Hiromu Takamatsu

Essential Bacillus subtilis genes

To estimate the minimal gene set required to sustain bacterial life in nutritious conditions, we carried out a systematic inactivation of Bacillus subtilis genes. Among ≈4,100 genes of the organism, only 192 were shown to be indispensable by this or previous work. Another 79 genes were predicted to be essential. The vast majority of essential genes were categorized in relatively few domains of cell metabolism, with about half involved in information processing, one-fifth involved in the synthesis of cell envelope and the determination of cell shape and division, and one-tenth related to cell energetics. Only 4% of essential genes encode unknown functions. Most essential genes are present throughout a wide range of Bacteria, and almost 70% can also be found in Archaea and Eucarya. However, essential genes related to cell envelope, shape, division, and respiration tend to be lost from bacteria with small genomes. Unexpectedly, most genes involved in the Embden–Meyerhof–Parnas pathway are essential. Identification of unknown and unexpected essential genes opens research avenues to better understanding of processes that sustain bacterial life.

Proteomics characterization of novel spore proteins of Bacillus subtilis

The spores of Bacillus subtilis have characteristic properties and consist of complex structures including various types of proteins. To perform comprehensive analysis of the protein composition of the spores, the proteins extracted from the spore were analysed by a combination of one-dimensional PAGE and liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS) using Turboquest SEQUEST software interfaced with the DNA sequence database of B. subtilis. A total of 154 proteins were identified, and 69 of them were novel. The remaining 85 proteins have been previously reported as sporulation-specific proteins or as proteins that are synthesized in vegetative cells. The expression pattern of each gene deduced to encode novel spore proteins was analysed using a series of strains carrying a lacZ reporter gene. The results revealed that the expression of 26 genes was dependent on sporulation-specific sigma factors, namely sigma(F), sigma(E), sigma(G) and sigma(K). In this study, it is demonstrated that the combination of the techniques of SDS-PAGE and LC-MS/MS, with the mutant library of B. subtilis, is an effective tool for the analysis of complicated cellular structures.

Proteins Involved in Formation of the Outermost Layer of Bacillus subtilis Spores

To investigate the outermost structure of the Bacillus subtilis spore, we analyzed the accessibility of antibodies to proteins on spores of B. subtilis. Anti-green fluorescent protein (GFP) antibodies efficiently accessed GFP fused to CgeA or CotZ, which were previously assigned to the outermost layer termed the spore crust. However, anti-GFP antibodies did not bind to spores of strains expressing GFP fused to 14 outer coat, inner coat, or cortex proteins. Anti-CgeA antibodies bound to spores of wild-type and CgeA-GFP strains but not cgeA mutant spores. These results suggest that the spore crust covers the spore coat and is the externally exposed, outermost layer of the B. subtilis spore. We found that CotZ was essential for the spore crust to surround the spore but not for spore coat formation, indicating that CotZ plays a critical role in spore crust formation. In addition, we found that CotY-GFP was exposed on the surface of the spore, suggesting that CotY is an additional component of the spore crust. Moreover, the localization of CotY-GFP around the spore depended on CotZ, and CotY and CotZ depended on each other for spore assembly. Furthermore, a disruption of cotW affected the assembly of CotV-GFP, and a disruption of cotX affected the assembly of both CotV-GFP and CgeA-GFP. These results suggest that cgeA and genes in the cotVWXYZ cluster are involved in spore crust formation.

The Bacillus subtilis yabG gene is transcribed by SigK RNA polymerase during sporulation, and yabG mutant spores have altered coat protein composition.

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 SigK-dependent 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.

Localization of Proteins to Different Layers and Regions of Bacillus subtilis Spore Coats

Bacterial spores are encased in a multilayered proteinaceous shell known as the coat. In Bacillus subtilis, over 50 proteins are involved in spore coat assembly but the locations of these proteins in the spore coat are poorly understood. Here, we describe methods to estimate the positions of protein fusions to fluorescent proteins in the spore coat by using fluorescence microscopy. Our investigation suggested that CotD, CotF, CotT, GerQ, YaaH, YeeK, YmaG, YsnD, and YxeE are present in the inner coat and that CotA, CotB, CotC, and YtxO reside in the outer coat. In addition, CotZ and CgeA appeared in the outermost layer of the spore coat and were more abundant at the mother cell proximal pole of the forespore, whereas CotA and CotC were more abundant at the mother cell distal pole of the forespore. These polar localizations were observed both in sporangia prior to the release of the forespore from the mother cell and in mature spores after release. Moreover, CotB was observed at the middle of the spore as a ring- or spiral-like structure. Formation of this structure required cotG expression. Thus, we conclude not only that the spore coat is a multilayered assembly but also that it exhibits uneven spatial distribution of particular proteins.

kinA mRNA is missing a stop codon in the undomesticated Bacillus subtilis strain ATCC 6051

Several features distinguish laboratory and undomesticated strains of Bacillus subtilis. For example, unlike the laboratory strain 168, the undomesticated strain ATCC 6051 is deficient in sporulation in a rich sporulation medium, 2x SG. ATCC 6051 cannot induce transcription of the spoIIG operon, suggesting that this strain has a defect in initiation of sporulation. To determine the genetic difference between 168 and ATCC 6051, the DNA region responsible for the Spo(-) phenotype was transferred to strain 168. Genetic mapping and DNA sequencing analysis revealed that a stop codon (TAA) for kinA in 168 is replaced with Lys (TAT) in ATCC 6051, making the kinA open reading frame 201 bp longer in the undomesticated strain ATCC 6051. Introduction of kinA from strain 168 restored sporulation in ATCC 6051, indicating that the difference in kinA is responsible for the Spo(-) phenotype of ATCC 6051. A potential rho-independent terminator is located upstream of a stop codon for the extended kinA open reading frame in ATCC 6051. Northern blot analysis showed that transcription of kinA terminated at this terminator, and kinA mRNA is missing a stop codon in ATCC 6051. Moreover, deletion of tmRNA suppresses the sporulation defect in ATCC 6051. These observations indicate that in ATCC 6051 the absence of a stop codon in kinA mRNA affects sporulation, probably by leading to rapid degradation of KinA via the trans-translation process. In ATCC 6051, the kinA mutation affects sporulation but not other Spo0A-dependent phenomena such as biofilm formation, which can be activated by a low level of Spo0A approximately P. This is due to the fact that KinA activity is kept low during the exponential phase via transcriptional and post-translational regulation. Thus, the stop-codon-less kinA probably affects only sporulation. DNA sequencing of 30 B. subtilis strains revealed that another strain also produces stop-codon-less kinA mRNA. This observation suggests that the lack of a stop codon for kinA mRNA may give rise to a selective advantage under certain conditions.

A Novel Lipolytic Enzyme, YcsK (LipC), Located in the Spore Coat of Bacillus subtilis, Is Involved in Spore Germination

The predicted amino acid sequence of Bacillus subtilis ycsK exhibits similarity to the GDSL family of lipolytic enzymes. Northern blot analysis showed that ycsK mRNA was first detected from 4 h after the onset of sporulation and that transcription of ycsK was dependent on SigK and GerE. The fluorescence of the YcsK-green fluorescent protein fusion protein produced in sporulating cells was detectable in the mother cell but not in the forespore compartment under fluorescence microscopy, and the fusion protein was localized around the developing spores dependent on CotE, SafA, and SpoVID. Inactivation of the ycsK gene by insertion of an erythromycin resistance gene did not affect vegetative growth or spore resistance to heat, lysozyme, or chloroform. The germination of ycsK spores in a mixture of L-asparagine, D-glucose, D-fructose, and potassium chloride and LB medium was also the same as that of wild-type spores, but the mutant spores were defective in L-alanine-stimulated germination. In addition, zymogram analysis demonstrated that the YcsK protein heterologously expressed in Escherichia coli showed lipolytic activity. We therefore propose that ycsK should be renamed lipC. This is the first study of a bacterial spore germination-related lipase.

The Bacillus subtilis yabQ gene is essential for formation of the spore cortex.

An extensive screening for transcripts with probes specific for the genes in a 108 kb region from rrnO to spo0H of the Bacillus subtilis chromosome led to identification of an operon, yabP--yabQ--divIC--yabR, the expression of which was initiated at the second hour of sporulation and in a sigma(E)-dependent manner. Among three y genes in the operon, deletion of the yabQ gene, which is predicted to encode a protein product of 468 residues with five membrane-spanning domains, resulted in a large decrease in numbers of chloroform-, lysozyme- and heat-resistant spores, compared to findings with the wild-type strain. Electron microscopy revealed that development of the spore cortex was blocked in the yabQ mutant. In addition, although the spore coat was visible, the inner coat layer of the mutant seemed partially detached from the outer coat. In sporangia of the strains harbouring an in-frame fusion of the green fluorescent protein gene to yabQ, fluorescence was detected around the forespore. This localization did not depend on SpoIVA or on CotE functions, both of which determine proper localization of coat proteins and cortex formation. The yabQ deletion did not affect expression of genes involved in cortex synthesis. These results suggest that the YabQ protein localizes in the membrane of the forespore and plays an important role in cortex formation.

Expression of yeeK during Bacillus subtilis Sporulation and Localization of YeeK to the Inner Spore Coat using Fluorescence Microscopy

The yeeK gene of Bacillus subtilis is predicted to encode a protein of 145 amino acids composed of 28% glycine, 23% histidine, and 12% tyrosine residues. Previous studies were unable to detect YeeK in wild-type spores; however, the 18-kDa YeeK polypeptide has been identified in yabG mutant spores. In this study, we analyze the expression and localization of YeeK to explore the relationship between YeeK and YabG. Northern hybridization analysis of wild-type RNA indicated that transcription of the yeeK gene, which was initiated 5 h after the onset of sporulation, was dependent on a SigK-containing RNA polymerase and the GerE protein. Genetic disruption of yeeK did not impair vegetative growth, development of resistant spores, or germination. Fluorescent microscopy of in-frame fusions of YeeK with green fluorescent protein (YeeK-GFP) and red fluorescent protein (YeeK-RFP) confirmed that YeeK assembles into the spore integument. CotE, SafA, and SpoVID were required for the proper localization of YeeK-GFP. Comparative analysis of YeeK-RFP and an in-frame GFP fusion of YabG indicated that YeeK colocalized with YabG in the spore coat. This is the first use of fluorescent proteins to show localization to different layers of the spore coat. Immunoblotting with anti-GFP antiserum indicated that YeeK-GFP was primarily synthesized as a 44-kDa molecule, which was then digested into a 29-kDa fragment that corresponded to the molecular size of GFP in wild-type spores. In contrast, a minimal amount of 44-kDa YeeK-GFP was digested in yabG mutant spores. Our findings demonstrate that YeeK is guided into the spore coat by CotE, SafA, and SpoVID. We conclude that YabG is directly or indirectly involved in the digestion of YeeK.

A Novel Small Protein of Bacillus subtilis Involved in Spore Germination and Spore Coat Assembly

Two small genes named sscA (previously yhzE) and orf-62, located in the prsA-yhaK intergenic region of the Bacillus subtilis genome, were transcribed by SigK and GerE in the mother cells during the later stages of sporulation. The SscA-FLAG fusion protein was produced from T5 of sporulation and incorporated into mature spores. sscA mutant spores exhibited poor germination, and Tricine–SDS–PAGE analysis showed that the coat protein profile of the mutant differed from that of the wild type. Bands corresponding to proteins at 59, 36, 5, and 3 kDa were reduced in the sscA null mutant. Western blot analysis of anti-CotB and anti-CotG antibodies showed reductions of the proteins at 59 kDa and 36 kDa in the sscA mutant spores. These proteins correspond to CotB and CotG. By immunoblot analysis of an anti-CotH antibody, we also observed that CotH was markedly reduced in the sscA mutant spores. It appears that SscA is a novel spore protein involved in the assembly of several components of the spore coat, including CotB, CotG, and CotH, and is associated with spore germination.