Septation and chromosome segregation during sporulation in Bacillus subtilis

The early stages of sporulation in Bacillus subtilis incorporate a modified, highly asymmetric cell division. It is now clear that most, if not all, of the components of the vegetative division machinery are used also for asymmetric division. However, the machinery for chromosome segregation may differ significantly between vegetative growth and sporulation. Several interesting checkpoint mechanisms couple cell cycle events to gene expression early in sporulation. This review summarises important advances in the understanding of chromosome segregation and cell division at the onset of sporulation in B.subtilis in the past three years.     

The minCD locus of Bacillus subtilis lacks the minE determinant that provides topological specificity to cell division

A key event of the sporulation process in Bacillus subtilis is the asymmetric cell division that divides the developing cell into two unequal compartments. To examine the function of vegetative cell division genes in this developmental division, we isolated and characterized the B. subtilis counterpart to the Escherichia coli minicell operon minB, which governs correct placement of the division septum. Starting from the closely linked spo/VFlocus, we used walking methods to isolate the region of the B. subtilis chromosome proximate to the divlVB minicell locus. DNA sequence analysis found two open reading frames whose predicted products had significant identity to the E. coli MinC cell division inhibitor and the MinD ATPase activator of MinC, and disruption of minCD function generated a minicell phenotype in B. subtilis. Notably, no homologue to the E. coli MinE topological specificity element was found in the B. subtilis minCD region. The B. subtilis min genes were part of an operon transcribed from a major promoter more than 2.5 kb upstream from minC. An internal promoter immediately upstream from minC was dependent on RNA polymerase containing sigma-H and was active at the onset of sporulation. However, neither minCnor minD function was absolutely required for sporulation and, by implication, for asymmetric septum formation.     

Cell polarity and the mechanism of asymmetric cell division

During development one mechanism for generating different cell types is asymmetric cell division, by which a cell divides and contributes different factors to each of its daughter cells. Asymmetric cell division occurs through out the eukaryotic kingdom, from yeast to humans. Many asymmetric cell divisions occur in a defined orientation. This implies a cellular mechanism for sensing direction, which must ultimately lead to differences in gene expression between two daughter cells. In this review, we describe two classes of molecules: regulatory factors that are differentially expressed upon asymmetric cell division, and components of a signal transduction pathway that may define cell polarity. The lin-11 and mec-3 genes of C. elegans, the Isl-1 gene of mammals and the HO gene of yeast, encode regulatory factors that determine cell type of one daughter after asymmetric cell division. The CDC24 and CDC42 genes of yeast affect both bud positioning and orientation of mating projections, and thus may define a general cellular polarity. We speculate that molecules such as Cdc24 and Cdc42 may regulate expression of genes such as lin-11, mec-3, Isl-1 and HO upon asymmetric cell division.     

Identification and Immunochemical Location of UMP Kinase from <Emphasis Type="Italic">Bacillus subtilis</Emphasis>

Phosphorylation of CMP and UMP is accomplished in Bacillus subtilis, as in Escherichia coli, by two different enzymes exhibiting characteristic structural and catalytic properties. UMP kinase from B. subtilis is an oligomer whose activity is strictly dependent on GTP. The B. subtilis enzyme is unstable in the absence of UTP, which acts as an allosteric inhibitor. Antibodies raised against recombinant B. subtilis UMP kinase recognized the protein both in soluble extract and in immunoelectron microscopy. UMP kinase from B. subtilis has a peripheral distribution which is related most probably to its role in the synthesis of membrane sugar components and its putative role in cell division.     

Bacterial cell division: regulating Z-ring formation

The earliest stage of cell division in bacteria is the formation of a Z ring, composed of a polymer of the FtsZ protein, at the division site. Z rings appear to be synthesized in a bi‐directional manner from a nucleation site (NS) located on the inside of the cytoplasmic membrane. It is the utilization of a NS specifically at the site of septum formation that determines where and when division will occur. However, a Z ring can be made to form at positions other than at the division site. How does a cell regulate utilization of a NS at the correct location and at the right time? In rod‐shaped bacteria such as Escherichia coli and Bacillus subtilis, two factors involved in this regulation are the Min system and nucleoid occlusion. It is suggested that in B. subtilis, the main role of the Min proteins is to inhibit division at the nucleoid‐free cell poles. In E. coli it is currently not clear whether the Min system can direct a Z ring to the division site at mid‐cell or whether its main role is to ensure that division inhibition occurs away from mid‐cell, a role analogous to that in B. subtilis. While the nucleoid negatively influences Z‐ring formation in its vicinity in these rod‐shaped organisms, the exact relationship between nucleoid occlusion and the ability to form a mid‐cell Z ring is unresolved. Recent evidence suggests that in B. subtilis and Caulobacter crescentus, utilization of the NS at the division site is intimately linked to the progress of a round of chromosome replication and this may form the basis of achieving co‐ordination between chromosome replication and cell division.     

Cell cycle and sporulation in Bacillus subtilis

Recent work on cell division and chromosome orientation and partitioning in Bacillus subtilis has provided insights into cell cycle regulation during growth and development. The cell cycle is an integral part of development and entrance into sporulation is modulated by signals that transmit the status of DNA integrity, chromosome replication and segregation. In addition, B. subtilis modifies cell division and DNA segregation to establish cell-type-specific gene expression during sporulation.     

FtsEX is required for CwlO peptidoglycan hydrolase activity during cell wall elongation in Bacillus subtilis

The peptidoglycan (PG) sacculus, a meshwork of polysaccharide strands cross‐linked by short peptides, protects bacterial cells against osmotic lysis. To enlarge this covalently closed macromolecule, PG hydrolases must break peptide cross‐links in the meshwork to allow insertion of new glycan strands between the existing ones. In the rod‐shaped bacterium Bacillus subtilis, cell wall elongation requires two redundant endopeptidases, CwlO and LytE. However, it is not known how these potentially autolytic enzymes are regulated to prevent lethal breaches in the cell wall. Here, we show that the ATP‐binding cassette transporter‐like FtsEX complex is required for CwlO activity. In Escherichia coli, FtsEX is thought to harness ATP hydrolysis to activate unrelated PG hydrolases during cell division. Consistent with this regulatory scheme, B. subtilis FtsE mutants that are unable to bind or hydrolyse ATP cannot activate CwlO. Finally, we show that in cells depleted of both CwlO and LytE, the PG synthetic machinery continues moving circumferentially until cell lysis, suggesting that cross‐link cleavage is not required for glycan strand polymerization. Overall, our data support a model in which the FtsEX complex is a remarkably flexible regulatory module capable of controlling a diverse set of PG hydrolases during growth and division in different organisms.     

The Bacillus subtilis soj-spo0J locus is required for a centromere-like function involved in prespore chromosome partitioning

During sporulation in Bacillus subtilis a small prespore cell is formed by an asymmetric cell division. Pre-spore chromosome partitioning occurs by a specialised mechanism in which septation precedes chromosome movement. We show that the spo0J gene is needed to specify the orientation of the chromosome at the time of polar division and to impose directionality on the subsequent transport of the remainder of the chromosome through the septum. Both phenotypes may arise by disruption of a centromere-like apparatus that anchors the oriC region of the prespore chromosome in the pole of the cell.     

Synthetic developmental regulator MciZ targets FtsZ across Bacillus species and inhibits bacterial division

Cell division in most bacteria is directed by FtsZ, a conserved tubulin‐like GTPase that assembles forming the cytokinetic Z‐ring and constitutes a target for the discovery of new antibiotics. The developmental regulator MciZ, a 40‐amino acid peptide endogenously produced during Bacillus subtilis sporulation, halts cytokinesis in the mother cell by inhibiting FtsZ. The crystal structure of a FtsZ:MciZ complex revealed that bound MciZ extends the C‐terminal β‐sheet of FtsZ blocking its assembly interface. Here we demonstrate that exogenously added MciZ specifically inhibits B. subtilis cell division, sporulation and germination, and provide insight into MciZ molecular recognition by FtsZ from different bacteria. MciZ and FtsZ form a complex with sub‐micromolar affinity, analyzed by analytical ultracentrifugation, laser biolayer interferometry and isothermal titration calorimetry. Synthetic MciZ analogs, carrying single amino acid substitutions impairing MciZ β‐strand formation or hydrogen bonding to FtsZ, show a gradual reduction in affinity that resembles their impaired activity in bacteria. Gene sequences encoding MciZ spread across genus Bacillus and synthetic MciZ slows down cell division in Bacillus species, including pathogenic Bacillus cereus and Bacillus anthracis. Moreover, B. subtilis MciZ is recognized by the homologous FtsZ from Staphylococcus aureus and inhibits division when it is expressed into S. aureus cells.     

Nuclear and cell division in Bacillus subtilis Antibiotic-induced morphological changes

Incubation of Bacillus subtilis after outgrowth from spores in the presence of four different antibiotics in two different concentrations, showed that septation can occur without termination of nuclear division. Septation is then only partially uncoupled from the normal division cycle. Observations on location and development of mesosomes in the presence of the antibiotics, made in three-dimensional cell reconstructions, suggest that the mesosome plays a role in the normal coordination between nuclear and cell division, and may explain the partial independence between these two processes in B. subtilis.with technical assistance of Catherine J. SchaapThis work has been presented in part at the A.S.M. Conference on Bacilli: Biochemical Genetics, Physiology and Industrial Applications; 6–9 Aug, 1975, Ithaca, N.Y.     

The role of asymmetric cell division in pteridophyte cell differentiation. I. Localized metal accumulation and differentiation inVittaria gemmae andOnoclea prothallia

Summary In gemmae ofVittaria graminifolia and prothallia ofOnoclea sensibilis, cell differentiation is initiated by nuclear migration and geometrically asymmetric cell division. The small daughter cells inVittaria develop into antheridia in the presence of gibberellic acid or into rhizoids or new prothallia in its absence. Antheridial differentiation from asymmetric division is induced inOnoclea byPteridium antheridiogen, whereas rhizoid or vegetative cell formation occurs in its absence. Although asymmetric cytokinesis initiates differentiation, it does not in itself determine the developmental fate of the smaller cell. Several histochemical techniques demonstrate that prior to nuclear migration and cell division, Ca²⁺ accumulates in the cytoplasm and wall of the cell at the site where asymmetric division will occur, regardless of the developmental fate of the small cell. The cytoplasmic localization of Ca²⁺ appears to reflect a mobilization of Ca²⁺ from within the cell that eventually moves into the cell wall. We propose that this internal accumulation of Ca²⁺ leads to a localized decrease in cytosolic [Ca²⁺] which in turn may regulate developmental events such as nuclear migration.Publishing prior to 1984 as Alix R. Bassel.     

Artificial septal targeting of Bacillus subtilis cell division proteins in Escherichia coli: an interspecies approach to the study of protein-protein interactions in multiprotein complexes

Bacterial cell division is mediated by a set of proteins that assemble to form a large multiprotein complex called the divisome. Recent studies in Bacillus subtilis and Escherichia coli indicate that cell division proteins are involved in multiple cooperative binding interactions, thus presenting a technical challenge to the analysis of these interactions. We report here the use of an E. coli artificial septal targeting system for examining the interactions between the B. subtilis cell division proteins DivIB, FtsL, DivIC, and PBP 2B. This technique involves the fusion of one of the proteins (the “bait”) to ZapA, an E. coli protein targeted to mid-cell, and the fusion of a second potentially interacting partner (the “prey”) to green fluorescent protein (GFP). A positive interaction between two test proteins in E. coli leads to septal localization of the GFP fusion construct, which can be detected by fluorescence microscopy. Using this system, we present evidence for two sets of strong protein-protein interactions between B. subtilis divisomal proteins in E. coli, namely, DivIC with FtsL and DivIB with PBP 2B, that are independent of other B. subtilis cell division proteins and that do not disturb the cytokinesis process in the host cell. Our studies based on the coexpression of three or four of these B. subtilis cell division proteins suggest that interactions among these four proteins are not strong enough to allow the formation of a stable four-protein complex in E. coli in contrast to previous suggestions. Finally, our results demonstrate that E. coli artificial septal targeting is an efficient and alternative approach for detecting and characterizing stable protein-protein interactions within multiprotein complexes from other microorganisms. A salient feature of our approach is that it probably only detects the strongest interactions, thus giving an indication of whether some interactions suggested by other techniques may either be considerably weaker or due to false positives.     

The FtsZ protein of Bacillus subtilis is localized at the division site and has GTPase activity that is dependent upon FtsZ concentration

The ftsZ gene is essential for cell division in both Escherichia coli and Bacillus subtilis. In E. coli FtsZ forms a cytokinetic ring at the division site whose formation is under cell-cycle control. In addition, the FtsZ from E. coli has a GTPase activity that shows an unusual lag in vitro. In this study we show that FtsZ in Bacillus subtilis forms a ring that is at the tip of the invaginating septum. The FtsZ ring is dynamic since it is formed as division is initiated, changes diameter during septation, and disperses upon completion of septation. In vitro the purified FtsZ from B. subtilis exhibits a GTPase activity without a demonstrable lag, but the GTPase activity is markedly dependent upon the FtsZ concentration, suggesting that the FtsZ protein must oligomerize to express the GTPase activity.     

Differentiated roles for MreB‐actin isologues and autolytic enzymes in Bacillus subtilis morphogenesis

Cell morphogenesis in most bacteria is governed by spatiotemporal growth regulation of the peptidoglycan cell wall layer. Much is known about peptidoglycan synthesis but regulation of its turnover by hydrolytic enzymes is much less well understood. Bacillus subtilis has a multitude of such enzymes. Two of the best characterized are CwlO and LytE: cells lacking both enzymes have a lethal block in cell elongation. Here we show that activity of CwlO is regulated by an ABC transporter, FtsEX, which is required for cell elongation, unlike cell division as in Escherichia coli. Actin‐like MreB proteins are thought to play a key role in orchestrating cell wall morphogenesis. B. subtilis has three MreB isologues with partially differentiated functions. We now show that the three MreB isologues have differential roles in regulation of the CwlO and LytE systems and that autolysins control different aspects of cell morphogenesis. The results add major autolytic activities to the growing list of functions controlled by MreB isologues in bacteria and provide new insights into the different specialized functions of essential cell wall autolysins.