Unidirectional theta replication of the structurally stable Enterococcus faecalis plasmid pAM beta 1.

Numerous bacterial replicons remain poorly characterized due to difficulties in localization of the replication origin. We have circumvented this problem in the characterization and fine mapping of the origin of plasmid pAM beta 1 by exploiting the Bacillus subtilis termination signal, terC. In terC-containing derivatives, theta-form molecules with two invariant endpoints accumulate. The endpoints, which correspond to plasmid origin and terC, were mapped with single-nucleotide precision. Analysis of the replication intermediates of wild-type molecules by two-dimensional gel electrophoresis confirmed the location of the plasmid origin. Our results demonstrate that pAM beta 1 replication proceeds unidirectionally by a theta mechanism. This work confirms the use of termination signals to localize origins, suggests that termination in B. subtilis occurs by a mechanism similar to that of Escherichia coli and establishes that in addition to rolling circle replicating plasmids, Gram positive bacteria harbour plasmids which replicate by a theta mechanism.     

Nonrandom cosmid cloning and prophage SP beta homology near the replication terminus of the Bacillus subtilis chromosome.

From a library of Bacillus subtilis DNA cloned with the Escherichia coli cosmid vector pHC79, 85 recombinant cosmids containing DNA from near the replication terminus, terC, were identified. The DNA inserts of these cosmids were confined to three regions of a 350-kilobase segment of the chromosome extending from the left end of the SP beta prophage to approximately 75 kilobases on the right of terC. All B. subtilis genes known to reside in this segment, as well as the portion of the SP beta prophage that is expressed early in the lytic cycle of the phage, appeared to be absent from the library. A region of SP beta homology distinct from the prophage and just to the left of terC was identified.     

The normal replication terminus of the Bacillus subtilis chromosome, terC, is dispensable for vegetative growth and sporulation

The Bacillus subtilis strains CU1693, CU1694 and CU1695 were shown by hybridization analysis to carry large deletions of the terminus region that originated within discrete fragments of the SP beta prophage genome. The absence of terC in CU1693 was demonstrated definitively by the identification of a novel junction fragment comprising SP beta DNA and DNA that lies on the other side of terC in the parent strain. This represented the deletion of approximately 230 kb of CU1693 DNA, with the removal of approximately 150 kb to the left of terC and approximately 80 kb to the right of terC. The lack of hybridization of CU1694 and CU1695 DNA to cloned DNA carrying the terC sequence and to cloned DNAs flanking terC suggested that terC is absent from the chromosome of each of these strains also, and that the deletions in CU1694 and CU1695 extend beyond the segment of the terminus region that has been mapped and cloned. The normal growth rate and morphology of CU1693, CU1694 and CU1695 relative to the parent strain when grown in complex medium indicated dispensability of terC for vegetative growth and division. B. subtilis SU153 was constructed using a specific deletion-insertion vector that was designed to effect the deletion of 11.2kb of DNA spanning terC, with the removal of approximately 9.7kb to the left of terC and approximately 1.kb to the right of terC. This manipulation did not introduce any readily detectable auxotrophic requirement. Physiological characterization of SU153 confirmed the dispensability of terC for vegetative growth and cell division, and also established the lack of requirement of terC for the specialized cell division that is associated with formation of the bacterial endospore.     

Characteristics of expression of the tetracycline resistance gene from the plasmid pBR322 in Bacillus subtilis cells

The expression of Tc resistance gene derived from plasmid pBR322 has been studied in Bacillus subtilis cells where this alien gene is not usually expressed. Fragments of Bacillus subtilis chromosome were inserted into the Tc resistance gene promoter region of the hybrid plasmid pGG20 and the expression of this gene was registered. Plasmid pGG20 confers a constitutive mode of Tc resistance in Escherichia coli cells. In contrast, the inducibility of Tc resistance gene expression in Bacillus subtilis cells has been reported. Optimal concentration for the highest inducibility of Tc resistance by the antibiotic has been determined.     

A protein involved in termination of chromosome replication in Bacillus subtilis binds specifically to the terC site.

The small basic protein encoded by the open reading frame adjacent to the terC site in the Bacillus subtilis chromosome and previously implicated in termination of the replication process was purified. Band retardation assays established that this protein (now called the replication terminator protein, encoded by the rtp gene) binds specifically to a 209-base-pair fragment of DNA within which terC is located.     

Sequence features of the replication terminus of the Bacillus subtilis chromosome.

The sequence of 1267 nucleotides spanning the replication terminus, terC, of the Bacillus subtilis 168 chromosome has been determined. The site of arrest of the clockwise fork, which defines terC, has been localized to a 30-nucleotide portion (approximately) within this sequence. The arrest site occurs in an A + T-rich region between two open reading frames and very close to one of two imperfect inverted repeats (47-48 nucleotides each) which are separated by 59 nucleotides. The closeness of approach of the arrested clockwise fork to the first imperfect inverted repeat encountered in this region raises the possibility of a role for the inverted repeats in the mechanism of fork arrest.     

Cloning the gyrA gene of Bacillus subtilis.

We have isolated an eight kilobase fragment of Bacillus subtilis DNA by specific integration and excision of a plasmid containing a sequence adjacent to ribosomal operon rrn O. The genetic locus of the cloned fragment was verified by linkage of the integrated vector to nearby genetic markers using both transduction and transformation. Functional gyrA activity encoded by this fragment complements E. coli gyrA mutants. Recombination between the Bacillus sequences and the E. coli chromosome did not occur. The Bacillus wild type gyrA gene, which confers sensitivity to nalidixic acid, is dominant in E. coli as is the E. coli gene. The cloned DNA precisely defines the physical location of the gyrA mutation on the B. subtilis chromosome. Since an analogous fragment from a nalidixic acid resistant strain has also been isolated, and shown to transform B. subtilis to nalidixic acid resistance, both alleles have been cloned.     

Plasmid and chromosomal gene transfer in Bacillus subtilis and Escherichia coli in natural transformation

The transfer of hDHFR gene by natural transformation between Escherichia coli and Bacillus subtilis cells has been studied, as well as intrageneric gene transfer in Bacillus subtilis. The gene was transferred by natural transformation in bacterial cells and included into the chromosome or the plasmid.     

Insertion and deletion mutations in the repA4 region of the IncFII plasmid NR1 cause unstable inheritance.

Mutants of IncFII plasmid NR1 that have transposons inserted in the repA4 open reading frame (ORF) are not inherited stably. The repA4 ORF is located immediately downstream from the replication origin (ori). The repA4 coding region contains inverted-repeat sequences that are homologous to the terC inverted repeats located in the replication terminus of the Escherichia coli chromosome. The site of initiation of leading-strand synthesis for replication of NR1 is also located in repA4 near its 3' end. Transposon insertions between ori and the right-hand terC repeat resulted in plasmid instability, whereas transposon insertions farther downstream did not. Derivatives that contained a 35-bp frameshift insertion in the repA4 ORF were all stable, even when the frameshift was located very near the 5' end of the coding region. This finding indicates that repA4 does not specify a protein product that is essential for plasmid stability. Examination of mutants having a nest of deletions with endpoints in or near repA4 indicated that the 3' end of the repA4 coding region and the site of leading-strand initiation could be deleted without appreciable effect on plasmid stability. Deletion of the pemI and pemK genes, located farther downstream from repA4 and reported to affect plasmid stability, also had no detectable effect. In contrast, mutants from which the right-hand terC repeat, or both right- and left-hand repeats, had been deleted were unstable. None of the insertion or deletion mutations in or near repA4 affected plasmid copy number. Alteration of the terC repeats by site-directed mutagenesis had little effect on plasmid stability. Plasmid stability was not affected by a fus mutation known to inactivate the termination function. Therefore, it appears that the overall integrity of the repA4 region is more important for stable maintenance of plasmid NR1 than are any of the individual known features found in this region.     

Amplification of the Bacillus subtilis maf gene results in arrested septum formation.

The Bacillus subtilis homolog of the Escherichia coli morphogene orfE (of the mre operon) has been identified. The determinant is located on the chromosome immediately upstream of the mreBCD-minCD (divIVB) operon. The Maf protein shares substantial amino acid sequence identity with the E. coli OrfE protein. Introduction of the B. subtilis maf determinant on a multicopy plasmid into B. subtilis cells results in an inhibition of septation, which leads to extensive filamentation and loss of viability in the transformed cell population. Insertional inactivation of maf indicated that this gene is not essential for cell division.     

Expression of the rtp gene of Bacillus subtilis is required for replication fork arrest at the chromosome terminus

It was earlier proposed that clockwise replication fork arrest at the chromosome terminus in Bacillus subtilis is dependent upon expression of the rtp gene adjacent to the site of arrest, terC [Smith and Wake, J. Bacteriol. 170 (1988) 4083-4090]. A merodiploid strain of B. subtilis, in which rtp was placed under the control of the IPTG-inducible spac-1 promoter, was constructed. Replication fork arrest at terC, as monitored by the level of a forked DNA molecule of predicted dimensions, was shown to be dependent upon IPTG-induced expression of rtp in this strain. The very low concentration of IPTG needed to induce a substantial level of fork arrest suggests that relatively little RTP, the protein product of rtp, is needed for fork arrest at terC.     

Phosphoribosylpyrophosphate synthetase of Bacillus subtilis. Cloning, characterization and chromosomal mapping of the prs gene

The gene (prs) encoding phosphoribosylpyrophosphate (PRPP) synthetase has been cloned from a library of Bacillus subtilis DNA by complementation of an Escherichia coli prs mutation. Flanking DNA sequences were pruned away by restriction endonuclease and exonuclease BAL 31 digestions, resulting in a DNA fragment of approx. 1.8 kb complementing the E. coli prs mutation. Minicell experiments revealed that this DNA fragment coded for a polypeptide, shown to be the PRPP synthetase subunit, with an Mr of approx. 40,000. B. subtilis strains harbouring the prs gene in a multicopy plasmid contained up to nine-fold increased PRPP synthetase activity. The prs gene was cloned in an integration vector and the resulting hybrid plasmid inserted into the B. subtilis chromosome by homologous recombination. The integration site was mapped by transduction and the gene order established as purA-guaA-prs-cysA.     

Suppression of Escherichia coli dnaA46 mutations by integration of plasmid R100.1. derivatives: constraints imposed by the replication terminus.

We have studies the phenotypic suppression of a dnaA46 mutation by plasmid integration at preselected chromosomal sites after introducing homologous sequences (Mu prophages) onto both the chromosomes and the suppressive plasmid. The plasmids used were all derived from plasmid R100.1. We found that the conditions required to get viable suppressive integration varied as the plasmid integration site moved from the origin to the terminus of chromosome replication. Two constraints were observed. Both appeared to be linked to the new characteristics acquired by chromosome replication from the integrated plasmid. One constraint was that strains with integrative suppression near the terminus terC were viable only in minimal medium. The rich medium sensitivity of these strains was correlated with a loss of regulation of initiation. The other constraint was a requirement for a specific orientation in certain regions of the chromosome. The two branches defined by normally initiated replication, between oriC and terC, were also symmetrical with respect to these plasmid orientation constraints. In studying the possible reasons for a plasmid orientation constraint, we found that, of the two forks initiated in bidirectional replication from the integrated plasmid, one was capable of moving across the terC region with a higher movability than the other.     

Genetic analysis of sacB, the structural gene of a secreted enzyme, levansucrase of Bacillus subtilis Marburg

The structural gene sacB encoding B. subtilis levansucrase, a secreted enzyme, expresses in E. coli. E. coli hosts of the sacB gene are poisoned by sucrose. This property allowed a powerful selection of mutants affected in the cloned gene. The plasmidic mutations were readily introduced in the B. subtilis chromosome. Using a collection of plasmids bearing various deletions extending in sacB we developed a technique of deletion mapping based on plasmid integration in the chromosome of B. subtilis. A generalization of this technique is discussed.     

Expression of thymidylate synthetase activity in Bacillus subtilis upon integration of a cloned gene from Escherichia coli

The gene from Escherichia coli encoding thymidylate synthetase was cloned in the plasmid pBR322. The resulting chimeric plasmid, pER2, was effective in transforming both E. coli and Bacillus subtilis to thymine prototrophy. Uncloned linear E. coli chromosomal DNA was unable to transform thymine-requiring strains of B. subtilis to thymine independence. Linearization of the chimeric plasmid, pER2, with restriction enzymes markedly diminished its ability to transform B. subtilis auxotrophs. The Thy+ transformants derived from the transformation of B. subtilis with pER2 DNA did not contain detectable extrachromosomal DNA as demonstrated by Southern hybridization patterns and centrifugation in CsCl gradients of DNA isolated from B. subtilis colonies transformed with the chimeric plasmid. We conclude that the DNA from the chimeric plasmid was integrated into the chromosome of B. subtilis, demonstrating that extensive homology is not required for the integration of foreign DNA. This is the first reported case of a gene from a Gram-negative bacterium functioning in a Gram-positive organism.     

Integration of various plasmids into the Bacillus subtilis chromosome

Some features of integration of temperature-sensitive pE194, pGG10 and pGG20 plasmids into the Bacillus subtilis chromosome were studied. Several auxotrophic mutations were obtained using insertion of these plasmids into the chromosome. The sites of plasmids for illegitimate recombination were determined. It was shown that the integration into the Bac. subtilis chromosome is characteristic not only for the plasmid pE194 but is the property of Staphylococcus aureus plasmid pC194 and Escherichia coli pBR322 plasmid. The influence of different Bac. subtilis rec mutations on the frequency of integration was studied.     

Identification of restriction fragments from two cryptic Clostridium butyricum plasmids that promote the establishment of a replication-defective plasmid in Bacillus subtilis

Clostridium butyricum NCIB 7423 carries two cryptic plasmids, pCB101 (6.05 kbp) and pCB102 (7.8 kbp). Sites for the restriction enzymes EcoRI, EcoRV, HindIII, ClaI and PstI have been found in one or both of these plasmids and their relative positions determined. Restriction fragments from both plasmids have been inserted into a vector plasmid (pJAB1) that is able to replicate in Escherichia coli but not in Bacillus subtilis and the recombinant plasmids have been established in E. coli. A 3.3 kbp Sau3A fragment of pCB101 conferred upon the vector the ability to transform both Rec+ and Rec- strains of B. subtilis. Plasmid pRB1, a representative chimaera carrying only the 3.3 kbp Sau3A fragment of pCB101, was successfully transferred from B. subtilis back to E. coli. Plasmid pRB1 was readily lost from B. subtilis in the absence of selection. This evidence, together with the results of hybridization experiments, suggests that pRB1 is present as a weakly replicating autonomous element in B. subtilis. A recombinant plasmid carrying a 2.0 kbp Sau3A fragment of pCB102 underwent integration into the B. subtilis chromosome.     

Insertional mutagenesis in Bacillus subtilis: mechanism and use in gene cloning

The plasmid pHV32, which replicates in Escherichia coli but not in Bacillus subtilis, transformed B. subtilis-competent cells efficiently when linked in vitro to EcoRI B. subtilis DNA segments. The transformed clones carried pHV32 inserted in their chromosomes, and often displayed a mutant phenotype. One of the transformed clones carried pHV32 inserted close to the thyB gene. We cleaved the DNA extracted from this clone with BglII restriction endonuclease, for which no sites exist on pHV32, ligated the released segments and used them to transform E. coli selecting for pHV32-carried genetic markers. The transformants harbored a hybrid plasmid which carried the B. subtilis thyB gene. Circular molecules composed of pHV32 joined to B. subtilis DNA inserted into the chromosome by a Campbell-like recombination event. Linear molecules, in which pHV32 was flanked by two non-adjacent DNA segments, underwent a double cross-over recombination with the chromosome. In this case the chromosomal sequences between the non-adjacent segments were deleted, and replaced by pHV32 sequences.