Clustered arg genes on a BamHI segment of the Escherichia coli chromosome.

BamHI cleavage of DNAs from transducing phages gamma darg13 (ppc, argECBH, bfe), gamma darg14 (ppc, argECBH) and gamma darg23 (argECBH) yields three purely gamma DNA segments (and, in one case, a fourth), as well as several Excherichia coli-DNA-containing segments. The length (in kilobases, kb) of the segments, determined by electron microscopy and ararose gel electrophoresis is 4.2, 7.5, 8.4, 6.2, 6.9, and 6.4 kb for gamma darg13; 13.0, 7.5, 4.7, 6.2, 6.9, and 6.4 kb for gamma darg 14: and 5.3, 11.0, 4.7, 6.2, 6.9, and 6.4 kb for gamma darg23. Ordering of the segments (in relation to the gamma genetic map and with the direction from left to right corresponding to the clockwise orientation of the E. coli genetic map and to each of the numerical sequences given) reveals, on 26 kb of bacterial DNA, two cleavage sites defining the 7.5-kb segment obtainable from the DNA of either gamam darg13 or gamma darg14. These and analogous findings with argEC and argCB deletion-bearing strains, together with results from heteroduplex experiments, locate argE, argC, argB, and presumably argH on the 7.5-kb segment.     

DNA cleavage of lambda and phi 80 transducing phages carrying the argA, argECBH, argF and argI operons of Escherichia coli K-12 with the restriction endonucleases EcoRI, SmaI and HindIII.

DNA isolated from each of the seven arginine transducing phages lambdaargA2cI857susS7, phi80ppc argECBH, phi80argF, phi80argF ilambdacI857, lambdaargF2, lambdaargF23 and lambdaargI valScI857susS7 has been specifically cleaved by the restriction endonucleases EcoRI, SmaI and HindIII. The DNA fragments resulting from single, and in some cases, double endonuclease digests were separated by electrophoresis in agarose and also in polyacrylamide gel. The electrophoretic patterns thus obtained were compared with those produced by digestion of DNA isolated from the corresponding lambda and phi80 parental phages. The majority of cleavage sites produced by the action of these restriction enzymes on arginine transducing DNA have been physically mapped.     

Construction and analysis of recombinant lambda phages containing mitochondrial DNA fragments.

Rat mtDNA has a molecular length of about 16 kilobase (kb) pairs and is cleaved into seven fragments by restriction endonuclease EcoRI. These fragments were cloned in Escherichia coli K-12 host using lambda gtWES.lambda B' (lambda gtWES.lambda B, for short, in this paper) as a vector. Recombinant DNAs containing one or a few fragments of the mtDNA were transfected to CaCl2-treated E. coli, and the plaques containing specific recombinant phages were selected. DNA amplified in the recombinanat phage lambda gt.mt was shown to contain the same restriction endonuclease cleavage sites as those found in the mtDNA. Present results permitted the DNA sequencing of any portion of the mitochondrial genome.     

Cloning of Thermomonospora fusca genes coding for beta 1-4 endoglucanases E1, E2 and E5

Thermomonospora fusca chromosomal DNA was partially digested with EcoRI and fragments in the size range from 4 to 15 kb were isolated, ligated into lambda gtWES.lambda B arms, packaged, and the recombinant phages plated on Escherichia coli. The plaques were screened for carboxymethyl cellulase (CMCase) activity by a gel overlay procedure, and 25 plaques were positive among the 15,000 plaques that were screened. Positive phages were amplified and used to prepare infected E. coli extracts which were assayed for CMCase activity before and after treatment with antisera prepared against five purified T. fusca beta 1-4 endoglucanases (E1-E5). One phage produced an enzyme that was inhibited by E1 antiserum, nine of the phages produced enzymes that were inhibited by E2 antiserum, 14 produced enzymes that were inhibited by E5 antiserum and the enzyme produced by the other phages was not inhibited by any of the five antisera. The DNA insert present in the phage coding for E1 was cut into a number of different fragments which were subcloned into E. coli first using lambda gtWES.lambda B and then plasmid pBR322. The smallest active subclone, pTE12, contained a 3.1-kb insert. The insert present in one of the phages coding for E2 was also subcloned and the smallest active subclone pTE23 contained a 2-kb insert. E. coli HB101 containing plasmid pTE12 or pTE23 produced enzymes that were identical to E1 and E2, respectively, in all the properties tested.     

pMB9 plasmids bearing the Salmonella typhimurium his operon and gnd gene

A plasmid containing the entire Salmonella typhimurium his operon was constructed from plasmid pM89 and an EcoRI fragment of phi 80 his imm lambda DNA. The recombinant pST41 also includes the glucose 6-phosphate dehydrogenase (gnd) gene and has one EcoRI endonuclease cleavage site in the integrated fragment. This plasmid served as a source for the construction of two additional plasmids, one carrying the OGDC-region of the his operon and the other a CBHAFIE segment of the his gene along with the gnd gene. The presence of the his operon in the constructed plasmids was confirmed by hybridization to S. typhimurium his RNA. The location of the gnd gene in the CBHAFIE fragment of the his gene was confirmed genetically: after transfection with the plasmid bearing the gnd gene, a gnd recipient gained the capacity to utilize gluconate as a sole carbon source. The DNAs of the three hybrid plasmids were analyzed by gel electrophoresis. By comparing the EcoRI endonuclease cleavage pattern of these three hybrid plasmids with the DNA cleavage pattern of phi 80 his imm lambda, phi 80 imm lambda and lambda phages, the EcoRI cleavage map of phi 80 his imm lambda was obtained.     

Molecular cloning of four tricarboxylic acid cyclic genes of Escherichia coli.

A fragment of DNA (3.1 kilobases [kb]) from a ColE1 Escherichia coli DNA hybrid plasmid containing the bacterial citrate synthase gene (gltA) was subcloned in both orientations into phage lambda vectors by in vitro recombination. The resulting phages were able to transduce gltA and, as prophages, complemented the lesion of a gltA mutant, showing that a functional gltA gene is contained in the 3.1-kb fragment. The segment of E. coli DNA cloned in these lambda gltA phages was extended in vivo by prophage integration and aberrant excision in the gltA region. Plaque-forming derivatives, carrying up to three additional tricarboxylic acid cycle genes, succinate dehydrogenase (sdh), 2-oxoglutarate dehydrogenase (sucA), and dihydrolipoamide succinyltransferase (sucB), were isolated and characterized by their transducing and complementing activities with corresponding mutants, and the order of the genes was confirmed as gltA-sdh-sucA-sucB. Physical maps of a variety of the transducing phages showed that the four tricarboxylic acid cycle genes are contained in a 12.8-kb segment of bacterial DNA. The four gene products, plus a possible succinate dehydrogenase small subunit, were identified in postinfection labeling studies, and the polarities of gene expression were defined as counterclockwise for gltA and clockwise for sdh, sucA, and sucB, relative to the E. coli linkage map.     

Cloning and properties of the Salmonella typhimurium tricarboxylate transport operon in Escherichia coli.

The tricarboxylate transport operon (tctI) was cloned in Escherichia coli as a 12-kilobase (kb) fragment from an EcoRI library of the Salmonella typhimurium chromosome in lambda gtWES. It was further subcloned as a 12-kb fragment into pACYC184 and as an 8-kb fragment into pBR322. By insertional mutagenesis mediated by lambda Tn5, restriction mapping, and phenotypic testing, the tctI operon was localized to a 4.5-kb region. The tctC gene which encodes a periplasmic binding protein (C protein) was located near the center of the insert. E. coli/tctI clones on either multicopy or single-copy vectors grew on the same tricarboxylates as S. typhimurium, although unusually long growth lags were observed. E. coli/tctI clones exhibited similar [14C]fluorocitrate transport kinetics to those of S. typhimurium, whereas E. coli alone was virtually impermeable to [14C]fluorocitrate. The periplasmic C proteins (C1 and C2 isoelectric forms) were produced in prodigious quantities from the cloned strains. Motile E. coli/tctI clones were not chemotactic toward citrate, whereas tctI deletion mutants of S. typhimurium were. Taken together, these observations indicate that tctI is not an operon involved in chemotaxis.     

Genetics of Bacillus subtilis chemotaxis: isolation and mapping of mutations and cloning of chemotaxis genes

We isolated a collection of chemotaxis mutants and characterized them for chemotactic phenotype and genotype. The mutations of most of these mutants mapped in the region between pyrD and thyA. However, the mutation in the gene specifying the chemotactic methyltransferase mapped very close to aroF. From a bank of phages containing Bacillus subtilis DNA we identified two lambda charon4 phages that contained genes specifying chemotactic functions. The inserted DNAs were removed by digestion with restriction endonuclease EcoRI and were found to share a 4.0-kilobase (kb) fragment. One of these DNAs also contained a 7.7-kb fragment, and the other also contained a 10.9-kb fragment. We identified mutants that were complemented by each fragment. The fragments were each ligated into plasmid pFH7 and were incorporated into lysogenic SP beta c2 or a deletion mutant of SP beta c2 in order to form transducing phages. The mutants in the collection containing mutations that mapped in the region between pyrD and thyA were tested for complementation by transducing phages containing the 4.0-kb fragment, the 7.7-kb fragment, the 4.0-kb fragment plus the 7.7-kb fragment, and the 10.9-kb fragment. A total of 24 mutants were complemented by the 4.0-kb fragment, 7 were complemented by the 7.7-kb fragment, 9 were complemented by the 4.0-kb fragment plus the 7.7-kb fragment, 15 were complemented by the 10.9-kb fragment, and 25 were complemented by none of the fragments.     

Identification of Tn4451 and Tn4452, chloramphenicol resistance transposons from Clostridium perfringens.

The recombinant plasmids pJIR45 and pJIR97 contain the chloramphenicol resistance determinants derived from the Clostridium perfringens R plasmids pIP401 and pJIR27, respectively. Escherichia coli cultures which harbored these recombinant plasmids rapidly became chloramphenicol sensitive when grown in the absence of chloramphenicol. The loss of resistance was associated with the loss of 6.2-kilobase (kb) segments from both plasmids. Detailed restriction analysis of E. coli- and C. perfringens-derived deletion plasmids indicated that deletion of these segments was essentially precise. Transposition of the 6.2-kb segments was demonstrated by cloning the determinants into a temperature-sensitive plasmid, curing the recombinant plasmids, and selecting chloramphenicol-resistant, plasmid-free clones. Southern hybridization analysis of chromosomal DNA isolated from these recA E. coli clones indicated that the 6.2-kb segments had transposed to different sites on the chromosome. Heteroduplex analysis and restriction mapping indicated that the transposons, Tn4451 (pIP401) and Tn4452 (pJIR27), were closely related and did not contain large inverted or directly repeated sequences. These transposons represent the first transposable elements from the clostridia to be identified and characterized.     

The isolation of lambda phage carrying DNA from the histidine and isoleucine-valine regions of the Bacillus subtilis chromosome

From a lambda gtWES library of the chromosome of Bacillus subtilis, phages carrying DNA from the hisA and ilv-leu regions were isolated. They were identified by their ability to form complementing plaques on hisB, ilvC or leuB mutants of Escherichia coli K12 under selective conditions and in the presence of a helper phage. The his phages complemented E. coli his A, B or D mutations and could transform seven mutations in the hisA region of the B. subtilis chromosome; each carried a single EcoR1 insert of about 8.2 kb. Phages complementing E. coli ilvC or leuB mutations and carrying the equivalent B. subtilis genes ilvC and leuC transformed a range of mutations in the B. subtilis ilv-leu region. The distribution of genetic markers carried by the phages suggests that the entire ilv-leu cluster from az1A through leuD is covered in the collection of phages obtained and is carried in three EcoR1 restriction fragments of approximately 6.7, 4.7 and 2.85 kb.     

Analysis of the enterohemorrhagic Escherichia coli O157 DNA region containing lambdoid phage gene p and Shiga-like toxin structural genes.

In this study, we determined the nucleotide sequence of the p gene contained within a 5-kb EcoRI restriction fragment cloned from Shiga-like toxin II (SLT-II)-converting phage 933W of Escherichia coli O157:H7 strain EDL933. The p gene was 702 bp long and had 95.3% sequence similarity to the p gene of phage lambda. Multiple hybridization patterns were obtained when genomic DNA fragments were hybridized with both p and slt-I, slt-II, or slt-IIc sequences. All O157 isolates also possessed an analog of lambda gene p which was not linked with either slt-I or slt-II. Restriction fragment length polymorphism comparisons of clinical O157 isolates and derivates undergoing genotype turnover during infection were made, and loss of large DNA fragments that hybridized with slt-II and p sequences was observed. To further analyze the DNA region containing the p and slt genes, we amplified fragments by using a PCR with one primer complementary to p and the other complementary to either the slt-I or the slt-II gene. PCR analysis with enterohemorrhagic E. coli O157 and non-O157 strains yielded PCR products that varied in size between 5.1 and 7.8 kb. These results suggest that even within O157 isolates, the genomes of SLT-converting phages differ. The methods described here may assist in further investigation of SLT-encoding phages and their role in the epidemiology of infection with enterohemorrhagic E. coli.     

Cloning of a xylanase gene from Fibrobacter succinogenes 135 and its expression in Escherichia coli

A genomic library consisting of 4- to 7-kb EcoRI DNA fragments from Fibrobacter succinogenes 135 was constructed using a phage vector, lambda gtWES lambda B, and Escherichia coli ED8654 as the host bacterium. Two positive plaques, designated lambda FSX101 and lambda FSX102, were identified. The inserts were 10.5 and 9.8 kb, respectively. A 2.3-kb EcoRI fragment that was subcloned from lambda FSX101 into pBR322 also showed xylanase activity. Southern blot analysis showed that the cloned EcoRI fragment containing the xylanase gene had originated from F. succinogenes 135. The cloned endo-(1,4)-beta-D-xylanase gene (pFSX02) was expressed constitutively in E. coli HB101 when grown on LB and on M9 medium containing either glucose or glycerol as the carbon source. Most of the beta-D-xylanase activity was located in the periplasmic space. Zymogram activity stains of nondenaturing polyacrylamide gels and isoelectric focusing gels showed that several xylanase isoenzymes were present in the periplasmic fraction of the E. coli clone FSX02 and they probably were due to posttranslational modification of a single gene product. Comparison of the FSX02 xylanase and the xylanase from the extracellular culture fluids of F. succinogenes 135 and S85 for their ability to degrade oat spelt xylan showed that, for equal units of beta-D-xylanase activity, hydrolysis by the cloned gene product was more complete. However, unlike the unfractionated mixture of xylanases from F. succinogenes 135 and S85, the enzyme from E. coli FSX02 was unable to release arabinose from oat spelt xylan.     

Mapping of insertion element IS5 in the Escherichia coli K-12 chromosome. Chromosomal rearrangements mediated by IS5

We identified phage clones containing insertion element IS5 in a set of 476 lambda phage clones carrying chromosomal segments that cover almost the entire chromosome of Escherichia coli K-12 W3110. Precise locations and orientations of IS5 were then determined by cleavage analysis of phage DNAs containing them. We mapped 23 copies of IS5 (named is5A to is5W) on the W3110 chromosome. Among them, ten were identified as the common elements present at the same locations in both chromosomes of W3110 and another E. coli K-12 strain, JE5519. While most of the mapped IS5 elements were scattered over the W3110 chromosome, four copies of IS5 (designated is5L, is5M, is5N and is5O) were in a region representing tandem duplication of a DNA segment flanked by two copies of IS5. Interestingly, one unit of this DNA segment as well as a portion of it was seen also in a tandem array in a different region where two copies of IS5 (designated is5P and is5Q) were present. In particular two pairs of the mapped IS5 elements may have been involved in inversion of the chromosomal segments in two of the E. coli K-12 derivatives.     

Functional expression of two Bacillus subtilis chromosomal genes in Escherichia coli.

EcoRI-cleaved deoxyribonucleic acid segments carrying two genes from Bacillus subtilis, pyr and leu, have been cloned in Escherichia coli by insertion into a derivative of the E. coli bacteriophage lambda. Lysogenization of pyrimidine- and leucine-requiring auxotrophs of E. coli by the hybrid phages exhibited prototrophic phenotypes, suggesting the expression of B. subtilis genes in E. coli. Upon induction, these lysogens produced lysates capable of transducing E. coli pyr and leu auxotrophs to prototrophy with high frequency. Isolated DNAs of these bacteriophages have the ability to transform B. subtilis auxotrophs to pyr and leu independence and contain EcoRI-cleaved segments which hybridize to corresponding segments of B. subtilis.     

Molecular characterization of ilvC specialized transducing phages of Escherichia coli K-12

A series of lambda defective ilvC specialized transducing phage has been isolated which carry regions of isoleucine and valine structural and regulatory genes derived from the ilv cluster at minute 83 on the linkage map of the chromosome of Escherichia coli K-12. The ilv genes carried by these phages and their order have been determined by transduction of auxotrophs. The ilvC+ lysogen of an ilvC- strain gave rise, after heat induction of the lysogen, to transducing particles which carried the wild-type allele of the cya-marker. Further experiments have shown that the lambda defective ilvC phages were able to cotransduce a rho-15ts mutation as well as a rep-5 mutation. Hence, the order of the clockwise excision of the ilv cluster was found to be ilvC-rho-rep-cya. Enzyme levels in strains carrying the lambda defective ilvC phages indicated the the ilvC gene was not altered by the insertion of lambda into the ilv cluster. The isolation and digestion of lambda defective ilvC DNA by EcoRI and HindIII restriction endonucleases demonstrated that the specialized transducing phages carried part of the genome from the E. coli K-12 chromosome.     

Detection and cloning of murine leukemia virus-related sequences from African green monkey liver DNA.

By using low-stringency nucleic acid hybridization conditions and specific subgenomic segments of the AKR ecotropic provirus as probes, murine leukemia virus (MuLV)-related sequences were detected in African green monkey (AGM) liver DNA. The MuLV-reactive segments present in restricted AGM DNA ranged from 1.9 kilobases (kb) to greater than 10 kb in size. On the basis of this finding, a 17-kb segment was cloned from a partial EcoRI AGM library in lambda Charon 4A which shared nearly 5 kb of homology with AKR ecotropic MuLV DNA. The MuLV-related sequences detected in restricted preparations of AGM DNA or present in the cloned monkey DNA reacted with probes mapping 2.0 to 7.0 kb from the 5' terminus of the AKR ecotropic provirus. The AGM clone also contained repeated sequences that flanked the MuLV-related segment. Labeled, subgenomic, MuLV-reactive segments of the monkey clone hybridized to multiple restriction fragments of AGM liver DNA, indicating the presence of several copies of the MuLV-related sequences.     

Chromosome of the enterohemorrhagic Escherichia coli O157:H7; comparative analysis with K-12 MG1655 revealed the acquisition of a large amount of foreign DNAs.

A complete Xba I and Bln I cleavage map was constructed for the chromosome of an enterohemorrhagic Escherichia coli (EHEC) O157:H7 strain isolated from an outbreak in Sakai City, Japan, in 1996. A comparative chromosome analysis with E. coli K-12 strain MG1655 was made. The EHEC chromosome was approximately 5600 kb in length, 1 Mb larger than that of MG1655. Despite the marked difference in chromosome length, the location and direction of seven rRNA operons of the EHEC strain were similar to those for MG1655. Overall organization of genes common in both strains is also highly conserved. Chromosome expansion was observed throughout the EHEC chromosome, albeit in an uneven manner. A large portion of the chromosome enlargement was observed in the region surrounding the replication terminus, particularly in a segment containing the terA locus. Sample sequencing of 3627 random shotgun clones suggested the presence of approximately 1550 kb strain-specific DNAs on the EHEC chromosome, most of which are likely to be of foreign origin.     

Toward a bacterial genome technology: integration of theEscherichia coli prophage lambda genome into theBacillus subtilis 168 chromosome

A novel approach to the cloning large DNAs in theBacillus subtilis chromosome was examined. AnEscherichia coli prophage lambda DNA (48.5 kb) was assembled in the chromosome ofB. subtilis. The lambda DNA was first subcloned in four segments, having partially overlapping regions. Assembly of the complete prophage was achieved by successive transformation using three discrete DNA integration modes: overlap-elongation, Campbell-type integration, and gap-filling. In theB. subtilis chromosome, DNA was elongated, using contiguous DNA segments, via overlap-elongation. Jumping from one end of a contiguous DNA stretch to another segment was achieved by Campbell-type integration. The remaining gap was sealed by gap-filling. The incorporated lambda DNA thus assembled was stably replicated as part of the 4188 kbB. subtilis chromosome under non-selective conditions. The present method can be used to accommodate larger DNAs in theB. subtilis chromosome and possible applications of this technique are discussed.     

Cloning, restriction endonuclease mapping and post-transcriptional regulation of rpsA, the structural gene for ribosomal protein S1

Transducing lambda phages have been isolated that carry segments of the Escherichia coli chromosome in the aspC region, 20.5 min on the E. coli map. One of these phages, lambda aspC2, carries rpsA, the structural gene for the ribosomal protein S1. A three kilobase fragment from this phage, cloned into either the plasmid pACYC184 or the plasmid pBR322, was found to express S1. In cells carrying the rpsA gene on the high copy number plasmid pBR322 the rate of rpsA mRNA synthesis was increased 40-fold, whereas the rate of protein S1 synthesis was doubled, in comparison with these rates in an rpsA haploid.