Alterations in the number of rRNA operons within the Bacillus subtilis genome

Deletions and additions of rRNA gene sets in Bacillus subtilis were observed by Southern hybridizations using cloned radiolabeled rDNA sequences. Of the ten rRNA gene sets found in B. subtilis 168M or NCTC3610, one was deleted in strains possessing the leuB1, ilvC1, argA2 and pheA1 mutations. Among EcoRI restriction fragments of genomic DNA products, a 2.9-kb 23S rRNA homolog was missing. In HindIII digest, both 5.5- and 5.1-kb hybrid bands were lost with 16S and 23S probes, respectively. Similarly, genomic DNAs digested with SmaI showed the absence of both 2.1- and 2.0-kb fragments that hybridized to 16S and 5S sequences, respectively, in wild-type genomes. In contrast, B. subtilis strain 166 and its derivatives displayed a gain of a 3.3-kb HindIII fragment homologous to 16S rRNA. Transforming the ilvC1 and leuB1 mutations into new genetic backgrounds revealed in some clones the concomitant introduction of the ribosomal defect. Transformations with the slightly heterologous donor DNA from strain W23 yielded some Leu+ and Arg+ transformants with altered hybridization patterns when probed with cloned sequences. We propose that the deletion of the rRNA operon occurred in the ilv-leu gene cluster of the B. subtilis genome as a result of unequal recombination between redundant sequences.     

A new cloning system for Bacillus subtilis comprising elements of phage, plasmid and transposon vectors

A new cloning system for Bacillus subtilis was devised which makes use of a combination of Tn917-containing phage SP beta derivatives and Tn917-containing Escherichia coli-B. subtilis shuttle plasmids. This system allows the initial cloning of genes in single copy, via 'prophage transformation', with a selection for complementation of mutational defects in B. subtilis hosts and permits subsequent transfer of the cloned material by homologous recombination to low-copy and high-copy vectors that replicate in both B. subtilis and E. coli. Because cloned sequences are adjacent to pB322-derived DNA in the recombinant phages, inserts can also be 'rescued' directly from the phage DNA after digestion with appropriate restriction enzymes, circularization of the fragments by ligation and transformation of an E. coli recipient. Two genomic libraries of B. subtilis chromosomal Sau3A-generated partial-digest fragments in the size ranges of 5-8 kb and 8-10 kb were constructed and screened for the complementation of mutations aroI906, cysA14, dal-1, glyB133, metC3, purA16, purB33, thrA5, trpC2 and recE4. In all cases, specialized transducing phages carrying inserts that complemented the selected markers were recovered. Inserts complementing the dal-1 and trpC2 mutations could be transferred from recombinant phages to Tn917-containing plasmids by homologous recombination without in vitro subcloning. Another insert complementing the purB33 mutation was rescued directly into E. coli from a recombinant phage DNA.     

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.     

Construction of a novel gene bank of Bacillus subtilis using a low copy number vector in Escherichia coli

Low copy number vector plasmid pCT571 was constructed to clone Bacillus subtilis genomic fragments in Escherichia coli. pCT571 confers KmR, TcR and CmR in E. coli and CmR in B. subtilis. It has unique restriction sites within the KmR and TcR markers to allow screening for recombinant plasmids by insertional inactivation of these genes. It contains the pSC101 replicon and replicates normally at six to eight copies per chromosome equivalent in E. coli. It also contains oriVRK2, which when supplied with the product of the trfA gene of RK2 in trans, allows pCT571 to replicate at 35-40 copies per chromosome equivalent. A B. subtilis gene bank was created by cloning partially Sau3A-digested and size-fractionated fragments of B. subtilis chromosomal DNA into the BamHI site of pCT571. DNA from 1097 KmR TcS transformants was extracted and analysed electrophoretically as supercoiled DNA and after digesting with EcoRI or EcoRI and SalI. Approximately 1000 hybrid plasmids were found with reasonably sized B. subtilis fragments. The mean size of the inserts in pCT571 is 8 kb, ranging from 4 to 20 kb in different plasmids. The gene bank covers most of the B. subtilis chromosome, as demonstrated by the results of screening the gene bank for selectable nutritional markers in E. coli and B. subtilis. Hybrid plasmids which complement E. coli mutants for arg, his, lys, met, pdx, pyr and thr markers were identified from the gene bank. In B. subtilis the presence of argC, cysA, dal, hisA, ilvA, leuA, lys, metB, metC, phe, purA, purB, thr and trpC was established by transformation experiments. The effects of copy number on cloning and long-term maintenance in the bacterial strains were also investigated. At high copy number some hybrid plasmids cannot be maintained at all, while others show an increased rate of structural deletions and rearrangements.     

Construction of a Bacillus subtilis cloning vehicle with heterologous DNA sequence

A cloning vehicle, pFTB91, for the Bacillus subtilis host was constructed with DNA fragments heterologous to the host chromosome. It consists of three DNA fragments: (i) chromosomal DNA of Bacillus amyloliquefaciens which complements the leuA and ilvC mutations in B. subtilis; (ii) a B. amyloliquefaciens plasmid DNA that supplies an autonomously replicating function; and (iii) a HindIII fragment of Staphylococcus aureus plasmid pTP5 that carries gene tetr, conferring the TetR phenotype. It has sufficiently low DNA homology to prevent its integration into the host chromosome in recombination-competent cells of B. subtilis. It is 9.3 kb, and approx. 10 copies are present per chromosome. The SalI and KpnI sites in the ilvC+ and tetr genes, respectively, could be used for selection of recombinant plasmids by insertional inactivation. The plasmid has unique sites for EcoRI, PstI, and XbaI.     

Genetic complementation of the Saccharomyces cerevisiae leu2 gene by the Escherichia coli leuB gene.

The leucine operon of Escherichia coli was cloned on a plasmid possessing both E. coli and Saccharomyces cerevisiae replication origins. This plasmid, pEH25, transformed leuA, leuB, and leuD auxotrophs of E. coli to prototrophy; it also transformed leu2 auxotrophs of S. cerevisiae to prototrophy. beta-Isopropylmalate dehydrogenase was encoded by the leuB gene of E. coli and the leu2 gene of yeast. Verification that the leuB gene present on pEH26 was responsible for complementing yeast leu2 was obtained by isolating in E. coli several leuB mutations that resided on the plasmid. These mutant leuB- plasmids were no longer capable of complementing leu2 in S. cerevisiae. We conclude that S. cerevisiae is capable of transcribing at least a portion of the polycistronic leu operon of E. coli and can translate a functional protein from at least the second gene of this operon. The yeast Leu+ transformants obtained with pEH25, when cultured in minimal medium lacking leucine, grew with a doubling time three to four times longer than when cultured in medium supplemented with leucine.     

Molecular cloning of a gene affecting the autolysin level and flagellation in Bacillus subtilis

A 2.8 kb PstI fragment of Bacillus subtilis 168W DNA has been cloned into Escherichia coli HB101 and B. subtilis AG5 using pAC3 as a shuttle plasmid. The new plasmid (pBRG1), of 10.2 kb, complemented flaD mutations which show reduced production of autolysin(s), filamentation and non-motility (deficiency of flagella). Deletion experiments showed that the suppressive gene is located between the HindIII and XbaI sites (1.0 kb apart) in pBRG1. The integration of a plasmid having chloramphenicol resistance closely linked to the flaD gene into the B. subtilis AC703 chromosome and its genetic analysis indicated that the cloned fragment contained the flaD gene itself. A high-copy-number plasmid carrying the cloned gene did not lead to an increase in autolysin production above the wild-type level, but it changed the colony morphology from smooth to rough. Among several autolysin-deficient mutations, lyt-151 was suppressed only by the high-copy-number plasmid carrying the cloned gene.     

Complementation of argG and hisA mutations of Escherichia coli by DNA cloned from the archaebacterium Methanococcus voltae

DNA derived from the methanogenic archaebacterium Methanococcus voltae was digested with PstI restriction endonuclease and cloned into the PstI site of pBR322. The recombinant plasmids generated were used to transform a multiply auxotrophic strain of Escherichia coli with selection for tetracycline resistance. Plasmids complementing the argG(pAW1) or hisA(pAW2) mutations were isolated and characterized. Nick-translated pAW1 and pAW2 hybridized to the predicted M. voltae PstI fragments but not to digested E. coli DNA. A novel 55,000-dalton protein was synthesized in UV-irradiated cells by pAW1, whereas pAW2 synthesized a novel 26,000-dalton protein. Derivatives of pAW1 carrying insertion elements no longer complemented the argG mutation and failed to produce the 55,000-dalton protein. When an AccI fragment was deleted from pAW2, complementation of hisA did not occur and no 26,000-dalton protein was synthesized. The effect of orientation of the cloned DNA within the vector on complementation and polypeptide synthesis was examined.     

Molecular cloning of a tetracycline-resistance determinant from Bacillus subtilis chromosomal DNA and its expression in Escherichia coli and B. subtilis

Bacillus subtilis GSY908 DNA fragments (5.1 and 4.4 kilobase pairs (kb)) containing a tetracycline-resistance determinant were cloned in Escherichia coli using a shuttle plasmid vector pLS353. Restriction endonucelase analysis showed that the 4.4 kb fragment is a spontaneous deletion derivative of the 5.1 kb fragment. E. coli tetracycline-resistance transformants carrying pLS353 with the 5.1 kb fragment (named pTBS1) and that with 4.4 kb fragment (pTBS1.1) could grow at tetracycline concentrations up to 80 and 50 micrograms per ml, respectively. B. subtilis MI112 and RM125 were transformed by pTBS1, resulting in isolation of transformants of MI112 maintaining pTBS1 and RM125 maintaining either pTBS1 or pTBS1.1. Maximum tetracycline concentrations permitting growth of plasmidless MI112 and MI112 with pTBS1 were 4 and 10 micrograms per ml, respectively, while those of plasmidless RM125, RM125 with pTBS1 and RM125 with pTBS1.1 were 7, 50 and 80 micrograms per ml, respectively. It was interesting to note that the tetracycline-resistance level in E. coli conferred by the 5.1 kb fragment is higher than that conferred by the 4.4 kb fragment, but in B. subtilis the 4.4 kb fragment, in contrast, confers a higher level of tetracycline resistance. The level of tetracycline resistance in B. subtilis conferred by the cloned determinant clearly depends on the host strain. The tetracycline resistance conferred by the cloned determinant was associated with decreased accumulation of the drug into the cells. However, it was constitutive in E. coli, but inducible in B. subtilis. The cloned tetracycline-resistance determinant was detected specifically on the chromosome of B. subtilis Marburg 168 derivatives.     

Cloning of an unstable spoIIA-tyrA fragment from Bacillus subtilis

A recombinant cosmid clone was isolated from a library created from cosmid pQB79-1 and Bacillus subtilis DNA, and a 15 kb BamHI fragment derived from the cloned insert was transferred to the vector pHV33. The recombinant clone, pRC12, was capable of complementing eight auxotrophic markers in the spoIIA-tyrA region of the B. subtilis chromosome (map positions 205-210). It also complemented eight of nine markers in the spoIIA locus. The exception, spoIIA176, is the most distal marker from lysine. Although pRC12 failed to complement sporulation defects in spoVA or spoIVA (spoIIA+) strains, subclones of pRC12, lacking a functional spoIIA gene, did complement these mutations. pRC12 inhibited sporulation in a spo+ recE strain, possibly due to the presence of multiple functional spoIIA genes. Both the original cosmid and pRC12 were unstable in Escherichia coli and B. subtilis. Antibiotic selection of the vector resulted in extensive deletion of the insert, while selection for insert function in B. subtilis invariably led to loss of the chloramphenicol resistance vector function.     

Interspecific transformation of Bacillus subtilis competent cells by chromosomal DNA in lysates of protoplasts of Bacillus amyloliquefaciens

Competent cells of Bacillus subtilis were transformed with chromosomal DNA in lysates of protoplasts of B. subtilis or B. amyloliquefaciens. The interspecific transformation frequency of B. subtilis by cysA in a conserved region was 3.1 x 10(4) transformants per microg DNA, 60 times higher than that for conventional transformation using purified DNA. Increased interspecific transformation frequencies of B. subtilis were also observed for arg-1, lys-1, leuB, aroG, thr-5, hisH, or metC markers outside the conserved region (3.1 x 10 approximately 5.2 x 10(2) transformants per microg DNA). An interspecific cotransformation ratio (33-50%) as high as an intraspecific one (46%) using purified DNA was also detected between cysA and rpsL markers, which are separated by 16 kb on the B. subtilis chromosome. Interspecific double transformation of the cysA-arg-1 or cysA-metC marker was observed, which have not been detected for conventional transformation. The involvement of mutS in the interspecific transformation was not significant.     

A method for construction of specialized transducing phage rho 11 of Bacillus subtilis.

DNA from a temperate phage rho 11 and chromosomal DNA of Bacillus subtilis 168 were digested with endonuclease EcoRI and then ligated with T4 polynucleotide ligase. The ligated DNA fragments were used to transform a lysogenic strain, B. subtilis spoA12 lys21 hisA1 leuA8 p11, and Lys+, His+ or Leu+ transformants were selected. The cells of each type were then mixed, grown and treated with mitomycin C; the induced phages were tested for abilities abilities to form plaques and to tranduce the auxotrophic marker. Various types of plaque-forming or defective phages which transduce hisA or lys marker at considerably high frequencies were thus obtained.     

Precise mapping of the gpp gene involved in guanosine tetraphosphate synthesis and ilvC-gpp deletion in the region of the Escherichia coli chromosome

Using the set of transducing lambda phages the gpp gene, responsible for pppGpp to ppGpp conversion, was localized between rep and trxA genes on 85 min of the Escherichia coli genetic map. Taking advantage of the Tn10 transposon inserted into the adjacent ilvY locus, we deleted the region of E. coli chromosome covering ilvC, rep and gpp genes. The metabolism of (p)ppGpp in the deletion-containing cells confirms that the product of the gpp gene, guanosine pentaphosphatase, is not the only enzyme, responsible for pppGpp degradation and ppGpp synthesis.     

Interaction of the Bacillus subtilis DnaA-like protein with the Escherichia coli DnaA protein.

Plasmids carrying the intact Bacillus subtilis dnaA-like gene and two reciprocal hybrids between the B. subtilis and Escherichia coli dnaA genes were constructed. None of the plasmids could transform wild-type E. coli cells unless the cells contained surplus E. coli DnaA protein (DnaAEc). A dnaA (Ts) strain integratively suppressed by the plasmid R1 origin could be transformed by plasmids carrying either the B. subtilis gene (dnaABs) or a hybrid gene containing the amino terminus of the E. coli gene and the carboxyl terminus of the B. subtilis gene (dnaAEc/Bs). In cells with surplus E. coli DnaA protein, expression of the E. coli dnaA gene was derepressed by the B. subtilis DnaA protein and by the hybrid DnaAEc/Bs protein, whereas it was strongly repressed by the reciprocal hybrid protein DnaABs/Ec. The plasmids carrying the different dnaA genes probably all interfere with initiation of chromosome replication in E. coli by decreasing the E. coli DnaA protein concentration to a limiting level. The DnaABs and the DnaAEc/Bs proteins effect this decrease possibly by forming inactive oligomeric proteins, while the DnaABs/Ec protein may decrease dnaAEc gene expression.     

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.     

Genes and their organization in the replication origin region of the bacterial chromosome

Genes and their organization are conserved in the replication origin region of the bacterial chromosome. To determine the extent of the conserved region in Gram-positive and Gram-negative bacteria, which diverged 1.2 billion years ago, we have further sequenced the region upstream from the dnaA genes in Bacillus subtilis and Pseudomonas putida. Fifteen open reading frames (ORFs) and 11 ORFs were identified in the 13.6 kb and the 9.8 kb fragments in B. subtilis and P. putida, respectively. Eight consecutive P. putida genes, except for one small ORF (homologous to gene 9K of Escherichia coli) in between, are homologous in sequence and relative locations to genes in B. subtilis. Altogether, 12 genes and their organization are conserved in B. subtilis and P. putida in the origin region. We found that the conserved region terminated on one side after the orf290 in P. putida (orf282 in B. subtilis). In the B. subtilis chromosome, five additional ORFs were found in between the conserved genes, suggesting that they are added after Gram-positive bacteria were diverged from the Gram-negative bacteria. One of the ORFs is a duplicate of the conserved gene. The third non-translatable region containing multiple repeats of DnaA-box (second in the case of P. putida) was found flanking gidA in both organisms. This result shows clearly that E. coli oriC and flanking genes gidA and gidB have been translocated by the inversion of some 40 kb fragment.