Influence of the nucleoid and the early stages of DNA replication on positioning the division site in Bacillus subtilis

Although division site positioning in rod‐shaped bacteria is generally believed to occur through the combined effect of nucleoid occlusion and the Min system, several lines of evidence suggest the existence of additional mechanisms. Studies using outgrown spores of Bacillus subtilis have shown that inhibiting the early stages of DNA replication, leading up to assembly of the replisome at oriC, influences Z ring positioning. Here we examine whether Z ring formation at midcell under various conditions of DNA replication inhibition is solely the result of relief of nucleoid occlusion. We show that midcell Z rings form preferentially over unreplicated nucleoids that have a bilobed morphology (lowering DNA concentration at midcell), whereas acentral Z rings form beside a single‐lobed nucleoid. Remarkably however, when the DnaB replication initiation protein is inactivated midcell Z rings never form over bilobed nucleoids. Relieving nucleoid occlusion by deleting noc increased midcell Z ring frequency for all situations of DNA replication inhibition, however not to the same extent, with the DnaB‐inactivated strain having the lowest frequency of midcell Z rings. We propose an additional mechanism for Z ring positioning in which the division site becomes increasingly potentiated for Z ring formation as initiation of replication is progressively completed.     

In long bacterial cells,the Min system can act off‐center

In many rod‐shaped bacteria, the Min system is well‐known for generating a cell‐pole to cell‐pole standing wave oscillation with a single node at mid‐cell to align cell division. In filamentous E. coli cells, the single‐node standing wave transitions into a multi‐nodal oscillation. These multi‐nodal dynamics have largely been treated simply as an interesting byproduct of artificially elongated cells. However, a recent in vivo study by Muraleedharan et al. shows how multi‐nodal Min dynamics are used to align non‐mid‐cell divisions in the elongated swarmer cells of Vibrio parahaemolyticus. The authors propose a model where the combined actions of cell‐length dependent Min dynamics, in concert with nucleoid occlusion along the cell length and regulation of FtsZ levels ensures Z ring formation and complete chromosome segregation at a single off‐center position. By limiting the number of cell division events to one per cell at an off‐center position, long swarmer cells are preserved within a multiplying population. The findings unveil an elegant mechanism of cell‐division regulation by the Min system that allows long swarmer cells to divide without the need to ‘dedifferentiate’.     

A novel component of the division‐site selection system of Bacillus subtilis and a new mode of action for the division inhibitor MinCD

Cell division in bacteria is governed by a complex cytokinetic machinery in which the key player is a tubulin homologue, FtsZ. Most rod‐shaped bacteria divide precisely at mid‐cell between segregated sister chromosomes. Selection of the correct site for cell division is thought to be determined by two negative regulatory systems: the nucleoid occlusion system, which prevents division in the vicinity of the chromosomes, and the Min system, which prevents inappropriate division at the cell poles. In Bacillus subtilis recruitment of the division inhibitor MinCD to cell poles depends on DivIVA, and these proteins were thought to be sufficient for Min function. We have now identified a novel component of the division‐site selection system, MinJ, which bridges DivIVA and MinD. minJ mutants are impaired in division because MinCD activity is no longer restricted to cell poles. Although MinCD was thought to act specifically on FtsZ assembly, analysis of minJ and divIVA mutants showed that their block in division occurs downstream of FtsZ. The results support a model in which the main function of the Min system lies in allowing only a single round of division per cell cycle, and that MinCD acts at multiple levels to prevent inappropriate division.     

The Min system and nucleoid occlusion are not required for identifying the division site in Bacillus subtilis but ensure its efficient utilization

Precise temporal and spatial control of cell division is essential for progeny survival. The current general view is that precise positioning of the division site at midcell in rod-shaped bacteria is a result of the combined action of the Min system and nucleoid (chromosome) occlusion. Both systems prevent assembly of the cytokinetic Z ring at inappropriate places in the cell, restricting Z rings to the correct site at midcell. Here we show that in the bacterium Bacillus subtilis Z rings are positioned precisely at midcell in the complete absence of both these systems, revealing the existence of a mechanism independent of Min and nucleoid occlusion that identifies midcell in this organism. We further show that Z ring assembly at midcell is delayed in the absence of Min and Noc proteins, while at the same time FtsZ accumulates at other potential division sites. This suggests that a major role for Min and Noc is to ensure efficient utilization of the midcell division site by preventing Z ring assembly at potential division sites, including the cell poles. Our data lead us to propose a model in which spatial regulation of division in B. subtilis involves identification of the division site at midcell that requires Min and nucleoid occlusion to ensure efficient Z ring assembly there and only there, at the right time in the cell cycle.     

The Min system is not required for precise placement of the midcell Z ring in Bacillus subtilis

In bacteria, the Min system plays a role in positioning the midcell division site by inhibiting the formation of the earliest precursor of cell division, the Z ring, at the cell poles. However, whether the Min system also contributes to establishing the precise placement of the midcell Z ring is unresolved. We show that the Z ring is positioned at midcell with a high degree of precision in Bacillus subtilis, and this is completely maintained in the absence of the Min system. Min is therefore not required for correct midcell Z ring placement in B. subtilis. Our results strongly support the idea that the primary role of the Min system is to block Z ring formation at the cell poles and that a separate mechanism must exist to ensure cell division occurs precisely at midcell.     

Identifying how bacterial cells find their middle: a new perspective

Bacterial cell division begins with the polymerization of the FtsZ protein to form a Z ring at the division site. This ring subsequently recruits the division machinery to allow cytokinesis. How the Z ring is positioned correctly remains a challenging question in biology and our knowledge in this area has been restricted to a few model species. Spatial regulation of division in these bacteria has been considered to be negatively controlled, with Z rings assembling in the area of least inhibition: the cell centre. An article in this issue of Molecular Microbiology reports the discovery of a new protein in Myxococcus xanthus, called PomZ (Positioning at midcell of FtsZ), that is required for the efficient recruitment of the Z ring to the division site. PomZ is a member of the Mrp/Min family of P loop ATPases that includes a diverse range of proteins involved in spatial regulation in bacteria. PomZ is the first positive regulator of Z ring positioning to be identified in vegetatively growing bacterial cells. Positive spatial regulation of division has previously been observed during sporulation in Streptomyces coelicolor and has been suggested to occur in Bacillus subtilis. Perhaps this will emerge as a common theme in the future.     

SlmA, a nucleoid-associated, FtsZ binding protein required for blocking septal ring assembly over Chromosomes in E. coli

Cell division in Escherichia coli begins with assembly of the tubulin-like FtsZ protein into a ring structure just underneath the cell membrane. Spatial control over Z ring assembly is achieved by two partially redundant negative regulatory systems, the Min system and nucleoid occlusion (NO), which cooperate to position the division site at midcell. In contrast to the well-studied Min system, almost nothing is known about how Z ring assembly is blocked in the vicinity of nucleoids to effect NO. Reasoning that Min function might become essential in cells impaired for NO, we screened for mutations synthetically lethal with a defective Min system (slm mutants). By using this approach, we identified SlmA (Ttk) as the first NO factor in E. coli. Our combined genetic, cytological, and biochemical results suggest that SlmA is a DNA-associated division inhibitor that is directly involved in preventing Z ring assembly on portions of the membrane surrounding the nucleoid.     

Asymmetric growth and division in Mycobacterium spp.: compensatory mechanisms for non‐medial septa

Mycobacterium spp., rod‐shaped cells belonging to the phylum Actinomycetes, lack the Min‐ and Noc/Slm systems responsible for preventing the placement of division sites at the poles or over the nucleoids to ensure septal assembly at mid‐cell. We show that the position for establishment of the FtsZ‐ring in exponentially growing Mycobacterium marinum and Mycobacterium smegmatis cells is nearly random, and that the cells often divide non‐medially, producing two unequal but viable daughters. Septal sites and cellular growth disclosed by staining with the membrane‐specific dye FM4‐64 and fluorescent antibiotic vancomycin (FL‐Vanco), respectively, showed that many division sites were off‐centre, often over the nucleoids, and that apical cell growth was frequently unequal at the two poles. DNA transfer through the division septum was detected, and translocation activity was supported by the presence of a putative mycobacterial DNA translocase (MSMEG2690) at the majority of the division sites. Time‐lapse imaging of single live cells through several generations confirmed both acentric division site placement and unequal polar growth in mycobacteria. Our evidence suggests that post‐septal DNA transport and unequal polar growth may compensate for the non‐medial division site placement in Mycobacterium spp.     

A cell length‐dependent transition in MinD‐dynamics promotes a switch in division‐site placement and preservation of proliferating elongated Vibrio parahaemolyticus swarmer cells

Vibrio parahaemolyticus exists as swimmer and swarmer cells, specialized for growth in liquid and on solid environments respectively. Swarmer cells are characteristically highly elongated due to an inhibition of cell division, but still need to divide in order to proliferate and expand the colony. It is unknown how long swarmer cells divide without diminishing the population of long cells required for swarming behavior. Here we show that swarmer cells divide but the placement of the division site is cell length‐dependent; short swarmers divide at mid‐cell, while long swarmers switch to a specific non‐mid‐cell placement of the division site. Transition to non‐mid‐cell positioning of the Z‐ring is promoted by a cell length‐dependent switch in the localization‐dynamics of the division regulator MinD from a pole‐to‐pole oscillation in short swarmers to a multi‐node standing‐wave oscillation in long swarmers. Regulation of FtsZ levels restricts the number of divisions to one and SlmA ensures sufficient free FtsZ to sustain Z‐ring formation by preventing sequestration of FtsZ into division deficient clusters. By limiting the number of division‐events to one per cell at a specific non‐mid‐cell position, V. parahaemolyticus promotes the preservation of long swarmer cells and permits swarmer cell division without the need for dedifferentiation.     

A new factor stimulating peptidoglycan hydrolysis to separate daughter cells in Caulobacter crescentus

Cell division in Gram‐negative bacteria involves the co‐ordinated invagination of the three cell envelope layers to form two new daughter cell poles. This complex process starts with the polymerization of the tubulin‐like protein FtsZ into a Z‐ring at mid‐cell, which drives cytokinesis and recruits numerous other proteins to the division site. These proteins are involved in Z‐ring constriction, inner‐ and outer‐membrane invagination, peptidoglycan remodelling and daughter cell separation. Three papers in this issue of Molecular Microbiology, from the teams of Lucy Shapiro, Martin Thanbichler and Christine Jacobs‐Wagner, describe a novel protein, called DipM for Division Involved Protein with LysM domains, that is required for cell division in Caulobacter crescentus. DipM localizes to the mid‐cell during cell division, where it is necessary for the hydrolysis of the septal peptidoglycan to remodel the cell wall. Loss of DipM results in severe defects in cell envelope constriction, which is deleterious under fast‐growth conditions. State‐of‐the‐art microscopy experiments reveal that the peptidoglycan is thicker and that the cell wall is incorrectly organized in DipM‐depleted cells compared with wild‐type cells, demonstrating that DipM is essential for reorganizing the cell wall at the division site, for envelope invagination and cell separation in Caulobacter.     

The ParB homologs,Spo0J and Noc,together prevent premature midcell Z ring assembly when the early stages of replication are blocked in Bacillus subtilis

Precise cell division in coordination with DNA replication and segregation is of utmost importance for all organisms. The earliest stage of cell division is the assembly of a division protein FtsZ into a ring, known as the Z ring, at midcell. What still eludes us, however, is how bacteria precisely position the Z ring at midcell. Work in B. subtilis over the last two decades has identified a link between the early stages of DNA replication and cell division. A recent model proposed that the progression of the early stages of DNA replication leads to an increased ability for the Z ring to form at midcell. This model arose through studies examining Z ring position in mutants blocked at different steps of the early stages of DNA replication. Here, we show that this model is unlikely to be correct and the mutants previously studied generate nucleoids with different capacity for blocking midcell Z ring assembly. Importantly, our data suggest that two proteins of the widespread ParB family, Noc and Spo0J are required to prevent Z ring assembly over the bacterial nucleoid and help fine tune the assembly of the Z ring at midcell during the cell cycle.     

FtsZ rings in mukB mutants with or without the Min system

The site of cell division in Escherichia coli is defined by formation of the Z ring between the two segregated daughter nucleoids. Positioning of the Z ring, composed of the highly conserved and tubulin-like FtsZ protein, appears to be negatively regulated by both the nucleoid and the oscillating MinCD inhibitor proteins. MukB protein is probably involved in nucleoid condensation, and in the absence of MukB, the negative effect of the nucleoid on Z rings appears to be partially suppressed. In this study, we examined the localization of Z rings in cells lacking both the Min system and MukB. In the Deltamin DeltamukB double null mutant, essentially all nucleoid-free zones, either at the cell poles or at non-polar sites between nucleoids, contained Z rings. However, a significant proportion of Z rings also formed on top of nucleoids. Interestingly, Z ring clusters often formed at gaps between nucleoids, and some of the rings within the clusters were clearly positioned on top of nucleoids. These results provide further evidence that the negative topological effect of nucleoids in cells lacking MukB is partially but not totally suppressed, and that the absence of the Min system allows more promiscuous Z ring formation.     

Spatial regulation of cytokinesis in bacteria

Cytokinesis in bacteria such as Escherichia coli is orchestrated by FtsZ, a tubulin-like protein that forms a circumferential Z ring at the division site. The Z ring then recruits a number of other essential cell division proteins, ultimately assembling the cytokinetic machine that splits the cell. It has been known for some time that the MinCDE proteins and the bacterial nucleoid provide positional information to negatively regulate cytokinesis. Recently, direct visualization of Z rings and Min proteins in whole cells have contributed important new insights into the molecular mechanisms behind this fundamental cellular process. This review summarizes and integrates these insights.     

PomZ,a ParA‐like protein,regulates Z‐ring formation and cell division in Myxococcus xanthus

Accurate positioning of the division site is essential to generate appropriately sized daughter cells with the correct chromosome number. In bacteria, division generally depends on assembly of the tubulin homologue FtsZ into the Z‐ring at the division site. Here, we show that lack of the ParA‐like protein PomZ in Myxococcus xanthus resulted in division defects with the formation of chromosome‐free minicells and filamentous cells. Lack of PomZ also caused reduced formation of Z‐rings and incorrect positioning of the few Z‐rings formed. PomZ localization is cell cycle regulated, and PomZ accumulates at the division site at midcell after chromosome segregation but prior to FtsZ as well as in the absence of FtsZ. FtsZ displayed cooperative GTP hydrolysis in vitro but did not form detectable filaments in vitro. PomZ interacted with FtsZ in M. xanthus cell extracts. These data show that PomZ is important for Z‐ring formation and is a spatial regulator of Z‐ring formation and cell division. The cell cycle‐dependent localization of PomZ at midcell provides a mechanism for coupling cell cycle progression and Z‐ring formation. Moreover, the data suggest that PomZ is part of a system that recruits FtsZ to midcell, thereby, restricting Z‐ring formation to this position.     

An essential enzyme for phospholipid synthesis associates with the Bacillus subtilis divisome

The mechanism by which the membrane synthetic machinery might be co‐organized with the cell‐division architecture during the bacterial cell cycle remains to be investigated. We characterized a key enzyme of phospholipid and fatty acid synthesis in Bacillus subtilis, the acyl–acyl carrier protein phosphate acyltransferase (PlsX), and identified it as a component of the cell‐division machinery. Comprehensive interaction analysis revealed that PlsX interacts with FtsA, the FtsZ‐anchoring protein. PlsX mainly localized at the potential division site independent of FtsA and FtsZ and then colocalized with FtsA. By multidirectional approaches, we revealed that the Z‐ring stabilizes the association of PlsX at the septum and pole. The localization of PlsX is also affected by the progression of DNA replication. PlsX is needed for cell division and its inactivation leads to aberrant Z‐ring formation. We propose that PlsX localization is prior to Z‐ring formation in the hierarchy of septum formation events and that PlsX is important for co‐ordinating membrane synthesis with cell division in order to properly complete septum formation.     

Crystal structure of Helicobacter pylori MinE,a cell division topological specificity factor

In Gram‐negative bacteria, proper placement of the FtsZ ring, mediated by nucleoid occlusion and the activities of the dynamic oscillating Min proteins MinC, MinD and MinE, is required for correct positioning of the cell division septum. MinE is a topological specificity factor that counters the activity of MinCD division inhibitor at the mid‐cell division site. Its structure consists of an anti‐MinCD domain and a topology specificity domain (TSD). Previous NMR analysis of truncated Escherichia coli MinE showed that the TSD domain contains a long α‐helix and two anti‐parallel β‐strands, which mediate formation of a homodimeric α/β structure. Here we report the crystal structure of full‐length Helicobacter pylori MinE and redefine its TSD based on that structure. The N‐terminal region of the TSD (residues 19–26), previously defined as part of the anti‐MinCD domain, forms a β‐strand (βA) and participates in TSD folding. In addition, H. pylori MinE forms a dimer through the interaction of anti‐parallel βA‐strands. Moreover, we observed serial dimer–dimer interactions within the crystal packing, resulting in the formation of a multimeric structure. We therefore redefine the functional domain of MinE and propose that a multimeric filamentous structure is formed through anti‐parallel β‐strand interactions.     

The N‐succinyl‐l,l‐diaminopimelic acid desuccinylase DapE acts through ZapB to promote septum formation in Escherichia coli

Spatial regulation of cell division in Escherichia coli occurs at the stage of Z ring formation. It consists of negative (the Min and NO systems) and positive (Ter signal mediated by MatP/ZapA/ZapB) regulators. Here, we find that N‐succinyl‐L,L‐diaminopimelic acid desuccinylase (DapE) facilitates functional Z ring formation by strengthening the Ter signal via ZapB. DapE depends on ZapB to localize to the Z ring and its overproduction suppresses the division defect caused by loss of both the Min and NO systems. DapE shows a strong interaction with ZapB and requires the presence of ZapB to exert its function in division. Consistent with the idea that DapE strengthens the Ter signal, overproduction of DapE supports cell division with reduced FtsZ levels and provides some resistance to the FtsZ inhibitors MinCD and SulA, while deletion of dapE, like deletion of zapB, exacerbates the phenotypes of cells impaired in Z ring formation such as ftsZ84 or a min mutant. Taken together, our results report DapE as a new component of the divisome that promotes the integrity of the Z ring by acting through ZapB and raises the possibility of the existence of additional divisome proteins that also function in other cellular processes.     

Staphylococcus aureus requires at least one FtsK/SpoIIIE protein for correct chromosome segregation

Faithful coordination between bacterial cell division and chromosome segregation in rod‐shaped bacteria, such as Escherichia coli and Bacillus subtilis, is dependent on the DNA translocase activity of FtsK/SpoIIIE proteins, which move DNA away from the division site before cytokinesis is completed. However, the role of these proteins in chromosome partitioning has not been well studied in spherical bacteria. Here, it was shown that the two Staphylococcus aureus FtsK/SpoIIIE homologues, SpoIIIE and FtsK, operate in independent pathways to ensure correct chromosome management during cell division. SpoIIIE forms foci at the centre of the closing septum in at least 50% of the cells that are close to complete septum synthesis. FtsK is a multifunctional septal protein with a C‐terminal DNA translocase domain that is not required for correct chromosome management in the presence of SpoIIIE. However, lack of both SpoIIIE and FtsK causes severe nucleoid segregation and morphological defects, showing that the two proteins have partially redundant roles in S. aureus.     

Direct interaction of FtsZ and MreB is required for septum synthesis and cell division in Escherichia coli

How bacteria coordinate cell growth with division is not well understood. Bacterial cell elongation is controlled by actin–MreB while cell division is governed by tubulin–FtsZ. A ring‐like structure containing FtsZ (the Z ring) at mid‐cell attracts other cell division proteins to form the divisome, an essential protein assembly required for septum synthesis and cell separation. The Z ring exists at mid‐cell during a major part of the cell cycle without contracting. Here, we show that MreB and FtsZ of Escherichia coli interact directly and that this interaction is required for Z ring contraction. We further show that the MreB–FtsZ interaction is required for transfer of cell‐wall biosynthetic enzymes from the lateral to the mature divisome, allowing cells to synthesise the septum. Our observations show that bacterial cell division is coupled to cell elongation via a direct and essential interaction between FtsZ and MreB.     

The essential role of SepF in mycobacterial division

Mycobacteria lack several of the components that are essential in model systems as Escherichia coli or Bacillus subtilis for the formation of the divisome, a ring‐like structure assembling at the division site to initiate bacterial cytokinesis. Divisome assembly depends on the correct placement of the FtsZ protein into a structure called the Z ring. Notably, early division proteins that assist in the localisation of the Z ring to the cytoplasmic membrane and modulate its structure are missing in the so far known mycobacterial cell division machinery. To find mycobacterium‐relevant components of the divisome that might act at the level of FtsZ, a yeast two‐hybrid screening was performed with FtsZ from Mycobacterium tuberculosis. We identified the SepF homolog as a new interaction partner of mycobacterial FtsZ. Depending on the presence of FtsZ, SepF‐GFP fusions localised in ring‐like structures at potential division sites. Alteration of SepF levels in Mycobacterium smegmatis led to filamentous cells, indicating a division defect. Depletion of SepF resulted in a complete block of division. The sepF gene is highly conserved in the M. tuberculosis complex members. We therefore propose that SepF is an essential part of the core division machinery in the genus Mycobacterium.