Characterization and mapping of temperature-sensitive division initiation mutations of Bacillus subtilis

Failsafe mechanisms couple division and DNA replication in bacteria

The past 20 years have seen tremendous advances in our understanding of the mechanisms underlying bacterial cytokinesis, particularly the composition of the division machinery and the factors controlling its assembly [1]. At the same time, we understand very little about the relationship between cell division and other cell-cycle events in bacteria. Here we report that inhibiting division in Bacillus subtilis and Staphylococcus aureus quickly leads to an arrest in the initiation of new rounds of DNA replication, followed by a complete arrest in cell growth. Arrested cells are metabolically active but are unable to initiate new rounds of either DNA replication or division when shifted to permissive conditions. Inhibiting DNA replication results in entry into a similar quiescent state in which cells are unable to resume growth or division when returned to permissive conditions. Our data suggest the presence of two failsafe mechanisms: one linking division to the initiation of DNA replication and another linking the initiation of DNA replication to division. These findings contradict the prevailing view of the bacterial cell cycle as a series of coordinated but uncoupled events. Importantly, the terminal nature of the cell-cycle arrest validates the bacterial cell-cycle machinery as an effective target for antimicrobial development.

Lateral FtsZ association and the assembly of the cytokinetic Z ring in bacteria

Cell division in bacteria is facilitated by a polymeric ring structure, the Z ring, composed of tubulin-like FtsZ protofilaments. Recently it has been shown that in Bacillus subtilis, the Z ring forms through the cell cycle-mediated remodelling of a helical FtsZ polymer. To investigate how this occurs in vivo, we have exploited a unique temperature-sensitive strain of B. subtilis expressing the mutant protein FtsZ(Ts1). FtsZ(Ts1) is unable to complete Z ring assembly at 49 degrees C, becoming trapped at an intermediate stage in the helix-to-ring progression. To determine why this is the case, we used a combination of methods to identify the specific defect of the FtsZ(Ts1) protein in vivo. Our results indicate that while FtsZ(Ts1) is able to polymerize normally into protofilaments, it is defective in the ability to support lateral associations between these filaments at high temperatures. This strongly suggests that lateral FtsZ association plays a crucial role in the polymer transitions that lead to the formation of the Z ring in the cell. In addition, we show that the FtsZ-binding protein ZapA, when overproduced, can rescue the FtsZ(Ts1) defect in vivo. This suggests that ZapA functions to promote the helix-to-ring transition of FtsZ by stimulating lateral FtsZ association.

Trapping of a spiral-like intermediate of the bacterial cytokinetic protein FtsZ

The earliest stage in bacterial cell division is the formation of a ring, composed of the tubulin-like protein FtsZ, at the division site. Tight spatial and temporal regulation of Z-ring formation is required to ensure that division occurs precisely at midcell between two replicated chromosomes. However, the mechanism of Z-ring formation and its regulation in vivo remain unresolved. Here we identify the defect of an interesting temperature-sensitive ftsZ mutant (ts1) of Bacillus subtilis. At the nonpermissive temperature, the mutant protein, FtsZ(Ts1), assembles into spiral-like structures between chromosomes. When shifted back down to the permissive temperature, functional Z rings form and division resumes. Our observations support a model in which Z-ring formation at the division site arises from reorganization of a long cytoskeletal spiral form of FtsZ and suggest that the FtsZ(Ts1) protein is captured as a shorter spiral-forming intermediate that is unable to complete this reorganization step. The ts1 mutant is likely to be very valuable in revealing how FtsZ assembles into a ring and how this occurs precisely at the division site.

Cell division protein DivIB influences the Spo0J/Soj system of chromosome segregation in Bacillus subtilis

The initiation of the developmental process of sporulation in the rod-shaped bacterium Bacillus subtilis involves the activation of the Spo0A response regulator. Spo0A then drives the switch in the site of division septum formation from midcell to a polar position. Activated Spo0A is required for the transcription of key sporulation loci such as spoIIG, which are negatively regulated by the Soj protein. The transcriptional repressing activity of Soj is antagonized by Spo0J, and both proteins belong to the well-conserved Par family of partitioning proteins. Soj has been shown to jump from nucleoid to nucleoid via the cell pole. The dynamic behaviour of Soj is somehow controlled by Spo0J, which prevents the static association of Soj with the nucleoid, and presumably its transcriptional repression activity. Soj in turn is required for the proper condensation of Spo0J foci around the oriC region. The asymmetric partitioning of the sporangial cell requires DivIB and other proteins involved in vegetative (medial) division. We describe an allele of the cell division gene divIB (divIB80) that reduces the cellular levels of DivIB, and affects nucleoid structure and segregation in growing cells, yet has no major impact on cell division. In divIB80 cells Spo0J foci are not correctly condensed and Soj associates statically with the nucleoid. The divIB80 allele prevents transcription of spoIIG, and arrests sporulation prior to the formation of the asymmetric division septum. The defect in Spo0A-dependent gene expression, and the Spo- phenotype can be suppressed by expression of divIB in trans or by deletion of the soj-spo0J locus. However, deletion of the spo0J-soj region does not restore the normal cellular levels of DivIB. Therefore, the reduced levels of DivIB in the divIB80 mutant are sufficient for efficient cell division, but not to sustain a second, earlier function of DivIB related to the activity of the Spo0J/Soj system of chromosome segregation.

PBP1 is a component of the Bacillus subtilis cell division machinery

Bacillus subtilis penicillin-binding protein PBP1 has been implicated in cell division. We show here that a PBP1 knockout strain is affected in the formation of the asymmetric sporulation septum and that green fluorescent protein-PBP1 localizes to the sporulation septum. Localization of PBP1 to the vegetative septum is dependent on various cell division proteins. This study proves that PBP1 forms part of the B. subtilis cell division machinery.

Septal localization of the membrane-bound division proteins of Bacillus subtilis DivIB and DivIC is codependent only at high temperatures and requires FtsZ

Using immunofluorescence microscopy, we have examined the dependency of localization among three Bacillus subtilis division proteins, FtsZ, DivIB, and DivIC, to the division site. DivIC is required for DivIB localization. However, DivIC localization is dependent on DivIB only at high growth temperatures, at which DivIB is essential for division. FtsZ localization is required for septal recruitment of DivIB and DivIC, but FtsZ can be recruited independently of DivIB. These localization studies suggest a more specific role for DivIB in division, involving interaction with DivIC.

Role of penicillin-binding protein PBP 2B in assembly and functioning of the division machinery of Bacillus subtilis

We have characterized the role of the penicillin-binding protein PBP 2B in cell division of Bacillus subtilis. We have shown that depletion of the protein results in an arrest in division, but that this arrest is slow, probably because the protein is relatively stable. PBP 2B-depleted filaments contained, at about their mid-points, structures resembling partially formed septa, into which most, if not all, of the division proteins had assembled. Although clearly deficient in wall material, membrane invagination seemed to continue, indicating that membrane and wall ingrowth can be uncoupled. At other potential division sites along the filaments, no visible ingrowths were observed, although FtsZ rings assembled at regular intervals. Thus, PBP 2B is apparently required for both the initiation of division and continued septal ingrowth. Immunofluorescence microscopy showed that the protein is recruited to the division site. The pattern of localization suggested that this recruitment occurs continually during septal ingrowth. During sporulation, PBP 2B was present transiently in the asymmetrical septum of sporulating cells, and its availability may play a role in the regulation of sporulation septation.

Long-chain polyphosphate causes cell lysis and inhibits Bacillus cereus septum formation, which is dependent on divalent cations

We investigated the cellular mechanisms that led to growth inhibition, morphological changes, and lysis of Bacillus cereus WSBC 10030 when it was challenged with a long-chain polyphosphate (polyP). At a concentration of 0.1% or higher, polyP had a bacteriocidal effect on log-phase cells, in which it induced rapid lysis and reductions in viable cell counts of up to 3 log units. The cellular debris consisted of empty cell wall cylinders and polar caps, suggesting that polyP-induced lysis was spatially specific. This activity was strictly dependent on active growth and cell division, since polyP failed to induce lysis in cells treated with chloramphenicol and in stationary-phase cells, which were, however, bacteriostatically inhibited by polyP. Similar observations were made with B. cereus spores; 0.1% polyP inhibited spore germination and outgrowth, and a higher concentration (1.0%) was even sporocidal. Supplemental divalent metal ions (Mg(2+) and Ca(2+)) could almost completely block and reverse the antimicrobial activity of polyP; i. e., they could immediately stop lysis and reinitiate rapid cell division and multiplication. Interestingly, a sublethal polyP concentration (0.05%) led to the formation of elongated cells (average length, 70 microm) after 4 h of incubation. While DNA replication and chromosome segregation were undisturbed, electron microscopy revealed a complete lack of septum formation within the filaments. Exposure to divalent cations resulted in instantaneous formation and growth of ring-shaped edges of invaginating septal walls. After approximately 30 min, septation was complete, and cell division resumed. We frequently observed a minicell-like phenotype and other septation defects, which were probably due to hyperdivision activity after cation supplementation. We propose that polyP may have an effect on the ubiquitous bacterial cell division protein FtsZ, whose GTPase activity is known to be strictly dependent on divalent metal ions. It is tempting to speculate that polyP, because of its metal ion-chelating nature, indirectly blocks the dynamic formation (polymerization) of the Z ring, which would explain the aseptate phenotype.

Conservation of the 168 divIB gene in Bacillus subtilis W23 and B. licheniformis, and evidence for homology to ftsQ of Escherichia coli

The chromosomal regions of Bacillus subtilis (Bs) W23 and Bacillus licheniformis (Bl), which span the sequence encoding the homolog of the division initiation gene, divIB, of Bs168 were cloned and sequenced. The high level of conservation of the amino acid (aa) sequence of the DivIB protein (99 and 68% identity for BsW23 and Bl, respectively) was consistent with a significant role for this protein in the cell cycle of the two species. The hydropathy profile for DivIB of Bl was almost identical to that of Bs168 and consistent with a membrane location, as previously established for the latter. The higher than average level of identity (87%) of the 31-aa N-terminal cytoplasmic domain of DivIB between Bs168 and Bl raised the possibility of a special role for this domain. Database analyses using the Bl DivIB sequence and similarity analyses also strongly suggested that DivIB, of Bl and Bs, is a homolog of FtsQ of Escherichia coli. The flanking sequences extending into the unidentified orfs both upstream and downstream from divIB were highly conserved between Bs168 and Bl at both the nucleotide and aa levels. It was confirmed that orf4 of Bs168 is dispensable.

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.

Expression of divIB of Bacillus subtilis during vegetative growth

Expression of the division initiation gene, divIB, of Bacillus subtilis vegetative growth was examined. lacZ fusion studies and transcription start point mapping have established that a sigma A promoter proximal to divIB is utilized in vivo. The -10 region of this promoter, which is located 93 bp upstream of the start codon, has been defined precisely by site-directed mutagenesis that destroys the promoter. Examination of transcripts by Northern (RNA) blotting has shown that there are at least two transcripts for divIB. The established proximal promoter was found to give rise to a very minor transcript which could not be convincingly demonstrated in wild-type cells but which became apparent upon insertion of a plasmid into the chromosome just upstream of this promoter. The major transcript for divIB originated from a site several kb upstream of the gene and is probably the same as the long polycistronic message also traversing the murD-spoVE-murG genes that was identified previously by others (A.D. Henriques, H. de Lencastre, and P.J. Piggot, Biochimie 74:735-748, 1992). Transcription from the proximal promoter alone, in an upstream-deletion mutant strain, provided sufficient DivIB for normal growth and division as well as sporulation.

Characterization of mutations in divIB of Bacillus subtilis and cellular localization of the DivIB protein

Four temperature-sensitive mutations in the divIB gene of Bacillus subtilis have been localized to the region corresponding to the C-terminal half of the 263-residue DivIB protein. Antiserum was raised to the 80% C-terminal portion lying on one side of a putative transmembrane (hydrophobic) segment, and used to examine aspects of the nature and localization of the DivIB protein in the cell. A single DivIB species of a size equal to the full-length protein encoded by the divIB gene was detected in wild-type cells. Cell fractionation studies established that DivIB is associated preferentially with the cell envelope (membrane plus cell wall), with approximately 50% being released into solution upon treatment of cells with lysozyme under conditions that yield protoplasts. Of the remaining 50%, approximately half remained firmly associated with the membrane fraction. On the basis of the 'positive-inside rule' of von Heijne (1986) it is suggested that the topology of membrane-bound DivIB is such that the long C-terminal portion is directed to the outside and the smaller N-terminal portion to the inside of the cell. DivIB in protoplasts was rapidly degraded by proteinase K under conditions where there was no general proteolysis of the cytoplasmic proteins. This is consistent with its absence from the cytoplasm, and with the predicted membrane topology. Septum positioning in a divIB null mutant, which grows as filaments at temperatures of 30 degrees C and below, was found to be normal. It appears that DivIB is needed for achieving the appropriate rate of initiation of septum formation at normal division sites. It is proposed that the C-terminal portion of DivIB, localized on the exterior surface of the membrane and in juxtaposition to the peptidoglycan, normally interacts with another protein (or proteins) to initiate septum formation.

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.

Cell wall and DNA cosegregation in Bacillus subtilis studied by electron microscope autoradiography

Cells of a Bacillus subtilis mutant deficient in both major autolytic enzyme activities were continuously labeled in either cell wall or DNA or both cell wall and DNA. After appropriate periods of chase in minimal as well as in rich medium, thin sections of cells were autoradiographed and examined by electron microscopy. The resolution of the method was adequate to distinguish labeled DNA units from cell wall units. The latter, which could be easily identified, were shown to segregate symmetrically, suggesting a zonal mode of new wall insertion. DNA units could also be clearly recognized despite a limited fragmentation; they segregated asymmetrically with respect to the nearest septum. Analysis of cells simultaneously labeled in cell wall and DNA provided clear visual evidence of their regular but asymmetrical cosegregation, confirming a previous report obtained by light microscope autoradiography (J.-M. Schlaeppi and D. Karamata, J. Bacteriol. 152:1231-1240, 1982). In addition to labeled wall units, electron microscopy of thin sections of aligned cells has revealed fibrillar networks of wall material which are frequently associated with the cell surface. Most likely, these structures correspond to wall sloughed off by the turnover mechanism but not yet degraded to filterable or acid-soluble components.

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.

Bacterial growth and division: genes, structures, forces, and clocks

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Conformation and segregation of nucleoids accompanying cell length extension after completion of a single round of DNA replication in germinated and outgrowing Bacillus subtilis spores

When germinating spores of the temperature-sensitive DNA initiation mutant of Bacillus subtilis TsB134 are shifted to the restrictive temperature at a time such that just one or two rounds of replication are accomplished, the completed, nonreplicating nucleoids that form eventually adopt a doublet conformation. This conformation has now been observed after fixation by glutaraldehyde or osmium tetroxide, as well as by Formalin as found previously. The doublet was observed in media of different degrees of richness and under both light and electron microscopes. Electron micrographs of serial sections through the doublet were consistent with its formation by the gradual pulling apart of a single mass of DNA into two lobes. A systematic study was made of the effect of the time of shifting from the permissive to the restrictive temperature and of the restrictive temperature used on the number of nucleoids segregating within the outgrowing rod. It was established that the doublet nucleoid behaved as a single unit in replication control and segregation in both rich and poor media. Measurement of the relative position of the two segregating nucleoids within the outgrowing rod after completion of just one round of replication yielded quantitative information on the segregation and cell length extension processes. Segregation was accompanied by cell length extension at approximately equal rates on both sides of each nucleoid. Furthermore, the data were consistent with an exponential increase in such an extension with time over the early and major portion of the period studied, but it was not possible to rule out other models of length extension.

Timed action of the gene products required for septum formation in the cell cycle of Bacillus subtilis

Four isogenic strains of temperature-sensitive septationless mutants, whose mutations are located on different genes, were used to study the periods of action of the gene products required for the initiation of septum formation during the cell cycle of Bacillus subtilis. The shift-up experiments, in which portions of a synchronous culture of each mutant were transferred to the nonpermissive temperature, showed that the transition point, at which cells attained the ability to divide at the nonpermissive temperature in the cell cycle, was strain specific. Furthermore, the heat shock experiments, in which portions of a synchronous culture were subjected to the nonpermissive temperature before the transition point for a fixed period and shifted back to the permissive temperature, showed that the time interval between the shift-back and the subsequent cell division was specific to each strain but was independent of the age of heat shock. These results led us to the idea that the initiation of septum formation in B. subtilis requires the timed action of the four gene products, each of which functions at a specific stage in the cell cycle. In addition, the result with DNA elongation mutant MK-526, which is also septation defective, supported our previous findings that the initiation of septum formation requires the termination of DNA replication in the previous cell cycle.