Study on the cell cycle of Bacillus subtilis using temperature-sensitive mutants

[Molecular biological approach to screening essential genes as potential targets for antifungal targets in pathogenic yeast Candida]

  We established a system, named ETS system, for screening and identification of essential genes from the pathogenic haploid yeast Candida glabrata by using temperature-sensitive (ts) mutants. Based on the general concepts that ts mutations are generated within essential genes in the genome by virtue of point mutation, the ETS system enabled us to screen and identify a variety of essential genes from the C. glabrata genomic DNA library as the genes that complement ts mutations. The ETS system established in the present study may provide novel potential antifungal targets.

Proteome analysis of Bacillus subtilis extracellular proteins: a two-dimensional protein electrophoretic study

To analyse the proteome of Bacillus subtilis extracellular proteins, extracellular protein samples were prepared from culture media (minimal medium containing 0.4% glucose) of parental B. subtilis 168, a secA-temperature sensitive mutant and an ffh conditional mutant, and examined by two-dimensional gel electrophoresis. Approximately 100 to 110 spots were visualized in a gel of B. subtilis 168 extracellular proteins. Over 90% and 80% of these disappeared in the absence of SecA and Ffh, respectively. Thirty-eight obvious spots on the gel of the B. subtilis 168 preparation were selected and compared with spots obtained under SecA- or Ffh-deficient conditions. The appearance of 36 of these 38 spots depended on SecA and Ffh. Nineteen additional extracellular proteins were detected in cultures maintained in cellobiose, maltose and soluble starch. Among 23 proteins of which the N-terminal amino acid sequences were determined, 17 were extracellular proteins having signal peptides in their precursor form. Two membrane proteins, Yfnl and YflE, were cleaved behind 226Ala-Tyr-Ala228 and 213Ala-Leu-Ala215, respectively, and of which products seemed to be liberated into the culture medium. The production of Yfnl and YflE were also dependent on SecA and Ffh. These results indicate that most extracellular proteins target to and translocate across the cytoplasmic membrane by co-operation between the signal-recognition particle and Sec protein-secretion pathways. In contrast, a spot for Hag appeared independent from SecA and Ffh. Intracellular proteins Gap, SodA and KatA were identified in the extracellular protein samples. On the basis of these results and computer searches, it was predicted that B. subtilis produces 150 to 180 proteins extracellularly.

Isolation and characterization of a sporulation initiation mutation in the Bacillus subtilis secA gene

A Bacillus subtilis secA mutant, secA12, which is blocked at an early stage of sporulation, is able to grow as well as the wild-type strain at all temperatures tested. Experiments with lacZ fusion genes showed that the induction of kinA expression, as well as the sporulation-specific transcription of the spo0A gene, was not observed in the secA12 mutant. However, transcription of the spo0H gene (coding for sigmaH, which is required for the transcription of kinA and spo0A) and accumulation of the sigmaH protein were not affected in secA12. These results suggested that mutations in secA affect a factor required for efficient transcription of kinA as well as for the activation of the phosphorelay pathway.

Characterization of a cell division gene from Bacillus subtilis that is required for vegetative and sporulation septum formation

We report the cloning and characterization of a cell division gene, herein designated divIC, from the gram-positive, spore-forming bacterium Bacillus subtilis. This gene was previously identified on the basis of a temperature-sensitive mutation, div-355, that blocks septum formation at restrictive temperatures. We show that the divIC gene is a 125-codon open reading frame that is capable of encoding a protein of 14.7 kDa and that div-355 is a 5-bp duplication near the 3' end of the open reading frame. We also show that divIC is an essential gene by use of an in vitro-constructed null mutation. In confirmation and extension of earlier results, we show that divIC is necessary for both vegetative and sporulation septum formation, and we demonstrate that it is required for the activation of genes expressed under the control of the sporulation transcription factors sigma F and sigma E. The divIC gene is located 1.3 kb upstream of the coding sequence for the sporulation gene spoIIE. Between divIC and spoIIE is a 128-codon open reading frame whose predicted product contains a region of similarity to the RNA-binding domains of polynucleotide phosphorylase and ribosomal protein S1 from Escherichia coli and two putative tRNA genes for methionyl-tRNA and glutamyl-tRNA, the gene order being divIC orf128 tRNA(Met) tRNA(Glu) spoIIE.

Cloning and sequencing of the cell division gene pbpB, which encodes penicillin-binding protein 2B in Bacillus subtilis

The pbpB gene, which encodes penicillin-binding protein (PBP) 2B of Bacillus subtilis, has been cloned, sequenced, mapped, and mutagenized. The sequence of PBP 2B places it among the class B high-molecular-weight PBPs. It appears to contain three functional domains: an N-terminal domain homologous to the corresponding domain of other class B PBPs, a penicillin-binding domain, and a lengthy carboxy extension. The PBP has a noncleaved signal sequence at its N terminus that presumably serves as its anchor in the cell membrane. Previous studies led to the hypothesis that PBP 2B is required for both vegetative cell division and sporulation septation. Its sequence, map site, and mutant phenotype support this hypothesis. PBP 2B is homologous to PBP 3, the cell division protein encoded by pbpB of Escherichia coli. Moreover, both pbpB genes are located in the same relative position within a cluster of cell division and cell wall genes on their respective chromosomes. However, immediately adjacent to the B. subtilis pbpB gene is spoVD, which appears to be a sporulation-specific homolog of pbpB. Inactivation of SpoVD blocked synthesis of the cortical peptidoglycan in the spore, whereas carboxy truncation of PBP 2B caused cells to grow as filaments. Thus, it appears that a gene duplication has occurred in B. subtilis and that one PBP has evolved to serve a common role in septation during both vegetative growth and sporulation, whereas the other PBP serves a specialized role in sporulation.

Identification of Bacillus subtilis genes for septum placement and shape determination

The Bacillus subtilis divIVB1 mutation causes aberrant positioning of the septum during cell division, resulting in the formation of small, anucleate cells known as minicells. We report the cloning of the wild-type allele of divIVB1 and show that the mutation lies within a stretch of DNA containing two open reading frames whose predicted products are in part homologous to the products of the Escherichia coli minicell genes minC and minD. Just upstream of minC and minD, and in the same orientation, are three genes whose products are homologous to the products of the E. coli shape-determining genes mreB, mreC, and mreD. The B. subtilis mreB, mreC, and mreD genes are the site of a conditional mutation (rodB1) that causes the production of aberrantly shaped cells under restrictive conditions. Northern (RNA) hybridization experiments and disruption experiments based on the use of integrational plasmids indicate that the mre and min genes constitute a five-cistron operon. The possible involvement of min gene products in the switch from medial to polar placement of the septum during sporulation is discussed.

In vivo and in vitro characterization of the secA gene product of Bacillus subtilis

The putative amino acid sequence from the wild-type Bacillus subtilis div+ gene, which complements the temperature-sensitive div-341 mutation, shares a 50% identity with the sequence from Escherichia coli secA (Y. Sadaie, H. Takamatsu, K. Nakamura, and K. Yamane, Gene 98:101-105, 1991). The B. subtilis div-341 mutant accumulated the precursor proteins of alpha-amylase and beta-lactamase at 45 degrees C as in the case of sec mutants of E. coli. The div-341 mutation is a transition mutation causing an amino acid replacement from Pro to Leu at residue 431 of the putative amino acid sequence. The B. subtilis div+ gene was overexpressed in E. coli under the control of the tac promoter, and its product was purified to homogeneity. The Div protein consists of a homodimer of 94-kDa subunits which possesses ATPase activity, and the first 7 amino acids of the putative Div protein were found to be subjected to limited proteolysis in the purified protein. The antiserum against B. subtilis Div weakly cross-reacted with E. coli SecA. On the other hand, B. subtilis Div could not replace E. coli SecA in an E. coli in vitro protein translocation system. The temperature-sensitive growth of the E. coli secA mutant could not be restored by the introduction of B. subtilis div+, which is expressed under the control of the spac-1 promoter, and vice versa. The B. subtilis div+ gene is the B. subtilis counterpart of E. coli secA, and we propose that the div+ gene be referred to as B. subtilis secA, although Div did not function in the protein translocation system of E. coli.

Small cytoplasmic RNA of Bacillus subtilis: functional relationship with human signal recognition particle 7S RNA and Escherichia coli 4.5S RNA

Small cytoplasmic RNA (scRNA; 271 nucleotides) is an abundant and stable RNA of the gram-positive bacterium Bacillus subtilis. To investigate the function of scRNA in B. subtilis cells, we developed a strain that is dependent on isopropyl-beta-D-thiogalactopyranoside for scRNA synthesis by fusing the chromosomal scr locus with the spac-1 promoter by homologous recombination. Depletion of the inducer leads to a loss of scRNA synthesis, defects in protein synthesis and production of alpha-amylase and beta-lactamase, and eventual cell death. The loss of the scRNA gene in B. subtilis can be complemented by the introduction of human signal recognition particle 7S RNA, which is considered to be involved in protein transport, or Escherichia coli 4.5S RNA. These results provide further evidence for a functional relationship between B. subtilis scRNA, human signal recognition particle 7S RNA, and E. coli 4.5S RNA.

Mapping of the gene for a major penicillin-binding protein to a genetically conserved region of the Bacillus subtilis chromosome and conservation of the protein among related species of Bacillus

Penicillin-binding protein 5 is the most abundant penicillin-binding protein in the vegetative membranes of Bacillus subtilis and accounts for 95% of the D,D-carboxypeptidase activity of the cell. The structural gene for penicillin-binding protein 5 was mapped to a genetically conserved region near guaB at 0 degrees on the B. subtilis chromosome, and immunoassays revealed that there is conservation of this major penicillin-binding protein among related species.

Sequencing reveals similarity of the wild-type div+ gene of Bacillus subtilis to the Escherichia coli secA gene

We have determined the nucleotide (nt) sequence of the wild-type div+ gene of Bacillus subtilis which complements the temperature-sensitive div-341 mutation and is involved in cell septation, sporulation, secretion of extracellular enzymes, development of competence, autolysis and spore outgrowth. It has an open reading frame encoding 841 amino acids (aa) with homology to the Escherichia coli secA gene, which is involved in protein secretion and cell separation. The deduced aa sequence of the B. subtilis div+ gene shares 50% identity with that of the E. coli secA gene, and highly homologous regions were observed in the N-terminal portions. DNA-DNA hybridization with the E. coli secA gene as the probe showed that the div+ gene could be easily detected by homology and that a single copy of the homologous gene was present in B. subtilis. Since both genes are similar in their functions and deduced aa sequences, we propose that the div+ gene is the counterpart of the secA gene of E. coli.

Nucleotide sequence and insertional inactivation of a Bacillus subtilis gene that affects cell division, sporulation, and temperature sensitivity

Located at 135 degrees on the Bacillus subtilis genetic map are several genes suspected to be involved in cell division and sporulation. Previously isolated mutations mapping at 135 degrees include the tms-12 mutation and mutations in the B. subtilis homologs of the Escherichia coli cell division genes ftsA and ftsZ. Previously, we cloned and sequenced the B. subtilis ftsA and ftsZ genes that are present on an 11-kilobase-pair EcoRI fragment and found that the gene products and organization of these two genes are conserved between the two bacterial species. We have since found that the mutation in the temperature-sensitive filamenting tms-12 mutant maps upstream of the ftsA gene on the same 11-kilobase-pair EcoRI fragment in a gene we designated dds. Sequence analysis of the dds gene and four other open reading frames upstream of ftsA revealed no significant homology to other known genes. It was found that the dds gene is not absolutely essential for viability since the dds gene could be insertionally inactivated. The dds null mutants grew slowly, were filamentous, and exhibited a reduced level of sporulation. Additionally, these mutants were extremely temperature sensitive and were unable to form colonies at 37 degrees C. Another insertion, which resulted in the elimination of 103 C-terminal residues, resulted in a temperature-sensitive phenotype less severe than that in the dds null mutant and similar to that in the known tms-12 mutant. The tms-12 mutation was cloned and sequenced, revealing a nonsense codon that was predicted to result in an amber fragment that was about 65% of the wild-type size (elimination of 93 C-terminal residues).

Cloning and expression of a Bacillus subtilis division initiation gene for which a homolog has not been identified in another organism

The Bacillus subtilis 168 division initiation genes defined by the temperature-sensitive mutations ts-1 and ts-12 were cloned into a 10.5-kilobase EcoRI fragment of DNA in the lambda EMBL4 vector. The two genes were separated by approximately 3 kilobases. The gene in which the ts-1 mutation resides was shown to be the same as the B. subtilis homolog of the Escherichia coli ftsZ gene. The other gene was named divIB. It showed no homology to any previously identified gene and coded for a protein of 30.1 kilodaltons which was probably membrane bound.

Cloning and characterization of Bacillus subtilis homologs of Escherichia coli cell division genes ftsZ and ftsA

The Bacillus subtilis homolog of the Escherichia coli ftsZ gene was isolated by screening a B. subtilis genomic library with anti-E. coli FtsZ antiserum. DNA sequence analysis of a 4-kilobase region revealed three open reading frames. One of these coded for a protein that was about 50% homologous to the E. coli FtsZ protein. The open reading frame just upstream of ftsZ coded for a protein that was 34% homologous to the E. coli FtsA protein. The open reading frames flanking these two B. subtilis genes showed no relationship to those found in E. coli. Expression of the B. subtilis ftsZ and ftsA genes in E. coli was lethal, since neither of these genes could be cloned on plasmid vectors unless promoter sequences were first removed. Cloning the B. subtilis ftsZ gene under the control of the lac promoter resulted in an IPTGs phenotype that could be suppressed by overproduction of E. coli FtsZ. These genes mapped at 135 degrees on the B. subtilis genetic map near previously identified cell division mutations.

Bacillus subtilis gene involved in cell division, sporulation, and exoenzyme secretion

Bacillus subtilis strains carrying div-341 or sacU mutations, or both, have been characterized to reveal the roles of both genes in the initiation of sporulation, as well as in cell division and exoenzyme secretion. Both mutations were closely linked by transformation and caused the pleiotropic effects on sporulation and sporulation-associated events. Some sacU mutations (sacUh) resulted in hyperproduction of exoenzymes, reduced autolysis, and an ability to sporulate in the presence of excess nutrients. The div-341 mutation, on the other hand, resulted in filamentous growth at a higher temperature (45 degrees C) and showed spo0 properties at an intermediate permissive temperature (37 degrees C) in the usual sporulation medium. However, the div-341 strain sporulated better than wild-type strain at 37 degrees C in the presence of excess nutrients. Exoenzyme production and autolysis were reduced at 37 degrees C in the div-341 strain. A double mutant with sacUh32 and div-341 showed the complex phenotypes. It showed the sacUh32 property of autolysis and exoenyzme secretion. It showed the sacUh32 property of sporulation at 30 degrees C and the div-341 property at 37 degrees C. Slow growth and defective spore outgrowth of the div-341 strain at 37 degrees C were not observed in the double-mutant strain. Based on pleiotropic phenotypes and close linkages of both mutations, we discuss the relationship between the sacU and div-341 genes and their roles in sporulation, exoenzyme secretion, and cell division.

Timing and other features of the action of the ts1 division initiation gene product of Bacillus subtilis

The ts1 division initiation mutation of Bacillus subtilis 160 was transferred into a thymine-requiring strain of B. subtilis 168. Aspects of the role and timing of the action of the ts1 gene product in relation to septum formation were studied by comparing the behavior of this new strain with that of the isogenic wild type after outgrowth of germinated spores. The ts1 gene product was shown to be required for the asymmetric division which occurs in the absence of chromosome replication, in addition to normal division septation. The time interval between completion of the action of the ts1 gene product and initiation of the first central division septum was estimated to be less than 4 min at 34 degrees C, and it is possible that an active ts1 gene product is required until the commencement of septal growth. Recovery of septa after transfer of outgrown spores (filaments) from the nonpermissive to the permissive temperature was also examined. During recovery, septa formed at sites which were discrete fractional lengths of the filaments, with the first septum located at the most polar of these sites. The data have been interpreted in terms of the formation of potential division sites at the nonpermissive temperature and the preferred utilization, upon recovery, of the most recently formed site. Recovery of septa at the permissive temperature occurred in the absence of DNA synthesis but was blocked completely by inhibitors of RNA and protein synthesis. It is possible that the only protein synthesis required for recovery of septa is that of the ts1 gene product itself.