Analysis of the regulation of gene expression during Bacillus subtilis sporulation by manipulation of the copy number of spo-lacZ fusions.

The control of expression of the Bacillus subtilis spoIIA locus was analyzed by titrating gene expression against gene copy number. A plasmid integrated into the B. subtilis chromosome and carrying the spoIIA control region fused to Escherichia coli lacZ was forced to form tandem repeats by the selection of clones that grow on high levels of chloramphenicol, the antibiotic against which the plasmid determines resistance. DNA from the clones was digested with BglII, which did not cut in the reiterated region, and the size of the fragment was determined by orthogonal-field-alternation gel electrophoresis to determine the copy number. Most clones had fairly homogeneous copy numbers. Gene expression was monitored by beta-galactosidase activity. The results indicate that spoIIA was under positive control by a moiety present at about five copies per chromosome. Spore formation was not affected by amplification, so spoIIA-lacZ reiteration did not sequester a molecule required elsewhere for sporulation.     

Role of the Bacillus subtilis gsiA gene in regulation of early sporulation gene expression.

The Bacillus subtilis gsiA operon was induced rapidly, but transiently, as cells entered the stationary phase in nutrient broth medium. A mutation at the gsiC locus caused sporulation to be defective and expression of gsiA to be elevated and prolonged. The sporulation defect in this strain was apparently due to persistent expression of gsiA, since a gsiA null mutation restored sporulation to wild-type levels. Detailed mapping experiments revealed that the gsiC82 mutation lies within the kinA gene, which encodes the histidine protein kinase member of a two-component regulatory system. Since mutations in this gene caused a substantial blockage in expression of spoIIA, spoIIG, and spoIID genes, it seems that accumulation of a product of the gsiA operon interferes with sporulation by blocking the completion of stage II. It apparently does so by inhibiting or counteracting the activity of KinA.     

A general method for fusion of the Escherichia coli lacZ gene to chromosomal genes in Bacillus subtilis

A series of plasmids has been constructed that can be used to fuse the beta-galactosidase gene (lacZ) of Escherichia coli to chromosomal genes of Bacillus subtilis. Insertion of the lacZ gene is facilitated by the use of a selectable chloramphenicol acetyl-transferase (cat) gene. The latter is included, along with the lacZ gene, in a single DNA fragment or 'cartridge' that can be removed from the plasmid with a variety of different restriction endonucleases. Methods applicable to any cloned B. subtilis gene are described that enable the lac-cat cartridge to be inserted at specific sites, or at random, directly into the B. subtilis chromosome in a single step. These single-copy chromosomal fusions can be readily transferred, by selection for chloramphenicol resistance, to a temperate phage such as phi 105, to permit a more extensive genetic analysis of the expression of the target gene. Alternatively, the lac-cat cartridge and flanking DNA sequences can be transferred into different genetic backgrounds by transformation. These techniques have been used to construct, in a single step, lac fusions to genes in the sporulation operons spoIIA and spoVA.     

The Bacillus subtilis SinR protein is a repressor of the key sporulation gene spo0A.

SinR is a pleiotropic DNA binding protein that is essential for the late-growth processes of competence and motility in Bacillus subtilis and is also a repressor of others, e.g., sporulation and subtilisin synthesis. In this report, we show that SinR, in addition to being an inhibitor of sporulation stage II gene expression, is a repressor of the key early sporulation gene spo0A. The sporulation-specific rise in spo0A expression at time zero is absent in a SinR-overproducing strain and is much higher than normal in strains with a disrupted sinR gene. This effect is direct, since SinR binds specifically to spo0A in vitro, in a region overlapping the -10 region of the sporulation-specific Ps promoter that is recognized by E-sigma H polymerase. Methyl interference and site-directed mutagenesis studies have identified guanine residues that are important for SinR recognition of this DNA sequence. Finally, we present evidence that SinR controls sporulation through several independent genes, i.e., sp0A, spoIIA, and possibly spoIIG and spoIIE.     

Intergenic suppression of stage II sporulation defects by a mutation in the major vegetative sigma factor gene (rpoD) of Bacillus subtilis.

The Bacillus subtilis intergenic suppressor mutations crsA and rvtA, previously shown to restore sporulation competence to a variety of strains containing stage 0 sporulation defects, also suppress lesions in the stage II sporulation genes spoIIF, spoIIN and spoIIJ. They do not rescue sporulation in other stage II through stage V sporulation mutations. Cells containing spoIIN, spoIIF96 and spoIIJ::Tn917 mutations fail to transcribe spoIID, a late stage II gene. Introduction of crsA47 into spoIINts279, spoIIF96, or spoIIJ::Tn917 mutant backgrounds circumvents the need for the spoIIF, IIN, and IIJ products, restoring both expression of spoIID, and sporulation competence.     

The Bacillus subtilis spoIIA locus is expressed at two times during sporulation

Abstract The Bacillus subtilis spoIIA and spoIIAB genes were fused to the Escherichia coli lacZ gene on a novel integrational plasmid vector. The constructs were integrated into the B. subtilis chromosome, and used to show that the spoIIA locus was expressed at two times during sporulation.     

Cloning of sporulation gene spoIIG in Bacillus subtilis.

Two specialized transducing phages carrying a sporulation gene, spoIIG , of Bacillus subtilis were constructed from B. subtilis temperate phages p11 and phi 105 by the "prophage transformation" method. Restriction enzyme analysis and transformation experiments showed that the spoIIG gene was present on a 6.2 X 10(6)-dalton (6.2-Md) EcoRI fragment in both transducing phage genomes. Further analysis showed that spoIIG + transforming activity resides on a 2.25-Md EcoRI-BamHI fragment within the 6.2-Md EcoRI fragment. The 2.25-Md fragment was subcloned into the region between the EcoRI and BamHI sites of pUB110, and deletion plasmids lacking PstI or HindIII fragments within the 2.25-Md fragment were constructed. The recombinant plasmid carrying the intact spoIIG gene restored sporulation of strain HU1002 ( spoIIG41 recE4 ) to a frequency of 10(4) spores per ml and inhibited sporulation of strain 4309 ( spo + recE4 ) to a level of 10(3) spores per ml.     

Regulation of expression of genes coding for small, acid-soluble proteins of Bacillus subtilis spores: studies using lacZ gene fusions.

We constructed in-frame translational fusions of the Escherichia coli lacZ gene with four genes (sspA, sspB, sspD, and sspE) which code for small, acid-soluble spore proteins of Bacillus subtilis, and integrated these fusions into the chromosomes of various B. subtilis strains. With single copies of the fusions in wild-type B. subtilis, beta-galactosidase was synthesized only during sporulation, with the amounts accumulated being sspB much greater than sspE greater than or equal to sspA greater than or equal to sspD. Greater than 97% of the beta-galactosidase was found in the developing forespore, and the great majority was incorporated into mature spores. Less than 2% of the maximum amount of beta-galactosidase was made when these fusions were introduced into B. subtilis strains blocked in stages 0 and II of sporulation, as well as in some stage III mutants. Other stage III mutants, as well as stage IV and V mutants, had no effect on beta-galactosidase synthesis. Increasing the copy number of the sspA-, sspD-, or sspE-lacZ fusions (up to 17-fold for sspE-lacZ) in wild-type B. subtilis resulted in a parallel increase in the amount of beta-galactosidase accumulated (again only in sporulation and with greater than 95% in the developing forespore), with no significant effect on wild-type small, acid-soluble spore protein production. Similarly, the absence of one or more wild-type ssp genes or the presence of multiple copies of wild-type ssp genes had no effect on the expression of the lacZ fusions tested. These data indicate that these ssp-lacZ fusions escape the autoregulation seen for the intact sspA and sspB genes. Strikingly, the kinetics of beta-galactosidase synthesis were identical for all four ssp-lacZ fusions and paralleled those of glucose dehydrogenase synthesis. Similarly, all asporogenous mutants tested had identical effects on both glucose dehydrogenase and ssp-lacZ fusion expression.     

假单胞菌M18转录调节因子σs基因与无启动子lacZ基因融合突变株的构建和鉴定

通过菌落原位杂交和Southern杂交,从假单胞菌M18基因组文库中克隆了rpoS基因及相邻序列。为了深入研究影响rpoS基因表达的调控因素,运用同源重组技术,将无启动子β-半乳糖苷酶基因(-′lacZ)插入并融合于rpoS基因中,构建了假单胞菌M18rpoS基因突变株M18SZ。Miller法测定显示,突变株M18SZ的β-半乳糖苷酶可高达480U,而野生株检测不到β-半乳糖苷酶活性。表明,突变株中的rpoS基因与无启动子β-半乳糖苷酶基因已融合并且表达。在KMB培养基中生长量测定(OD600)的结果表明,突变株与野生株生长存在显著差异。