Amplification and deletion of the amyE+-tmrB+ gene region in a Bacillus subtilis recombinant-phage genome by the tmrA7 mutation.

A 22.4-kilobase DNA fragment containing the tmrA7-amyR2-amyE+-tmrB+-aroI+ region of the Bacillus subtilis N7 chromosomal DNA was cloned into a recombinant B. subtilis bacteriophage, p11-AA248. The amyE+-tmrB+ gene region, approximately 12.6 kilobases, in the phage genome was amplified in a tunicamycin-resistant (Tmr) Amy+ AroI+ transductant of B. subtilis by p11-AA248. On the other hand, the amyE+-tmrB+ region in the genomes of 80 to 90% of the phage particles was deleted when the phages were induced from the Tmr Amy+ AroI+ transductants by treatment with 1.0 micrograms of mitomycin C per ml. From analyses of the physical maps and DNA nucleotide sequences in the junction region of the deleted phage genome and the parental DNA fragments, it is suggested that the deletion occurred within a direct repeat sequence composed of 18 base pairs. The endpoints of the amplified gene region seemed to be closely related to both terminal regions of the deleted DNA.     

Conditional lethal phosphatidylserine decarboxylase mutants of Escherichia coli

Summary The final step in the biosynthesis of phosphatidylethanolamine, the major membrane lipid of Escherichia coli, is catalyzed by the membrane-bound enzyme, phosphatidylserine decarboxylase. A variation of a procedure for localized mutagenesis (Hong and Ames, 1971) was employed to generate conditional lethal mutants in phosphatidylserine decarboxylase. In our modification, an episome carrying the psd gene closely linked to purA ⁺ was heavily mutagenized in vivo in a strain also lysogenic for phage P1 CMclr100. After induction of a phage lytic cycle, the purA ⁺ marker was transduced to a purA ^- recipient. A majority of the Pur⁺ transductants thus contained a psd gene originating from the heavily mutagenized episomal strain. Three mutants were isolated in which temperature-sensitive growth is caused by thermosensitive phosphatidylserine decarboxylase activity that is defective in vivo at the non-permissive temperature. All 3 mutations were mapped at the same location as psd1, being cotransduced with melA, purA, and ampA. The gene order in this region, as determined by a phage P1-mediated, three-factor cross is ampA-psd-purA. psd ⁺ is dominant to the psd mutant alleles.     

Biological assay of prokaryotic genes in mouse cells following DNA mediated transformation

Summary Genes coding for leucine biosynthesis in Bacillus subtilis were introduced into mouse LTK^- cells by co-transformation with thymidine kinase⁺ (tk) DNA. Genomic DNA from the tk⁺ transformants was used to transform competent cultures of different B. subtilis leucine auxotrophs. Each auxotroph was transformed to prototrophy at a similar frequency and the number of leucine gene sequences per transformant genome as deduced by the B. subtilis bioassay strongly correlated with the number estimated by hybridization methods. Tk^- subclones were obtained by plating the transformants in 5-bromodeoxyuridine. One subclone still contained the non-selected leucine gene sequences and could transform auxotrophs of B. subtilis. No deletions or rearrangements in the linkage relationships of the leucine genes occurred in the LTK^- cells that inhibited transformation of B. subtilis.     

W-mutagenesis in competent cells of Bacillus subtilis

Summary The relative yield (N _m/N) of fluorescent mutants Ind^- after the transformation of Bacillus subtilis cells by means of UV-irradiated DNA is much higher in an uvr ^- recipient than in an uvr ⁺ strain, when compared at equal fluence, but practically identical at equal survival. Ind^- mutations are induced by UV-irradiation of separated single strands of transforming DNA. The H-strand is much more sensitive to the mutagenic action of UV light. Preliminary irradiation of competent recipient cells by moderate UV fluences increases the survival of UV-or -irradiated transforming DNA (W-reactivation) and the frequency of Ind^- mutations (W-mutagenesis). During transfection of B. subtilis cells by UV-irradiated prophage DNA isolated from lysogenic cells B. subtilis (Ø105 c ⁺) c-mutants of the phage are obtained in high yield only in conditions of W-mutagenesis, i.e. in UV-irradiated recipient cells. These data show that there is no substantial spontaneous induction of error-prone SOS-repair system in the competent cells of B. subtilis.     

Genetic and physical characterization of the ColIb plasmid using ColIb-R222 hybrids

Summary The presence of the ColIb plasmid in Escherichia coli cells inhibits the growth of bacteriophages BF23 and T5 (Ibf phenotype; inhibition of BF23 and T5 growth). To understand this abortive infection, we devised a method of isolating mutants that were defective in some ColIb phenotypes including Ibf. This method consisted of transduction of the tet (Tc^r; tetracycline resistance) or cml (Cm^r; chloramphenicol resistance) gene of plasmid R222 with phage P22 into ColIb, construction of Tc^rCm^rIbf⁺ Imm⁺ (immunity to colicin Ib) Cib^- (no production of colicin Ib) recombinants by crossing between the transductants, and isolation of deletion mutants from the recombinants by phage P1 transduction. By this procedure, pKM25-2 (Tc^rCm^sIbf^-Imm^-Cib^-) and pKM25-1 (Tc^rCm^sIbf⁺Imm⁺Cib^-) were isolated. Construction of the cleavage map of the ColIb plasmid by restriction endonucleases and comparative analyses of the DNA fragments produced from the mutant plasmids revealed that the genes determining Ibf and Imm mapped on a 4.60 Mdal HindIII fragment (H-3) and the gene determining Cib on a 1.71 Mdal EcoRI fragment (E-12).These results together with other observations (Wilkins et al. 1981; Hama personal communication) also show the approximate positions of the genes for Rep (replication), Inc (incompatibility), and Sog (suppression of dnaG) as well as Ibf, Imm, and Cib phenotypes on the cleavage map of the ColIb plasmid.Preliminary data were reported in the 1979 Annual Meeting of the Japan Molecular Biology Society (Uemura and Mizobuchi, Abst Ann Mol Biol Meet 1979, p 36)     

Host-controlled modification and restriction in Bacillus subtilis: Bsu 168-system and BsuR-system in B. subtilis 168.

Summary A Bsu168-specific restriction deficient (r ₁₆₈ ^- ) mutant of Bacillus subtilis Marburg 168 was transformed to be BsuR-specific restriction proficient (r _R ⁺ ) with B. subtilis R DNA as efficiently as the Bsu168-specific restriction proficient (r ₁₆₈ ⁺ ) parental strain (hsrM ⁺, hsdR ^-).We constructed r _R ⁺ m _R ⁺ r ₁₆₈ ⁺ m ₁₆₈ ⁺ strain (ISMR 4), r _R ⁺ m _R ⁺ r ₁₆₈ ^- m ₁₆₈ ⁺ strain (ISR 11) and r _R ⁺ m _R ⁺ r ₁₆₈ ^- m ₁₆₈ ^- strain (ISR 6) from strain 101 (r ₁₆₈ ⁺ m ₁₆₈ ⁺ ), strain 1012 (r ₁₆₈ ^- m ₁₆₈ ⁺ ) and strain RM125 (r ₁₆₈ ^- m ₁₆₈ ^- ), respectively by transformation with B. subtilis R DNA, and tested their restriction and modification activities on phage 105C. The results show that the sites recognized by Bsu168-specific restriction and modification enzymes and the sites recognized by BsuR-specific ones are not overlapping.We conclude that the Bsu168-modification and restriction system and the BsuR-modification and restriction system are controlled independently by two distinct sets of genes in the r _R ⁺ m _R ⁺ transformant of r ₁₆₈ ⁺ m ₁₆₈ ⁺ strain B. subtilis 168.     

Restriction of plasmid-mediated transformation in Bacillus subtilis 168.

Summary When plasmids carrying leucine genes of Bacillus subtilis 168 were isolated from a restriction and modification deficient (r^-m^-) strain and used for transformation of a restricting strain B. subtilis 168 leu recE4, the number of transformants was greatly reduced. Transformation of a rec ⁺ strain (transformation by integration of the donor DNA into the chromosome) with the plasmids was not affected irrespective of whether the recipient carried the r⁺ or r^- phenotype. These results show that the plasmid-mediated transformation is subject to the host controlled restriction and suggest that r^-m^- strains should be used for construction of recombinant DNA molecules in B. subtilis 168.     

Identification of the Product of Sporulation Gene spo0B in Bacillus subtilis

A 1.4-megadalton EcoRI restriction fragment carrying Bacillus subtilis sporulation gene spo0B was cloned from the specialized transducing phage, φ 105spo0B, into a unique EcoRI site of plasmid vector pUB110, and four plasmids having a deletion in the 1.4-megadalton EcoRI fragment were constructed. Analysis of the polypeptides synthesized in B. subtilis minicells harboring these plasmids and the sporulation ability of strain UOT0436 (spo0B136 recE4) harboring these plasmids showed that the spo0B gene product is a polypeptide of 24,000 daltons. Two-dimensional polyacrylamide gel analysis showed that the isoelectric point of this protein is almost neutral.     

Cloning and expression of Bacillus subtilis spore genes

Summary Two spore genes, spoOB and spoIIG have been cloned from the B. subtilis genome library, constructed by ligating Sau3A partially digested DNA to the dephosphorylated pHV33 plasmid vector at its BamH1 site.An hybrid plasmid pGsOB2, carrying a 1.7 Kb insert of B. subtilis DNA amplifiable in E. coli was cloned. This recombinant plasmid was capable of transforming the appropriate B. subtilis Rec⁺ and Rec^- recipients to Spo⁺ at very high efficiency. The pGsOB2 was further subcloned and four hybrid plasmids, pGsOB8, pGsOB9, pGsOB10 and pGsOB11 were selected and their restriction enzyme maps established. The four subcloned hybrid plasmids retained their entire transforming activity in both Rec⁺ and Rec^- recipients although two of them carry the insert in an inverse orientation, indicating thus, that the spoOB gene in these plasmids is being transcribed by the B. subtilis RNA polymerase using an internal promotor of the cloned DNA fragment. The adjacent genes spoIVF and pheA, mapped respectively to the right and left of the spoOB locus, that normally show 90% cotransformation, are absent on the cloned DNA fragments. The cloned hybrid plasmids have been expressed in E. coli minicells and it was shown that the spoOB locus encoded a polypeptide of 24 K.We have also cloned the spoIIG gene in two hybrid plasmids, pGsIIG24 and pGsIIG26, carrying respectively inserts of 2 and 3 Kb. From the transforming activity and the endonuclease cleavage maps it was shown that these two hybrid plasmids do not carry the entire spoIIG locus. The use of these plasmids for further cloning of this gene is discussed.     

Genetic engineering of Bacillus subtilis for the commercial production of riboflavin

Recombinant DNA engineering was combined with mutant selection and fermentation improvement to develop a strain of Bacillus subtilis that produces commercially attractive levels of riboflavin. The B. subtilis riboflavin production strain contains multiple copies of a modified B. subtilis riboflavin biosynthetic operon (rib operon) integrated at two different sites in the B. subtilis chromosome. The modified rib operons are expressed constitutively from strong phage promoters located at the 5′ end and in an internal region of the operon. The engineered strain also contains purine analog-resistant mutations designed to deregulate the purine pathway (GTP is the precursor for riboflavin), and a riboflavin analog-resistant mutation in ribC that deregulates the riboflavin biosynthetic pathway. Received 22 June 1998/ Accepted in revised form 6 November 1998     

Replication of the mini-R1 plasmid Rsc11 and Rsc11 hybrid plasmids

Summary The DNA polymerase induced by bacteriophage T7 is composed of a phage-specified subunit, the gene 5 protein, and a host-specified subunit, the 12,000 dalton thioredoxin of Escherichia coli. tsnC mutants of E. coli B (Chamberlin, 1974) have no detectable thioredoxin, and thus cannot support the growth of phage T7, although they are killed by phage infection. A mutant of E. coli K12 affecting thioredoxin has been isolated by a modification of the procedure used by Chamberlin (1974) to isolate tsnC mutants of E. coli B. The gene affecting thioredoxin has been designated trxA. This mutant, E. coli JM109, shows the TsnC phenotype in that it is killed by, but cannot support the growth of, bacteriophage T7. T7 DNA replication does not occur in mutantinfected cells. These phenotypic expressions of the tsnC mutation have enabled us to screen recombinants for the trxA allele in HfrxF^- crosses and F-ductants in episome transfer experiments. Extracts of transductants in generalized transduction by P1 phage were screened for their ability to complement partially purified phage T7 gene 5 protein to form T7 DNA polymerase. The trxA gene is located at 84 min on the E. coli linkage map, between uvrE and metE; trxA is 34% co-transducible with metE.     

Relationship between rates of respiratory proton extrusion and ATP synthesis in obligately alkaliphilic Bacillus clarkii DSM 8720T

To elucidate the energy production mechanism of alkaliphiles, the relationship between the rate of proton extrusion via the respiratory chain and the corresponding ATP synthesis rate was examined in obligately alkaliphilic Bacillus clarkii DSM 8720^T and neutralophilic Bacillus subtilis IAM 1026. The oxygen consumption rate of B. subtilis IAM 1026 cells at pH 7 was approximately 2.5 times higher than that of B. clarkii DSM 8720^T cells at pH 10. The H⁺/O ratio of B. clarkii DSM 8720^T cells was approximately 1.8 times higher than that of B. subtilis IAM 1026 cells. On the basis of oxygen consumption rate and H⁺/O ratio, the rate of proton translocation via the respiratory chain in B. subtilis IAM 1026 is expected to be approximately 1.4 times higher than that in B. clarkii DSM 8720^T. Conversely, the rate of ATP synthesis in B. clarkii DSM 8720^T at pH 10 was approximately 7.5 times higher than that in B. subtilis IAM 1026 at pH 7. It can be predicted that the difference in rate of ATP synthesis is due to the effect of transmembrane electrical potential (Δψ) on protons translocated via the respiratory chain. The Δψ values of B. clarkii DSM 8720^T and B. subtilis IAM 1026 were estimated as −192 mV (pH 10) and −122 mV (pH 7), respectively. It is considered that the discrepancy between the rates of proton translocation and ATP synthesis between the strains used in this study is due to the difference in ATP production efficiency per translocated proton between the two strains caused by the difference in Δψ.     

Cloning and expression inEscherichia coli of the sucrase gene fromBacillus subtilis

Summary A recombinant cosmid carrying the sucrase gene (sacA) was obtained from a colony bank ofE. coli harboring recombinant cosmids representative of theB. subtilis genome. It was shown that thesacA gene is located in a 2 kbEcoRI fragment and that the cloned sequence is homologous to the corresponding chromosomal DNA fragment. A fragment of 2 kb containing the gene was subcloned in both orientations in the bifunctional vector pHV33 and expression was further looked for inB. subtilis andE. coli. Complementation of asacA mutation was observed in Rec⁺ and Rec^- strains ofB. subtilis. Expression of sucrase was also demonstrated inE.coli, which is normally devoid of this activity, by SDS-polyacrylamide gel electrophoresis, specific immunoprecipitation and assay of the enzyme in crude extracts. The specific activity of the enzyme depended on the orientation of the inserted fragment. The saccharolytic activity was found to be cryptic inE. coli since the presence of the recombinant plasmids did not allow the transport of [U¹⁴C] sucrose and the growth of the cells.It was shown also that the recombinant cosmid contained part of the neighboring locus (sacP) which corresponds to a component of the PEP-dependent phosphotransferase system of sucrose transport ofB. subtilis.     

Transduction in Streptomyces hygroscopicus mediated by the temperate bacteriophage SH10

Summary The temperate actinophage SH10 mediates generalized transduction in Streptomyces hygroscopicus at low frequency. The efficiency of transduction depends on the average phage input, age of outgrowing spores of the recipient and on the selective marker. The highest EOT was found for the auxotrophic mutants 21 (phe^-) and 5(try^-)(4.1x10^-6 and 2.7x10^-6, respectively). Transduction of the thermosensitive mutant NG14-216 ts 35 was two orders of magnitude lower (2.5x10^-8). The transductant colonies segregated into stable and unstable clones. Stable transductants were never found to be lysogenic for phage SH10.     

The role of the HCR system in the repair of lethal lesions ofBacillus subtilis phages and their transfecting DNA damaged by radiation and alkylating agents

The role of the HCR system in the repair of prelethal lesions induced by UV-light, γ-rays and alkylating agents was studied in theBacillus subtilis SPP1 phage, its thermosensitive mutants (N3, N73 endts ₁) and corresponding infectious DNA. The survival of phages and their transfecting DNA after treatment with UV light is substantially higher inhcr ⁺ cells than inhcr cells, the differences being more striking in intact phages than in their transfecting DNA’s. Repair inhibitors reduce the survival inhcr ⁺ cells: caffeine lowers the survival of UV-irradiated phage SPP1 in exponentially growinghcr ⁺ cells but has no effect on its survival in competenthcr ⁺ cells; acriflavin and ethidium bromide decrease the survival of UV-irradiated SPP1 phage in both exponentially growing and competenthcr ⁺ cells to the level of survival observed inhcr cells; moreover, ethidium bromide lowers the number of infective centres inhcr ⁺ cells of UV-irradiated DNA of the SPP1 phage. Repair inhibitors do not lower the survival of UV-irradiated phages or their DNA inhcr cells. The repair mechanism under study repairs effectively also lesions induced by polyfunctional alkylating agents in transfecting DNA’s ofB. subtilis phages but is not functional with lesions induced by these agents in free phages and lesions caused in phages and their DNA by ethyl methanesulphonate or γ-rays.     

Direct plasmid transfer from replica-plated E. coli colonies to competent B. subtilis cells. Identification of an E. coli clone carrying the hisH and tyrA genes of B. subtilis

Summary We have cloned the hisH tyrA wild-type genes of Bacillus subtilis with the aid of the chimeric plasmid pBJ194, which replicates both in B. subtilis and Escherichia coli. Primary cloning was done in E. coli. The original E. coli clone, carrying the recombinant plasmid (pGR1) which complements hisH tyrA mutants of B. subtilis, was selected directly from a mixture of plated E. coli clones by replicaplating these clones onto minimal agar plates without tyrosine spread just before with competent B. subtilis cells. After overnight incubation clusters of small colonies had developed exclusively in the E. coli [pGR1] colony prints.The Tyr⁺ minicolonies were shown to be B. subtilis carrying pGR1 because (i) their appearance depended linearly on the number of B. subtilis cells plated, (ii) they produced extracellular protease and amylase and (iii) plasmids could be reisolated from the minicolonies and used to transform B. subtilis recE4 tyrA1 both to Cm^r and Tyr⁺.Plasmid pGR1 transfer through replica plating was compared with plasmid transfer in liquid. Both systems depended on transformable B. subtilis strains and were sensitive to DNAseI. However, whereas integration of the tyrA ⁺ gene into the chromosome and concomittant loss of plasmids occurred frequently during regular plasmid transformation of Rec⁺ B. subtilis, this was a rare event during plasmid transfer through replica plating.     

Isolation of symbiotically defective mutants in Rhizobium leguminosarum by insertion of the transposon Tn5 into a transmissible plasmid

Summary Selection was made for the transposition of the kanamycin resistance transposon Tn5 from a location on the chromosome of R. leguminosarum into a transmissible, bacteriocinogenic plasmid that also carries genes required for the induction of nitrogen-fixing nodules on peas.One hundred and sixty independent insertions into transmissible plasmids were isolated. When these plasmids were transferred by conjugation into a non-nodulating strain, which carries a deletion in one of its resident plasmids, of the 160 isolates tested 14 yielded transconjugants that formed nodules that did not fix nitrogen (Fix^-) and in a further 15 cases the transconjugants were unable to form nodules (were Nod^-). When transferred to a symbiotically proficient strain (i.e. Nod⁺ Fix⁺) none of the transconjugants was symbiotically defective; thus the mutations were not dominant.When kan was transduced from the clones that generated Fix^- transconjugants into a Fix⁺ recipient the majority of transductants inherited Fix^- indicating that the insertion of Tn5 had induced the symbiotic mutations. Transduction of kan, from the clones that failed to donate Nod⁺ by conjugation to strain 6015, occurred at barely detectable frequencies and it was not possible to demonstrate transduction of Nod^-. kan was co-transduced with Nod⁺ from some of the clones and some of these transductants also inherited the ability to produce medium bacteriocin and to transfer at high frequency by conjugation. Thus the genes for all these characters are closely linked.     

A genetic approach to the identification of functional amino acids in protein p6 of Bacillus subtilis phage ø29

Protein p6 of the Bacillus subtilis phage ø29 is essential for in vivo viral DNA replication. This protein activates the initiation of ø29 DNA replication in vitro by forming a multimeric nucleoprotein complex at the replication origins. The N-terminal region of protein p6 is involved in DNA binding, as shown by in vitro studies with p6 proteins altered by deletions or missense mutations. We report on the development of an in vivo functional assay for protein p6. This assay is based on the ability of protein p6-producing B. subtilis non-suppressor (su ^?) cells to support growth of a ø29 sus6 mutant phage. We have used this trans-complementation assay to investigate the effect on in vivo viral DNA synthesis of missense mutations introduced into the protein p6 N-terminal region. The alteration of lysine to alanine at position 2 resulted in a partially functional protein, whereas the replacement of arginine by alanine at position 6 gave rise to an inactive protein. These results indicate that arginine at position 6 is critical for the in vivo activity of protein p6. Our complementation system provides a useful genetic approach for the identification of functionally important amino acids in protein p6.     

A bifunctional plasmid carrying the recA gene of E. coli

Summary To investigate the effect of an active, plasmid-carried recA gene on the stability and/or the expression of plasmid genes in different genetic backgrounds, we have constructed a bifunctional plasmid (able to replicate in Escherichia coli and in Bacillus subtilis). Chimeric plasmids were obtained by inserting pC194 (Ehrlich 1977) into pDR1453 (Sancar and Rupp 1979). pDR1453 is a 12.9 Kbp plasmid constructed by inserting an E. coli chromosome fragment carrying the recA gene into pBR322. The expected bifunctional recombinant (pMR22/1) (15.7 Kbp) was easily obtained but surprisingly the Cm resistance was expressed only at a very low level in E. coli (as compared, for example, to pHV14, pHV15). We attribute this effect to the presence of multiple recA genes in the cell. On the contrary, Cm^r E. coli transformants bear a recombinant plasmid (pMR22/n) containing tandemly repeated copies of pC194 in equilibrium with excised free pC194. Such amplification has never been observed in a Rec^- background and is therefore mediated by the recA genes. Growth of these clones in the absence of Cm causes the loss of the extra copies, yielding a plasmid with a single copy of pC194, indistingishable from pMR22/1. Interestingly, we have observed that deletions occur at high frequency in pC194, which drastically increase Cm^r in E. coli containing plasmids with a single copy of pC194. Two types of such deletions were detected: (a) large 1050 bp deletions covering about onethird of pC194 and (b) small 120–150 bp deletions (near the MspI site) in the region containing the replicative functions of pC194 (Horinouchi and Weisblum 1982). Both types of deletion render the recombinant plasmid unable to replicate in B. subtilis. pM22/1 replicates, although with a low copy-number, and is stable in B. subtilis wild type; the recA gene of E. coli does not complement any of the rec ^- mutations of B. subtilis. A strong instability, mainly of the E. coli and pBR322 sequences, was observed in many dna and rec mutants of B. subtilis yielding smaller plasmid with a much higher copy-number.