Primary structure and mapping of the hupA gene of Salmonella typhimurium.

In bacteria, the complex nucleoid structure is folded and maintained by negative superhelical tension and a set of type II DNA-binding proteins, also called histonelike proteins. The most abundant type II DNA-binding protein is HU. Southern blot analysis showed that Salmonella typhimurium contained two HU genes that corresponded to Escherichia coli genes hupA (encoding HU-2 protein) and hupB (encoding HU-1). Salmonella hupA was cloned, and the nucleotide sequence of the gene was determined. Comparison of hupA of E. coli and S. typhimurium revealed that the HU-2 proteins were identical and that there was high conservation of nucleotide sequences outside the coding frames of the genes. A 300-member genomic library of S. typhimurium was constructed by using random transposition of MudP, a specialized chimeric P22-Mu phage that packages chromosomal DNA unidirectionally from its insertion point. Oligonucleotide hybridization against the library identified one MudP insertion that lies within 28 kilobases of hupA; the MudP was 12% linked to purH at 90.5 min on the standard map. Plasmids expressing HU-2 had a surprising phenotype; they caused growth arrest when they were introduced into E. coli strains bearing a himA or hip mutation. These results suggest that IHF and HU have interactive roles in bacteria.     

Genetic characterization of the gene hupB encoding the HU-1 protein of Escherichia coli

The gene hupB encoding the HU-1(HU beta) protein of Escherichia coli was mapped between proC at min 9 and minA at min 10 on the K-12 genome by plasmid integration and chromosome transfer studies. Genetic studies using plasmid rescue techniques demonstrated that the lon gene is located very close to the 5' end of hupB and that the two genes are both transcribed clockwise on the E. coli map [Bachmann, Microbiol. Rev. 47 (1983) 180-230].     

Cloning and expression of the rfe–rff gene cluster of Escherichia coli

We have cloned a 13 kb Escherichia coli DNA fragment which complemented the rfe mutation to recover the biosynthesis of E. coli O9 polysaccharide. Using Tn5 insertion inactivation, the rfe gene was localized at the 1.5 kb HindIII-EcoRI region flanking the rho gene. We constructed an rfe-deficient E. coli K-12 mutant by site-directed inactivation using a DNA fragment of the cloned 1.5 kb rfe gene. This also confirmed the presence of the rfe gene in the 1.5 kb region. By simultaneous introduction of both the rfe plasmid and the plasmid of our previously cloned E. coli O9 rfb into this rfe mutant, we succeeded in achieving in vivo reconstitution of O9 polysaccharide biosynthesis. From sequence analysis of the rfe gene, a putative promoter followed by an open reading frame (ORF) was identified downstream of the rho gene. This ORF coincided with the position of the rfe gene determined by Tn5 analysis and site-directed mutagenesis. Furthermore, we identified the rff genes in the 10.5 kb DNA flanking the rfe gene. We recognized at least two functional domains on this cloned rff region. Region I complemented a newly found K-12 rff mutant, A238, to synthesize the enterobacterial common antigen (ECA). Deletion of region II resulted in the synthesis of ECAs with shorter sugar chains. When the 10.5 kb rff genes of the plasmid were inactivated by either deletion or Tn5 insertion, the plasmid lost its ability to give rise to transformants of the rfe mutants.     

Construction and characterization of the deletion mutant of hupA and hupB genes in Escherichia coli

Insertion and deletion mutations of the hupB and hupA genes, which encode the HU-1 and HU-2 proteins, respectively, of Escherichia coli, have been constructed in vitro and transferred to the hup loci on the bacterial chromosome. The mutations were constructed by inserting a gene encoding chloramphenicol resistance or kanamycin resistance into the coding region of the hupB or hupA gene, respectively. A complete deletion of the hupA gene was constructed by replacing the entire hupA coding region with the kanamycin resistance gene. Cells in which either the hupB or the hupA gene is defective grow normally, but cells in which both of the hup genes are defective exhibit phenotypes different from the wildtype strain. The hupA-hupB double mutants are cold-sensitive, although their growth rate is normal at 37 degrees C. Furthermore, the viability of the hupA-hupB double mutants is severely reduced when the cells are subjected to either cold shock or heat shock, indicating that the hup genes are essential for cell survival under some conditions of stress. The double mutants also exhibit filamentation when grown in the lower range of permissive growth temperature.     

Molecular characterization of pmbA, an Escherichia coli chromosomal gene required for the production of the antibiotic peptide MccB17

Microcin B17 (MccB17) is a peptide antibiotic produced by Escherichia coli strains harbouring plasmid pMccB17. We have isolated two mutations that strongly reduce the production of MccB17. These mutations, which map at 96 min on the E. coli chromosome, define a new gene that we have called pmbA. A chromosomal DNA fragment of about 13 kb, including the wild-type pmbA allele, was cloned into a mini-Mu plasmid vector. pmbA was located within the cloned DNA fragment by insertional mutagenesis and deletion analysis. The nucleotide sequence of a 1.7 kb DNA region containing the gene was determined. pmbA encodes a hydrophilic protein of 450-amino-acid residues with a predicted molecular size of 48375D, which was visualized in polyacrylamide gels. Protein profiles of cellular envelope and soluble fractions from cells with plasmids overproducing PmbA indicated that it is cytoplasmic. Physiological experiments suggested that pmbA mutants synthesize a molecule (pro-MccB17) able to inhibit DNA replication but unable to be released from cells. We propose that PmbA facilitates the secretion of the antibiotic by completing its maturation.     

Cloning and physical mapping of the ADE1 gene of the yeast Saccharomyces cerevisiae

ADE1 gene of Saccharomyces cerevisiae codes for the primary structure of SAICAR-synthetase. Mutational changes of ADE1 gene result in the accumulation of red pigment in cells. Colour differences, thus, serve as a basis for the selection of mutants or transformants. ADE1 gene was cloned as a 4.0 kb HindIII fragment of yeast DNA in a shuttle vector by complementing the ade1 mutation in yeast. The study of ADE1 gene expression in Escherichia coli showed that the 4.0 kb fragment containing the ADE1 gene does not complement purC mutations in E. coli. However, prototrophic colonies appeared at a frequency of 10(-7)-10(-8) after incubating clones bearing the recombinant plasmid with ADE1 gene on selective media. The plasmid DNA isolated from such clones complements the purC mutation in E. coli and the ade1 mutation in S. cerevisiae. Structural analysis of the plasmid demonstrated that the cloned DNA fragment contained an additional insertion of the bacterial origin. Further restriction enzyme analysis proved the insertion to be the bacterial element IS1. Expression of the cloned ADE1 gene in S. cerevisiae is controlled by its own promoter, whereas in E. coli it is controlled by the IS1 bacterial element.     

Cloning and expression of the gene(s) for cephalosporinase production of Citrobacter freundii

The chromosomal gene(s) for cephalosporinase production of Citrobacter freundii GN346 has been cloned into vector plasmid pMK1, initially as a 7.3 kb EcoRI fragment. From the substrate profile and the response to anti-GN346 CSase serum of the enzyme produced, it was confirmed that the hybrid plasmid (pTY71) carries the relevant chromosomal cephalosporinase gene from C. freundii GN346. A restriction endonuclease cleavage map of cloned EcoRI fragments was constructed, and the structural gene of the cephalosporinase could be limited in the 1.5 kb BamHI fragment. The cloned gene(s) was expressed at an extremely low level in Escherichia coli. Furthermore, its expression was constitutive in E. coli, although inducible in its own cytoplasm.     

Direct cloning of full-length mouse mitochondrial DNA using a Bacillus subtilis genome vector

The complete mouse mitochondrial genome (16.3 kb) was directly cloned into a Bacillus subtilis genome (BGM) vector. Two DNA segments of 2.06 and 2.14 kb that flank the internal 12 kb of the mitochondrial DNA (mtDNA) were subcloned into an Escherichia coli plasmid. Subsequent integration of the plasmid at the cloning locus of the BGM vector yielded a derivative specific for the targeted cloning of the internal 12-kb mtDNA region. The BGM vector took up mtDNA purified from mouse liver and integrated it by homologous recombination at the two preinstalled mtDNA-flanking sequences. The complete cloned mtDNA in the BGM vector was converted to a covalently closed circular (ccc) plasmid form via gene conversion in B. subtilis. The mtDNA carried on this plasmid was then isolated and transferred to E. coli. DNA sequence fidelity and stability through the BGM vector-mediated cloning process were confirmed.     

A Col E1 hybrid plasmid containing Escherichia coli genes complementing d-xylose negative mutants of Escherichia coli and Salmonella typhimurium

The Clarke and Carbon bank of Col El - Escherichia coli DNa hybrid plasmids was screened for complementation of d-xylose negative mutants of E. coli. Of several obtained, the smallest, pRM10, was chosen for detailed study. Its size was 16 kilobases (kb) and that of the insert was 9.7 kg. By transformation or F'-mediated conjugation this plasmid complemented mutants of E. coli defective in either D-xylose isomerase or D-xylulose kinase activity, or both. The activity of D-xylulose kinase in E. coli transformants which bear an intact chromosomal gene for this enzyme was greater than that for the host, due to a gene dosage effect. The plasmid also complemented D-xylose negative mutants of Salmonella typhimurium by F'-mediated conjugation between E. coli and S. typhimurium. Salmonella typhimurium mutants complemented were those for D-xylose isomerase and for D-xylulose kinase in addition to pleiotropic D-xylose mutants which were defective in a regulatory gene of the D-xylose operon. In addition, the plasmid complemented the glyS mutation in E. coli and S. typhimurium. The glyS mutant of E. coli was temperature sensitive, indicating that the plasmid carried the structural gene for glycine synthetase. The glyS mutation in E. coli maps at 79 min, as do the xyl genes. The behaviour of the plasmid is consistent with the existence of a d-xylose operon in E. coli. The data also suggest that the plasmid carries three of the genes of this operon, specifically those for D-xylose isomerase, D-xylulose kinase, and a regulatory gene.     

Mutant isolation and molecular cloning of mre genes, which determine cell shape, sensitivity to mecillinam, and amount of penicillin-binding proteins in Escherichia coli.

A chromosomal region of Escherichia coli contiguous to the fabE gene at 71 min on the chromosomal map contains multiple genes that are responsible for determination of the rod shape and sensitivity to the amidinopenicillin mecillinam. The so-called mre region was cloned and analyzed by complementation of two closely related but distinct E. coli mutants characterized, respectively, by the mutations mre-129 and mre-678, that showed a rounded to irregular cell shape and altered sensitivities to mecillinam; the mre-129 mutant was supersensitive to mecillinam at 30 degrees C, but the mre-678 mutant was resistant. The mre-678 mutation also caused simultaneous overproduction of penicillin-binding proteins 1Bs and 3. A chromosomal region of the wild-type DNA containing the total mre region and the fabE gene was first cloned on a lambda phage; a 7-kilobase (kb) fragment containing the whole mre region, but not the fabE gene, was then recloned on a mini F plasmid, pLG339; and finally, a 2.8-kb fragment complementing only mre-129 was also cloned on this low-copy-number plasmid. The whole 7-kb fragment was required for complementing the mre-678 mutant phenotypes. Fragments containing fabE but not the mre-129 region could be cloned on a high-copy-number plasmid. Southern blot hybridization indicated that the mre-678 mutant had a large deletion of 5.25 kb in its DNA, covering at least part of the mre-129 gene.     

Cloning and the expression of the hemolysin gene of Leptospira pomona pomona in Escherichia coli

The library of Leptospira pomona genes was obtained on phage vector AL 47.1. From this library a recombinant phage carrying the hemolysin gene was selected. The DNA fragment (7.7 kb) of this phage containing the hemolysin gene was subcloned on plasmid pUC19. E. coli clones with hybrid plasmid pDR7 were shown to be hemolytic, but the secretion of hemolysin by E. coli into the culture medium was not observed.     

Construction of an Escherichia coli-Clostridium perfringens shuttle vector and plasmid transformation of Clostridium perfringens

A stable shuttle vector which replicates in Escherichia coli and Clostridium perfringens was constructed by ligating a 3.6-kilobase (kb) fragment of plasmid pBR322 with C. perfringens plasmid pHB101 (3.1 kb). The marker for this shuttle plasmid originated from the 1.3-kb chloramphenicol resistance gene of plasmid pHR106. The resulting shuttle vector, designated pAK201, is 8 kb in size and codes for resistance to 20 micrograms of chloramphenicol per ml in both E. coli and C. perfringens. Following shuttle vector construction in E. coli, plasmid pAK201 was transformed into E. coli HB101 and C. perfringens ATCC 3624A, using intact cell electroporation. The transformation frequencies were 10(6) and 10(4) transformants per microgram of DNA in E. coli and C. perfringens, respectively. Restriction enzyme analysis of the chimera isolated from transformants of both microorganisms suggested that the plasmids were identical. Reciprocal transformation experiments in E. coli and C. perfringens indicated no difference in transformation frequency. Plasmid pAK201 was stable in C. perfringens following repeated transfer in the absence of chloramphenicol pressure. The restriction map of plasmid pAK201 shows six unique cut sites which should be useful for future genetic analysis and C. perfringens gene library construction.     

Epidermolytic toxin serotype B of Staphylococcus aureus is plasmid-encoded

Abstract The gene coding for epidermolytic toxin serotype B ( etb ) was cloned in a plasmid expression vector in Escherichia coli . Its expression was dependent on the vector plasmid's trc promoter. A polypeptide immunochemically indistinguishable from the purified staphylococcal toxin and with the same molecular weight was predominantly localized in the periplasm of E. coli . The etb gene resides on a 1.7 kb Hin dIII fragment of the 42 kb plasmid pTC142 present in the parental Staphylococcus aureus strain.