The recE(A)+ gene of B subtilis and its gene product: further characterization of this universal protein

Although the SOS system of E coli and the SOB system of B subtilis share many similarities, there are distinct differences with respect to the regulation and specificity of the phenomena that constitute these global regulons. One of these differences resides in the regulation of the respective RecA and RecA-like proteins. In B subtilis the RecA-like protein, the RecE protein, shares 60% amino acid homology with its E coli counterpart. The E coli recA gene can complement most, but not all, of the functions that are lost in strains of B subtilis that do not produce a functional RecE protein. The DNA sequence of the recE+ gene as well as the sequence of the recE4 allele and the recA73 allele of B subtilis has demonstrated that mutants of the recE and recA loci of this bacterium actually represent alleles of the same complex gene. Accordingly, the major recombination protein of B subtilis should be referred to as RecA and the gene that encodes this protein as recA+.     

纳豆芽胞杆菌16S rRNA基因的克隆及其系统进化分析

纳豆芽胞杆菌是从豆豉中分离出的一种具有益生功能的芽胞杆菌。该研究从纳豆芽胞杆菌提取基因组DNA,以芽胞杆菌16S rRNA基因的通用引物,用PCR方法成功扩增出纳豆芽胞杆菌的部分16S rRNA基因,所克隆序列长1 435 bp,G＋C含量为55%,该序列已被GeneBank收录,其编号为AY864812。BLAST分析结果显示,AY864812与GeneBank中收录的枯草芽胞杆菌16S rRNA基因同源性最高,其中与AY601722的同源性为100%.用Clustalx 1.8对相关序列进行系统进化分析,结果显示纳豆芽胞杆菌与枯草芽胞杆菌在进化关系上的地位最近,从分子水平上证实了纳豆芽胞杆菌是枯草杆菌的1个亚种。     

Sequence of the Bacillus subtilis glutamine synthetase gene region

The nucleotide sequence of the glutamine synthetase (GS) region of Bacillus subtilis has been determined and found to contain several unique features. An open reading frame (ORF) upstream of the GS structural gene is part of the same operon as GS and is involved in regulation. Two downstream ORFs are separated from glnA by an apparent Rho-independent termination site. One of the downstream ORFs encodes a very hydrophobic polypeptide and contains its own potential RNA polymerase and ribosome-binding sites. The derived amino acid (aa) sequence of B. subtilis GS is similar to that of several other prokaryotes, especially to the GS of Clostridium acetobutylicum. The B. subtilis and C. acetobutylicum enzymes differ from the others in the lack of a stretch of about 25 aa as well as the presence of extra cysteine residues in a region known to contain regulatory as well as catalytic mutations. The region around the tyrosine residue that is adenylylated in GS from many species is fairly similar in the B. subtilis GS despite its lack of adenylylation.     

The blasticidin S resistance gene (bsr) selectable in a single copy state in the Bacillus subtilis chromosome

The blasticidin S resistance gene (bsr), originally isolated from Bacillus cereus, was studied in Bacillus subtilis. It was found that a 617 bp fragment including the intact bsr gene and its 5' flanking region could confer BS resistance on B. subtilis when integrated in its chromosome, even in a single copy state. The construction of a bsr gene cassette and its practical application as a novel selection marker for B. subtilis are reported.     

A cluster of nine tRNA genes between ribosomal gene operons in Bacillus subtilis.

A cluster of nine tRNA genes located in the 1-kb region between ribosomal operons rrnJ and rrnW in Bacillus subtilis has been cloned and sequenced. This cluster contains the genes for tRNA(UACVal), tRNA(UGUThr), tRNA(UUULys), tRNA(UAGLeu). tRNA(GCCGly), tRNA(UAALeu), tRNA(ACGArg), tRNA(UGGPro), and tRNA(UGCAla). The newly discovered tRNA gene cluster combines features of the 3'-end of trnI, a cluster of 6 tRNA genes between ribosomal operons rrnI and rrnH, and of the 5'-end of trnB, a cluster of 21 tRNA genes found immediately 3' to rrnB. Neither the tRNA(UAGLeu) gene nor its product has been found previously in B. subtilis. With the discovery of this new set of tRNA genes, a total of 60 such genes have now been found in B. subtilis. These known genes account for almost all of the tRNA hybridizing restriction fragments of the B. subtilis genome. The 60 known tRNA genes of B. subtilis code for only 28 different anticodons, compared with a total of 41 different anticodons for 78 tRNA genes in Escherichia coli. This may indicate that B. subtilis does not need as many anticodons because of more flexible translation rules, similar to the situation in Mycoplasma capricolum.     

Genetic mapping in Bacillus subtilis 168 of the aadK gene which encodes aminoglycoside 6-adenylyltransferase

Abstract Bacillus subtilis 168 has an aadK gene, which encodes aminoglycoside 6-adenylyltransferase, a streptomycin-modifying enzyme, on its chromosome. To characterize the aadK gene, we con tructed a B. subtilis 168 strain that carried the chloramphenicol resistance gene near the aadK on the chromosome and an aadK deletion mutant using an integration technique. The aadK gene was mapped between azlB and pheA on the chromosome of B. subtilis 168. The aadK deletion mutant was slightly more susceptible to streptomycin than the original strain. The result indicates that the aadK gene contributes low-level resistance to streptomycin in B. subtilis 168.     

Expression of the promoter for the maltogenic amylase gene in Bacillus subtilis 168

An additional amylase, besides the typical alpha-amylase, was detected for the first time in the cytoplasm of B. subtilis SUH4-2, an isolate from Korean soil. The corresponding gene (bbmA) encoded a maltogenic amylase (MAase) and its sequence was almost identical to the yvdF gene of B. subtilis 168, whose function was unknown. Southern blot analysis using bbmA as the probe indicated that this gene was ubiquitous among various B. subtilis strains. In an effort to understand the physiological function of the bbmA gene in B. subtilis, the expression pattern of the gene was monitored by measuring the beta-galactosidase activity produced from the bbmA promoter fused to the amino terminus of the lacZ structural gene, which was then integrated into the amyE locus on the B. subtilis 168 chromosome. The promoter was induced during the mid-log phase and fully expressed at the early stationary phase in defined media containing beta-cyclodextrin (beta-CD), maltose, or starch. On the other hand, it was kept repressed in the presence of glucose, fructose, sucrose, or glycerol, suggesting that catabolite repression might be involved in the expression of the gene. Production of the beta-CD hydrolyzing activity was impaired by the spo0A mutation in B. subtilis 168, indicating the involvement of an additional regulatory system exerting control on the promoter. Inactivation of yvdF resulted in a significant decrease of the beta-CD hydrolyzing activity, if not all. This result implied the presence of an additional enzyme(s) that is capable of hydrolyzing beta-CD in B. subtilis 168. Based on the results, MAase encoded by bbmA is likely to be involved in maltose and beta-CD utilization when other sugars, which are readily usable as an energy source, are not available during the stationary phase.     

Cloning in Escherichia coli of the gene specifying the DNA-entry nuclease of Bacillus subtilis

With the aim of cloning genes involved in transformation of Bacillus subtilis, a set of transformation-deficient mutants was isolated by means of insertional mutagenesis with plasmid pHV60 (Vosman et al., 1986). Analysis of these mutants showed that those mapping in the aroI region lacked the DNA-entry nuclease activity. Plasmid pHV60 derivatives, containing flanking chromosomal DNA fragments, were isolated from these mutants and were used to screen a library of B. subtilis chromosomal DNA in phage lambda EMBL4. In Escherichia coli lysates, prepared with the phages that hybridized to the pHV60-based probe, a prominent nuclease activity could be detected. The nuclease encoded by the phage DNA had the same Mr as the B. subtilis DNA-entry nuclease and its activity was strongly stimulated by Mn2+, which is also characteristic for the B. subtilis DNA-entry nuclease. From these results it was concluded that the gene specifying the B. subtilis DNA-entry nuclease had been cloned. It was shown that the nuclease activity was specified by a 700-bp EcoRI-PstI fragment.     

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.     

Cloning, sequencing, and expression in Escherichia coli of the Bacillus subtilis gene for phosphatidylserine synthase.

The Bacillus subtilis pss gene encoding phosphatidylserine synthase was cloned by its complementation of the temperature sensitivity of an Escherichia coli pssA1 mutant. Nucleotide sequencing of the clone indicated that the pss gene encodes a polypeptide of 177 amino acid residues (deduced molecular weight of 19,613). This value agreed with the molecular weight of approximately 18,000 observed for the maxicell product. The B. subtilis phosphatidylserine synthase showed 35% amino acid sequence homology to the yeast Saccharomyces cerevisiae phosphatidylserine synthase and had a region with a high degree of local homology to the conserved segments in some phospholipid synthases and amino alcohol phosphotransferases of E. coli and S. cerevisiae, whereas no homology was found with that of the E. coli counterpart. A hydropathy analysis revealed that the B. subtilis synthase is very hydrophobic, in contrast to the hydrophilic E. coli counterpart, consisting of several strongly hydrophobic segments that would span the membrane. A manganese-dependent phosphatidylserine synthase activity, a characteristic of the B. subtilis enzyme, was found exclusively in the membrane fraction of E. coli (pssA1) cells harboring a B. subtilis pss plasmid. Overproduction of the B. subtilis synthase in E. coli cells by a lac promoter system resulted in an unusual increase of phosphatidylethanolamine (up to 93% of the total phospholipids), in contrast to gratuitous overproduction of the E. coli counterpart. This finding suggested that the unusual cytoplasmic localization of the E. coli phosphatidylserine synthase plays a role in the regulation of the phospholipid polar headgroup composition in this organism.     

Characterization and mapping of the Bacillus subtilis prtR gene.

A gene from Bacillus natto encoding a 60-amino-acid peptide has been previously described that, when cloned on a high-copy plasmid in B. subtilis, enhances production of alkaline protease, neutral protease, and levansucrase. An identical gene was isolated from B. subtilis and caused a similar phenotype when placed on a high-copy plasmid. Genetic mapping localized this gene near metB, distant from other pleiotropic genes causing similar effects. Deletion of this gene from the B. subtilis chromosome had no obvious phenotypic effect.     

Expression of the gene for Bacillus subtilis aspartokinase II in Escherichia coli

The gene coding for the subunits of aspartokinase II from Bacillus subtilis has been identified in a B. subtilis DNA library and cloned in a bacterial plasmid (Bondaryk, R. P., and Paulus, H. (1984) J. Biol. Chem. 259, 585-591). The introduction of a plasmid carrying the aspartokinase II gene into an auxotrophic Escherichia coli strain lacking all three aspartokinases restored its ability to grow in the absence of L-lysine, L-threonine, and L-methionine. The B. subtilis aspartokinase gene could thus be functionally expressed in E. coli and substitute for the E. coli aspartokinases. Measurement of aspartokinase levels in extracts of aspartokinaseless E. coli transformed with the B. subtilis aspartokinase II gene revealed an enzyme level comparable to that in a genetically derepressed B. subtilis strain. In spite of the high level of aspartokinase, the growth of the transformed E. coli strain was severely inhibited by the addition of L-lysine but could be restored by also adding L-homoserine. This apparently paradoxical sensitivity to lysine was due to the allosteric inhibition of B. subtilis aspartokinase II by that amino acid, a property which was also observed in extracts of the transformed E. coli strain. The synthesis and degradation of the aspartokinase II subunits were measured by labeling experiments in E. coli transformed with the B. subtilis aspartokinase II gene. In contrast to exponentially growing cells of B. subtilis which contained equimolar amounts of the aspartokinase alpha and beta subunits, the transformed E. coli strain contained a 3-fold molar excess of beta subunit. Pulse-chase experiments showed that the disproportionate level of beta subunit was not due to more rapid turnover of alpha subunit, both subunits being quite stable, but presumably to a more rapid rate of synthesis. After the addition of rifampicin, the synthesis of alpha subunit declined much more rapidly than that of beta subunit, indicating that the two subunits were translated independently from mRNA species that differ in functional stability. In conjunction with the results described in the preceding paper which demonstrated that the aspartokinase subunits are encoded by a single DNA sequence, these observations imply that the alpha and beta subunits of B. subtilis aspartokinase II are the products of in-phase overlapping genes.     

Cloning and expression of the Escherichia coli recA gene in Bacillus subtilis

By means of homopolymer dG-dC tailing, using PstI linearized pBR327 as vector, we constructed small plasmids containing the entire Escherichia coli recA gene. The 1.8-kb inserts were recloned in the Bacillus subtilis expression vector pPL608 in a B. subtilis recE4 strain. Analysis of plasmid-coded proteins showed expression of the E. coli recA gene both in minicells and whole cells of B. subtilis. Expression was under control of the bacteriophage SP02 promoter, which is part of pPL608. A recA-expressing plasmid completely abolished the transformation deficiency of the recE4 mutant as well as its sensitivity to mitomycin C (MC). The expressed recA gene also restored recombination in other B. subtilis strains lacking the recE gene product. These results indicate a high similarity between the functions of the E. coli RecA and B. subtilis RecE proteins.     

Expression of the staphylococcal protein A gene in Bacillus subtilis by gene fusions utilizing the promoter from a Bacillus amyloliquefaciens alpha-amylase gene.

Gene fusions of DNA sequences encoding protein A from Staphylococcus aureus (spa) with expression elements from an alpha-amylase gene from Bacillus amyloliquefaciens (amyEBamP) directed the synthesis and efficient secretion of protein A in Bacillus subtilis. The fusions were established on multicopy pUB110-based plasmid vectors, in contrast to the intact spa gene, which could not be stably established on plasmids in B. subtilis. Some of the resulting B. subtilis strains secreted protein A at levels in excess of 1 g/liter, demonstrating that a foreign protein encoded by an engineered gene can be secreted by B. subtilis at levels comparable to endogenous exoproteins.