We collected and completely sequenced 28,469 full-length complementary DNA clones from Oryza sativa L. ssp. japonica cv. Nipponbare. Through homology searches of publicly available sequence data, we assigned tentative protein functions to 21,596 clones (75.86%). Mapping of the cDNA clones to genomic DNA revealed that there are 19,000 to 20,500 transcription units in the rice genome. Protein informatics analysis against the InterPro database revealed the existence of proteins presented in rice but not in Arabidopsis. Sixty-four percent of our cDNAs are homologous to Arabidopsis proteins.
SummaryWe have analysed the function of a gene of Bacillus subtilis, the product of which shows significant homology with eukaryotic SMC proteins essential for chromosome condensation and segregation. Two mutant strains were constructed; in one, the expression was under the control of the inducible spac promoter (conditional null) and, in the other, the gene was disrupted by insertion (disrupted null). Both could form colonies at 23ЊC but not at 37ЊC in the absence of the expression of the Smc protein, indicating that the B. subtilis smc gene was essential for cell growth at higher temperatures. Microscopic examination revealed the formation of anucleate and elongated cells and diffusion of nucleoids within the elongated cells in the disrupted null mutant grown at 23ЊC and in the conditional null mutant grown in low concentrations of IPTG at 37ЊC. In addition, immunofluorescence microscopy showed that subcellular localization of the Spo0J partition protein was irregular in the smc disrupted null mutant, compared with bipolar localization in wild-type cells. These results indicate that the B. subtilis smc gene is essential for chromosome partition. The role of B. subtilis Smc protein in chromosome partition is discussed.
The emerging field of synthetic genomics is expected to facilitate the generation of microorganisms with the potential to achieve a sustainable society. One approach towards this goal is the reduction of microbial genomes by rationally designed deletions to create simplified cells with predictable behavior that act as a platform to build in various genetic systems for specific purposes. We report a novel Bacillus subtilis strain, MBG874, depleted of 874 kb (20%) of the genomic sequence. When compared with wild-type cells, the regulatory network of gene expression of the mutant strain is reorganized after entry into the transition state due to the synergistic effect of multiple deletions, and productivity of extracellular cellulase and protease from transformed plasmids harboring the corresponding genes is remarkably enhanced. To our knowledge, this is the first report demonstrating that genome reduction actually contributes to the creation of bacterial cells with a practical application in industry. Further systematic analysis of changes in the transcriptional regulatory network of MGB874 cells in relation to protein productivity should facilitate the generation of improved B. subtilis cells as hosts of industrial protein production.
The expression of six novel genes located in the region from abrB to spoVC of the Bacillus subtilis chromosome was analyzed, and one of the genes, yabG, had a predicted promoter sequence conserved among SigKdependent genes. Northern blot analysis revealed that yabG mRNA was first detected from 4 h after the cessation of logarithmic growth (T 4 ) in wild-type cells and in a gerE36 (GerE ؊ ) mutant but not in spoIIAC (SigF ؊ ), spoIIGAB (SigE ؊ ), spoIIIG (SigG ؊ ), and spoIVCB (SigK ؊ ) mutants. The transcription start point was determined by primer extension analysis; the ؊10 and ؊35 regions are very similar to the consensus sequences recognized by SigK-containing RNA polymerase. Inactivation of the yabG gene by insertion of an erythromycin resistance gene did not affect vegetative growth or spore resistance to heat, chloroform, and lysozyme. The germination of yabG spores in L-alanine and in a mixture of L-asparagine, D-glucose, D-fructose, and potassium chloride was also the same as that of wild-type spores. On the other hand, the protein preparation from yabG spores included 15-, 18-, 21-, 23-, 31-, 45-, and 55-kDa polypeptides which were low in or not extracted from wild-type spores under the same conditions. We determined their N-terminal amino acid sequence and found that these polypeptides were CotT, YeeK, YxeE, CotF, YrbA (31 and 45 kDa), and SpoIVA, respectively. The fluorescence of YabG-green fluorescent protein fusion produced in sporulating cells was detectable in the forespores but not in the mother cell compartment under fluorescence microscopy. These results indicate that yabG encodes a sporulation-specific protein which is involved in coat protein composition in B. subtilis.
Insertional inactivation of the yrbA gene ofBacillus subtilis reduced the resistance of the mutant spores to lysozyme. The yrbA mutant spores lost their optical density at the same rate as the wild-type spores upon incubation with l-alanine but became only phase gray and did not swell. The response of the mutant spores to a combination of asparagine, glucose, fructose, and KCl was also extremely poor; in this medium yrbA spores exhibited only a small loss in optical density and gave a mixture of phase-bright, -gray, and -dark spores. Northern blot analysis of yrbA transcripts in varioussig mutants indicated that yrbA was transcribed by RNA polymerase with ςE beginning at 2 h after the start of sporulation. The yrbA promoter was localized by primer extension analysis, and the sequences of the −35 (TCATAAC) and −10 (CATATGT) regions were similar to the consensus sequences of genes recognized by ςE. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of proteins solubilized from intact yrbA mutant spores showed an alteration in the protein profile, as 31- and 36-kDa proteins, identified as YrbA and CotG, respectively, were absent, along with some other minor changes. Electron microscopic examination ofyrbA spores revealed changes in the spore coat, including a reduction in the density and thickness of the outer layer and the appearance of an inner coat layer-like structure around the outside of the coat. This abnormal coat structure was also observed on the outside of the developing forespores of the yrbA mutant. These results suggest that YrbA is involved in assembly of some coat proteins which have roles in both spore lysozyme resistance and germination.
The spore coat of Bacillus subtilis has a unique morphology and consists of polypeptides of different sizes, whose synthesis and assembly are precisely regulated by a cascade of transcription factors and regulatory proteins. We examined the factors that regulate cotS gene expression and CotS assembly into the coat layer of B. subtilis by Northern blot and Western blot analysis. Transcription of cotS mRNA was not detected in sporulating cells of ςK and gerE mutants by Northern blot analysis. By Western blot analysis using anti-CotS antibody, CotS was first detected in protein samples solubilized from wild-type cells at 5 h after the start of sporulation. CotS was not detected in the vegetative cells and spores of a gerEmutant or in the spores of mutants deficient in ςE, ςF, ςG, or ςK. CotS was detected in the sporangium but not in the spores of a cotEmutant. The sequence of the promoter region of cotS was similar to the consensus sequences for binding of ςK and GerE. These results demonstrate that ςK and GerE are required for cotS expression and that CotE is essential for the assembly of CotS in the coat. Immunoelectron microscopic observation using anti-CotS antibody revealed that CotS is located within the spore coat, in particular in the inner coats of dormant spores.
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