Genetic studies of the ribosomal proteins in Escherichia coli. 7. Mapping of several ribosomal protein components by transduction experiments between different strains of Escherichia coli

Summary Two 50s (50-10 and 50-12) and two 30s (30-4 and 30-7) ribosomal proteins could be distinguished between Shigella dysenteriae Sh/s and Escherichia coli K-12 JC411 with CMC column chromatography. On the other hand, E. coli K-12 AT2472 was shown to have a 30s ribosomal protein, 30-6(AT), which is specific to this strain and distinguishable from 30-6 of other E. coli K-12 strains. Transduction experiments by phage Plkc between Sh. dysenteriae Sh/s and E. coli ATSPCO1, a spectinomycin resistant mutant derived from AT2472 in which the 30-4 protein is altered, indicated that the genes specifying the above five ribosomal protein components are located in the streptomycin region on the E. coli chromosome.The gene order for three 50s (50-8, 50-10 and 50-12) and three 30s [str (30-?), 30-4 and 30-6] ribosomal proteins on the chromosome was determined by transduction technique between Sh. dysenteriae Sh/s and E. coli ATSPC01, between E. coli ATSPC01 and E. coli ER05 (an erythromycin resistant strain in which the 50-8 protein is altered), and between Sh. dysenteriae Sh/s and E. coli ERSPC14 (str ^s spc ^r ery ^r), respectively. It was found that these protein genes are arranged on the chromosome in the order of str (30-?)-30-4-30-6-50-8-50-10-50-12.     

A general method for the construction of Escherichia coli mutants by homologous recombination and plasmid segregation

Summary A technique is presented by which mutations can be introduced into the Escherichia coli chromosome by gene replacement between the chromosome and a plasmid carrying the mutant gene. The segregational instability of plasmids in E. coli is used with high efficiency to isolate E. coli mutants. The method should be applicable to construction of mutants for any E. coli chromosomal gene provided it is dispensable, and for any E. coli strain provided it is capable of homologous recombination. The use of the method was demonstrated by constructing E. coli mutants for the glycogen branching enzyme gene (glgB) and the -galactosidase gene (lacZ). The results show that recombination occurs via a reciprocal mechanism indicating that the method should, in a slightly modified form, also be useful in transferring chromosomal mutations onto multicopy plasmids in vivo.     

A novel genetic island of meningitic Escherichia coli K1 containing the ibeA invasion gene (GimA): functional annotation and carbon-source-regulated invasion of human brain microvascular endothelial cells

The IbeA (ibe10) gene is an invasion determinant contributing to E. coli K1 invasion of the blood-brain barrier. This gene has been cloned and characterized from the chromosome of an invasive cerebrospinal fluid isolate of E. coli K1, strain RS218 (018:K1: H7). In the present study, a genetic island of meningitic E. coli containing ibeA (GimA) has been identified. A 20.3-kb genomic DNA island unique to E. coli K1 strains has been cloned and sequenced from an RS218 E. coli K1 genomic DNA library. Fourteen new genes have been identified in addition to the ibeA. The DNA sequence analysis indicated that the ibeA gene cluster was localized to the 98 min region and consisted of four operons, ptnIPKC, cglDTEC, gcxKRCI and ibeRAT. The G+C content (46.2%) of unique regions of the island is substantially different from that (50.8%) of the rest of the E. coli chromosome. By computer-assisted analysis of the sequences with DNA and protein databases (GenBank and PROSITE databases), the functions of the gene products could be anticipated, and were assigned to the functional categories of proteins relating to carbon source metabolism and substrate transportation. Glucose was shown to enhance E. coli penetration of human brain microvascular endothelial cells and exogenous cAMP was able to block the stimulating effect of glucose, suggesting that catabolic regulation may play a role in control of E. coli K1 invasion gene expression. Our data suggest that this genetic island may contribute to E. coli invasion of the blood-brain barrier through a carbon-source-regulated process. Electronic Publication     

Suppressors of temperature-sensitive mutations in a ribosomal protein gene, rpsL (S12), of Escherichia coli K12

Summary Temperature-sensitive (ts) mutations were isolated within a ribosomal protein gene (rpsL) of Escherichia coli K12. Mutations were mapped by complementation using various transducing phages and plasmids carrying the rpsL gene, having either a normal or a defective promoter for the rpsL operon. One of these mutations, ts118, resulted in a mutant S12 protein which behaved differently from the wild-type S12 on CM-cellulose column chromatography. Suppressors of these ts mutations were isolated and characterized; one was found to be a mutation of a nonribosomal protein gene which was closely linked to the RNAase III gene on the E. coli chromosome. This suppressor, which was recessive to its wild-type allele, was cloned into a transducing phage and mapped finely. A series of cold-sensitive mutations, affecting the assembly of ribosomes at 20°C, was isolated within the purL to nadB region of the E. coli chromosome and one group, named rbaA, mapped at the same locus as the suppressor mutation, showing close linkage to the RNAase III gene.     

Conjugal Transfer of Plasmid DNA fromEscherichia colito Enterococci: A Method to Make Insertion Mutations

Shuttle vector pAT18 was transferred by conjugation fromEscherichia coliS17-1 toEnterococcus faecalisOG1RF andEnterococcus faeciumSE34. Transfer was mediated by the transfer functions of plasmid RK2 inE. coliS17-1 and the origin of conjugal transfer (oriT) located on pAT18. TheoriTsequence was then inserted into two plasmids to generate vectors pTEX5235 and pTEX5236. These two vectors cannot replicate in gram-positive bacteria and can be used to make insertion mutants in gram-positive bacteria. An internal sequence from an autolysin gene ofE. faecalisOG1RF was cloned into pTEX5235 and transferred by conjugation fromE. coliS17-1 toE. faecalisOG1RF. The plasmid was found to integrate into the chromosome of OG1RF by a single crossover event, resulting in a disrupted autolysin gene. A cosmid carrying the pyrimidine gene cluster fromE. faecalis,with a transposon insertion inpyrC,was also transferred fromE. coliS17-1 toE. faecalisOG1RF. After selection for the transposon, it was found to have recombined into the recipient chromosome by a double crossover between the cosmid and the chromosome of OG1RF. This resulted in apyrCknockout mutant showing an auxotrophic phenotype.     

DNA sequencing of the Escherichia coli ribonuclease III gene and its mutations

Summary A 0.7 kb DNA fragment of the Escherichia coli K12 chromosome was shown to contain the structural gene for RNAse III (rnc). The DNA sequence of the gene was determined and its alteration in an RNAse III defective mutant, AB301-105, was identified. DNA sequence analysis also showed that a secondary-site suppressor of a temperature-sensitive mutation in the E. coli ribosomal protein gene, rpsL, occurred within the rnc gene, providing genetic evidence for the interaction of ribosomal proteins with RNAse III, which in turn acts on the nascent ribosomal RNA during assembly of ribosomes in E. coli.     

Cloning and sequencing of an Escherichia coli K12 gene which encodes a polypeptide having similarity to the human ferritin H subunit

Summary Using lambda phage clones containing segments of the Escherichia coli K12 chromosome as hybridization probes, we found one gene at 42 min on the E. coli chromosome map, the expression of which was affected by RNase III. The sequence of the DNA fragment containing this gene (gen-165) revealed the presence of an open reading frame encoding a polypeptide of 165 amino acid residues. The amino acid sequence deduced from the nucleotide sequence exhibited a remarkable similarity to that of the human ferritin H chain.     

Family of the major cold-shock protein, CspA (CS7.4), of Escherichia coli, whose members show a high sequence similarity with the eukaryotic Y-box binding proteins

The cspA is a gene of Escherichia coli, whose expression is specifically induced at low temperatures to a level of 13% of total protein synthesis. The CspA protein consisting of 70 amino add residues has high sequence similarity with eukaryotic Y-box DNA-binding proteins. We found two independent clones from the Kohara miniset phage collection, which hybridized with a DNA fragment containing cspA. DNA sequencing of these clones confirmed that the two genes are highly homologous to cspA. One designated cspB is mapped at 35 min on the E. coli chromosome and encodes a 71-residue protein with 79% identity to CspA, while the other, cspC, is mapped at 40 min and encodes a 69-residue protein with 70% identity. In addition, a DNA sequence upstream of the clpA gene at 19 mm published elsewhere contains an open reading frame for a 74-residue protein with 45% identity to CspA. All csp genes were fused in the coding regions with the lacZ gene, and the expression of β-galactosidase was examined for these hybrid genes upon cold shock. A similar cold-shock induction to cspA was observed for cspB but not cspC and cspD. These results Indicate that E. coli has a family of the cspA gene, some of which are induced by cold shock.     

Hek: an Escherichia coli function involved in functional expression of the kil gene of bacteriophage Mu

Summary An Escherichia coli mutant has been isolated (Hek) in which the kil gene of bacteriophage Mu is not functionally expressed. The hek locus has been mapped between rpoD (66.2 min) and argR (69.5 min) on the E. coli chromosome. No influence of the hek mutation on phage or E. coli development could be detected.     

Identification, cloning, nucleotide sequence and chromosomal map location of hns, the structural gene for Escherichia coli DNA-binding protein H-NS

Summary Beginning with a synthetic oligonucleotide probe derived from its amino acid sequence, we have identified, cloned and sequenced the hns gene encoding H-NS, an abundant Escherichia coli 15 kDa DNA-binding protein with a possible histone-like function. The amino acid sequence of the protein deduced from the nucleotide sequence is in full agreement with that determined for H-NS. By comparison of the restriction map of the cloned gene and of its neighboring regions with the physical map of E. coli K12 as well as by hybridization of the hns gene with restriction fragments derived from the total chromosome, we have located the hns gene oriented counterclockwise at 6.1 min on the E. coli chromosome, just before an IS30 insertion element.     

Overexpression of the Saccharomyces cerevisiae MET17/MET25 gene in Escherichia coli and comparative characterization of the product with O-acetylserine·O-acetylhomoserine sulfhydrylase of the yeast

The Saccharomyces cerevisiae MET17/MET25 gene encoding O-acetyl-L-serine (OAS)·O-acetyl-L-homoserine (OAH) sulfhydrylase (EC 4.2.99.10) was overexpressed in Escherichia coli and the gene product was purified to homogeneity, using three steps, with a recovery of 28% from the total cell extract. The gene product has been compared with OAS·OAH sulfhydrylase purified from the yeast cells. These two protein preparations were indistinguishable with respect to their behavior in polyacrylamide gel electrophoresis, both with and without sodium dodecyl sulfate, their specificity for substrate amino acids, Michaelis constant (K _m) value for OAH, sensitivity to carbonyl reagents, absorption spectrum, isoelectric point, behavior in HPLC (both ion-exchange chromatography and gel filtration), sensitivity to heat treatment, susceptibility to trypsin digestion, and their N-terminal amino acid sequence. The results obtained imply that the gene product is properly processed in E. coli, and the technique developed in this study to overexpress the gene in bacterial cells provides us with a large amount of the purified preparation of the enzyme. In contrast to a previous report we found that cystathionine -lyase of S. cerevisiae behaved differently from OAS·OAH sulfhydrylase during the purification procedure.     

Growth, Survival and Characterization of cspA in Salmonella enteritidis Following Cold Shock

Salmonella enteritidis is a major foodborne microbial pathogen that can grow and survive at low temperatures for a considerable period of time. Increased survival was evidenced from a frozen S. enteritidis culture when treated at 10°C prior to freezing. Western blot analysis with Escherichia coli CspA antibody and analysis of radiolabeled proteins from S. enteritidis cultures after cold shock at 10°C and 5°C showed increased expression of a 7.4-kDa major cold shock protein, CS7.4, similar in size to that reported for E. coli. Cloning followed by nucleotide sequence analysis of the cspA gene from S. enteritidis showed a 100% nucleotide sequence identity in the promoter elements (−35 and −10) and the amino acid sequence encoded by the open reading frame (ORF) with the E. coli cspA gene. However, the differences in the nucleotide sequences between E. coli and S. enteritidis cspA genes in the putative repressor protein binding domain, the fragment 7, and in various segments throughout the upstream 0.642-kbp DNA may contribute to the expression of CS7.4 at less stringent temperatures in S. enteritidis. As in E. coli, the actual role of CS7.4 in protecting S. enteritidis from the damaging effects of cold or freezing temperatures is not yet understood. Received: 14 March 1997 / Accepted: 10 July 1997     

Location of the ompT gene relative to that of appY on the physical map of the Escherichia coli chromosome

Results concerning the precise location of the ompT gene (encoding the outer membrane protease OmpT) on the Escherichia coli chromosome were obtained which disagree with published restriction sites in the gene. It is shown that the gene, together with appY, is present on a 3.075 PstI fragment, encompassing positions 596–598 of the E. coli physical map.     

Highly efficient production of enzymes of an extreme thermophile, Thermus thermophilus: A practical method to overexpress GC-rich genes in Escherichia coli

The GC-rich leuB gene (coding for 3-isopropylmalate dehydrogenase) of Thermus thermophilus is scarcely expressed in Escherichia coli, unless a leader open reading frame (ORF) is provided. We conducted experiments on nonexpressible plasmids and obtained a modified plasmid showing greatly enhanced expression: the degree of expression from the plasmid was higher than that from any other plasmid so far constructed. Sequence analysis of the plasmid showed that a 258-bp leader ORF overlapped with the initiation codon of leuB was newly formed as a consequence of the insertion of a 0.5-kb BamHI fragment derived from the E. coli chromosome. The degree of expression from the plasmid was further improved by shortening the leader ORF to 36 bp without changing the overlapping portion, and the flanking sequence between the promoter and the leader ORF was removed. The expression in E. coli of the pfk1 gene (coding for phosphofructokinase) of T. thermophilus was improved by the construction of a structure similar to that which enhanced the expression of the leuB gene. Based on the results, a practical method for the overexpression of GC-rich genes in E. coli is proposed. Received: November 26, 1996 / Accepted: May 17, 1997     

Transfer of the chromosomally encoded tetracycline resistance gene <Emphasis Type="Italic">tet</Emphasis>(M) from marine bacteria to <Emphasis Type="Italic">Escherichia coli</Emphasis> and <Emphasis Type="Italic">Enterococcus faecalis</Emphasis>

The transferability of the tetracycline (TC) resistance gene tet(M) from marine bacteria to human enteric bacteria was examined by a filter-mating method. Vibrio spp., Lactococcus garvieae, Bacillus spp., Lactobacillus sp., and Paenibacillus sp. were used as donors, and Escherichia coli JM109 and Enterococcus faecalis JH2-2 were used as recipients. The combination of Vibrio spp. and E. coli resulted in 5/68 positive transconjugants with a transfer rate of 10⁻⁷ to 10⁻³; however, no transfer was observed with E. faecalis. In case of L. garvieae and E. faecalis, 6/6 positive transconjugants were obtained with a transfer rate of 10⁻⁶ to 10⁻⁵; however, no transfer was observed with E. coli. The tet(M) gene of Bacillus, Lactobacillus, and Paenibacillus were not transferred to either E. coli or E. faecalis. tet(M) transfer was confirmed in positive E. coli and E. faecalis transconjugants by polymerase chain reaction (PCR) and Southern hybridization. All the donor strains did not harbor plasmids, while they all harbored transposon Tn916. In the transconjugants, the transposon was not detected by PCR, suggesting the possible transfer of tet(M) from the marine bacterial chromosome to the recipient chromosome. This is the first report to show that tet(M) can be transferred from marine bacteria to human enteric bacteria in a species-specific manner.     

Integration and Intramolecular Transposition of the TnBP3 Transposon ofBordetella pertussis in the Escherichia coliK12 Cells Mutant for the Hpr Protein of the Phosphoenolpyruvate-Dependent Phosphotransferase System

Integration of a plasmid carrying the TnBP3 transposon of Bordetella pertussisinto the chromosome of Escherichia coliand transpositions of the integrated structure within a chromosome in the wild-type and mutant cells ptsHdevoid of the major Hpr protein of the phosphoenolpyruvate-dependent phosphotransferase system were studied. When transposed to a new chromosome site, the integrated structure was precisely (or almost precisely) excised from the metYgene sequence, which resulted in restoration of the Met⁺phenotype. The integration and transposition events were only observed in the E. colicells carrying the ptsH ⁺allele. The ptsHmutations inhibited integration and intramolecular transposition, which were restored after phenotypic or genetic suppression of the ptsHmutation. The intensity of the processes studied were suggested to depend on the integrity of a chain that ensures transferring of the phosphoryl residue by proteins of the phosphotransferase system in E. coliK12.     

Construction of an Escherichia coli mutant producing monophosphoryl lipid A

Lipid A is a major component in the outer membrane of most Gram-negative bacteria. Monophosphoryl lipid A contains no phosphate group at 1-position and can be used as an adjuvant. We constructed an Escherichia coli mutant CW001 by integrating a gene lpxE into the chromosome of E. coli W3110. The gene lpxE encodes an enzyme LpxE which removes the 1-phosphate group of lipid A. CW001 predominantly produces 1-dephosphorylated lipid A in vivo, as adjudged by thin layer chromatography and electro-spray ionization mass spectrometry. This study not only is important for the development of lipid A adjuvants but also provides a novel method for integration of heterologous genes into the chromosome of E. coli.     

A convenient method for multiple insertions of desired genes into target loci on the <Emphasis Type="Italic">Escherichia coli</Emphasis> chromosome

We developed a method to insert multiple desired genes into target loci on the Escherichia coli chromosome. The method was based on Red-mediated recombination, flippase and the flippase recognition target recombination, and P1 transduction. Using this method, six copies of the lacZ gene could be simultaneously inserted into different loci on the E. coli chromosome. The inserted lacZ genes were functionally expressed, and β-galactosidase activity increased in proportion to the number of inserted lacZ genes. This method was also used for metabolic engineering to generate overproducers of aromatic compounds. Important genes of the shikimate pathway (aroF ^fbr and tyrA ^fbr or aroF ^fbr and pheA ^fbr ) were introduced into the chromosome to generate a tyrosine or a phenylalanine overproducer. Moreover, a heterologous decarboxylase gene was introduced into the chromosome of the tyrosine or phenylalanine overproducer to generate a tyramine or a phenethylamine overproducer, respectively. The resultant strains selectively overproduced the target aromatic compounds. Thus, the developed method is a convenient tool for the metabolic engineering of E. coli for the production of valuable compounds.     

Common origin of plasmid encoded alpha-hemolysin genes in <Emphasis Type="Italic">Escherichia coli</Emphasis>

Background  

Alpha (α)-hemolysin is a pore forming cytolysin and serves as a virulence factor in intestinal and extraintestinal pathogenic strains of E. coli. It was suggested that the genes encoding α-hemolysin (hlyCABD) which can be found on the chromosome and plasmid, were acquired through horizontal gene transfer. Plasmid-encoded α-hly is associated with certain enterotoxigenic (ETEC), shigatoxigenic (STEC) and enteropathogenic E. coli (EPEC) strains. In uropathogenic E. coli (UPEC), the α-hly genes are located on chromosomal pathogenicity islands. Previous work suggested that plasmid and chromosomally encoded α-hly may have evolved independently. This was explored in our study.