10 allele and a powerful indirect selection for transferring compensatory mutations from male strains into non-compensatory female strains. One collection of spontaneous compensatory mutants is analyzed in detail and is shown to include compensatory mutations at three distinct loci: gyrA and gyrB, the genes that encode the subunits of DNA gyrase, and a previously unidentified locus near tolC. Mutations at this third locus, referred to as toc (topoisomerase one compensatory) mutations, do not behave as point mutations in transductional crosses and do not result in lowered DNA gyrase activity. These results show that wild-type strains of E. coli require DNA topoisomerase I, and at least one class of compensatory mutations can relieve this requirement by a mechanism other than reduction of DNA gyrase activity.     

The genes encoding the two carboxyltransferase subunits of Escherichia coli acetyl-CoA carboxylase.

We report characterization of the component proteins and molecular cloning of the genes encoding the two subunits of the carboxyltransferase component of the Escherichia coli acetyl-CoA carboxylase. Peptide mapping of the purified enzyme component indicates that the carboxyltransferase component is a complex of two nonidentical subunits, a 35-kDa alpha subunit and a 33-kDa beta subunit. The alpha subunit gene encodes a protein of 319 residues and is located immediately downstream of the polC gene (min 4.3 of the E. coli genetic map). The deduced amino acid composition, molecular mass, and amino acid sequence match those determined for the purified alpha subunit. Six sequenced internal peptides also match the deduced sequence. The amino-terminal sequence of the beta subunit was found within a previously identified open reading frame of unknown function called dedB and usg (min 50 of the E. coli genetic map) which encodes a protein of 304 residues. Comparative peptide mapping also indicates that the dedB/usg gene encodes the beta subunit. Moreover, the deduced molecular mass and amino acid composition of the dedB/usg-encoded protein closely match those determined for the beta subunit. The deduced amino acid sequences of alpha and beta subunits show marked sequence similarities to the COOH-terminal half and the NH2-terminal halves, respectively, of the rat propionyl-CoA carboxylase, a biotin-dependent carboxylase that catalyzes a similar carboxyltransferase reaction reaction. Several conserved regions which may function as CoA-binding sites are noted.     

Evidence for a new Escherichia coli protein resembling a lysyl-tRNA synthetase.

The amino acid sequence deduced from the nucleotide sequence of an open reading frame adjacent to the frdA gene of Escherichia coli shows 30.5% identity with the C terminus of Escherichia coli lysyl-tRNA synthetases. The three motifs characteristic of aminoacyl-tRNA synthetases of class 2 are recognizable within this sequence.     

Expression in Escherichia coli of two mutated genes encoding the cholera toxin B subunit

To allow subsequent genetically mediated fusion of foreign antigens to cholera toxin B subunit (CTB), two mutated CTB encoding genes (ctxB) were constructed and overexpressed in Escherichia coli. The signal peptide coding sequence was deleted and restriction sites were created at both ends of the modified sequence. Both synthesized CTBs contain additional amino acid(s) at the N terminus (one and three). They were purified as insoluble products and refolded into the natural pentameric CTB structure by a denaturation-renaturation cycle. After renaturation, both recombinant proteins recovered CTB antigenicity and the ability to bind to GM1 gangliosides, as shown by in vitro analysis. Preliminary data indicated that both properties were unaltered by fusion of a foreign peptide to the mutated CTBs.     

Effect of a null mutation in the priA gene on radioresistance of Escherichia coli

According to Kogoma's model of DNA recombination by replication, the PriA protein is involved in the RecBCD pathway of double-strand break (DSB) repair, which is associated with extensive DNA degradation, at the stage of primosome assembly in D-loops (intermediates of strand exchange at the ends of DSB) for the subsequent switch to DSB-induced DNA resynthesis. Comparable data on possible involvement of the PriA protein in the repair of gamma-ray-induced lethal lesions in cells of the wild-type strain of Escherichia coli (strain AB1157) and in two radiation-resistant mutants Gamr445 and Gamr444 were obtained. In all the three strains examined, the null priA2::kan mutation in the structural priA gene was shown to markedly enhance the radiation sensitivity, causing a two- to threefold increase in the slopes of linear dose-survival curves. In the AB1157 strain, the inactivation of PriA is manifested most clearly in the range of low doses (up to 0.15 kGy) when the priA2::kan mutation had only a slight effect on the radiation resistance of Gamr mutants. It can be assumed that, in these mutants with a decreased level of postradiation DNA degradation, the PriA-dependent RecBCD pathway of DSB repair associated with extensive DNA resynthesis is not essential for the repair of lethal lesions at low doses. However, this pathway becomes crucial at higher doses (> 0.5 kGy) even for radiation-resistant strains, especially for the most resistant Gamr444 mutant.     

Role of lysyl-tRNA in the regulation of lysine biosynthesis in Escherichia coli K12.

A mutant of lysyl-tRNA synthetase has been isolated in Escherichia coli K12. With this strain the Kmapp for lysine is 25 fold higher than with the parental strain. The percentage of charged tRNAlys in vivo is only 7 per cent (as against 65 per cent with HFR H). Under these conditions no derepression of synthesis is observed for three lysine biosynthetic enzymes (AK III, ASA-dehydrogenase, DAP-decarboxylase) ; a partial derepression is obtained in the case of the dhdp-reductase. Thus lysyl-tRNA does not act as the only corepressor molecule in the lysine regulon.     

Suppressor genes of a dnaA temperature sensitive mutation in Escherichia coli

Summary Recombinant plasmids were constructed from EcoRI digests of Escherichia coli chromosomal DNA and pMB9 DNA by selecting for suppression of a dnaA–T46 temperature-sensitive mutation. Two types of plasmid capable of suppressing the dnaA mutation were isolated. They did not carry any genetic markers around dnaA and physical mapping with various restriction enzymes showed that neither of the plasmids contained the dnaA gene. One plasmid, pYT47, was characterized further and the protein responsible for the suppression was identified by two-dimensional gel electrophoresis. The molecular weight of the suppressor protein was about 68 Kdal and thus is clearly different from the dnaA gene product.     

Inorganic phosphate transport in Escherichia coli: involvement of two genes which play a role in alkaline phosphatase regulation

Two classes of alkaline phosphatase constitutive mutations which comprise the original phoS locus (genes phoS and phoT) on the Escherichia coli genome have been implicated in the regulation of alkaline phosphatase synthesis. When these mutations were introduced into a strain dependent on a single system, the pst system, for inorganic phosphate (P(i)) transport, profound changes in P(i) transport were observed. The phoT mutations led to a complete P(i) (-) phenotype in this background, and no activity of the pst system could be detected. The introduction of the phoS mutations changed the specificity of the pst system so that arsenate became growth inhibitory. Changes in the phosphate source led to changes in the levels of constitutive alkaline phosphatase synthesis found in phoS and phoT mutants. When glucose-6-phosphate or l-alpha-glycerophosphate was supplied as the sole source of phosphate, phoT mutants showed a 3- to 15- fold reduction in constitutive alkaline phosphatase synthesis when compared to the maximal levels found in limiting P(i) media. However, these levels were still 100 times greater than the basal level of alkaline phosphatase synthesized in wild-type strains under these conditions. The phoS mutants showed only a two- to threefold reduction when grown with organic phosphate sources. The properties of the phoT mutants selected on the basis of constitutive alkaline phosphatase synthesis were similar in many respects to those of pst mutants selected for resistance to growth inhibition caused by arsenate. It is suggested that the phoS and phoT genes are primarily involved in P(i) transport and, as a result of this function, play a role in the regulation of alkaline phosphatase synthesis.     

Conditional lethal amber mutations in essential Escherichia coli genes

The essential genes of microorganisms encode biological functions important for survival and thus tend to be of high scientific interest. Drugs that interfere with essential functions are likely to be interesting candidates for antimicrobials. However, these genes are hard to study genetically because knockout mutations in them are by definition inviable. We recently described a conditional mutation system in Escherichia coli that uses a plasmid to produce an amber suppressor tRNA regulated by the arabinose promoter. This suppressor was used here in the construction of amber mutations in seven essential E. coli genes. Amber stop codons were introduced as "tagalong" mutations in the flanking DNA of a downstream antibiotic resistance marker by lambda red recombination. The drug marker was removed by expression of I-SceI meganuclease, leaving a markerless mutation. We demonstrate the method with the genes frr, gcpE, lpxC, map, murA, ppa, and rpsA. We were unable to isolate an amber mutation in ftsZ. Kinetics of cell death and morphological changes were measured following removal of arabinose. As expected given the wide range of cellular mechanisms represented, different mutants showed widely different death curves. All of the mutations were bactericidal except the mutation in gcpE, which was bacteriostatic. The strain carrying an amber mutation in murA was by far the most sensitive, showing rapid killing in nonpermissive medium. The MurA protein is critical for peptidoglycan synthesis and is the target for the antibiotic fosfomycin. Such experiments may inexpensively provide valuable information for the identification and prioritization of targets for antibiotic development.     

Independent regulation of two genes in Escherichia coli by tetracyclines and Tet repressor variants

We report a regulation system in Escherichia coli for independent regulation of two distinct reporter genes by application of Tet repressors with different specificities. One Tet repressor variant comprises wild-type tet operator (tetO) recognition and exclusive induction with the novel inducer 4-dedimethylamino-anhydrotetracycline. The other Tet repressor variant shows tetO-4C recognition and induction with tetracycline. We demonstrate that both variants are independently active in vivo and allow selective regulation of two genes in the same cell without any cross talk.