Diverse paths to midcell: assembly of the bacterial cell division machinery

At the heart of bacterial cell division is a dynamic ring-like structure of polymers of the tubulin homologue FtsZ. This ring forms a scaffold for assembly of at least ten additional proteins at midcell, the majority of which are likely to be involved in remodeling the peptidoglycan cell wall at the division site. Together with FtsZ, these proteins are thought to form a cell division complex, or divisome. In Escherichia coli, the components of the divisome are recruited to midcell according to a strikingly linear hierarchy that predicts a step-wise assembly pathway. However, recent studies have revealed unexpected complexity in the assembly steps, indicating that the apparent linearity does not necessarily reflect a temporal order. The signals used to recruit cell division proteins to midcell are diverse and include regulated self-assembly, protein-protein interactions, and the recognition of specific septal peptidoglycan substrates. There is also evidence for a complex web of interactions among these proteins and at least one distinct subcomplex of cell division proteins has been defined, which is conserved among E. coli, Bacillus subtilis and Streptococcus pneumoniae.     

Premature targeting of cell division proteins to midcell reveals hierarchies of protein interactions involved in divisome assembly

In order to divide, the bacterium Escherichia coli must assemble a set of at least 10 essential proteins at the nascent division site. These proteins localize to midcell according to a linear hierarchy, suggesting that cell division proteins are added to the nascent divisome in strict sequence. We previously described a method, 'premature targeting', which allows us to target a protein directly to the division site independently of other cell division proteins normally required for its localization at midcell. By systematically applying this method to probe the recruitment of and associations among late cell division proteins, we show that this linear assembly model is likely incorrect. Rather, we find that the assembly of most of the late proteins can occur independently of 'upstream' proteins. Further, most late proteins, when prematurely targeted to midcell, can back-recruit upstream proteins in the reverse of the predicted pathway. Together these observations indicate that the late proteins, with the notable exception of the last protein in the pathway, FtsN, are associated in a hierarchical set of protein complexes. Based on these observations we present a revised model for assembly of the E. coli division apparatus.     

Occludin and claudin-1 concentrate in the midbody of immortalized mouse hepatocytes during cell division.

It has been believed that epithelial cells maintain tight junctions at all times, including during cell division, to provide a continuous epithelial seal. However, changes in localization of integral tight junction proteins during cell division have not been examined. In this study, using SV40-immortalized mouse hepatocytes transfected with human Cx32 cDNA, in which tight junction strands and the endogenous tight junction proteins occludin, claudin-1, ZO-1, and ZO-2 were induced, we examined changes in localization of the tight junction proteins at all stages of cell division. All tight junction proteins were present between mitotic cells and neighboring cells throughout cell division. In late telophase, the integral tight junction proteins occludin and claudin-1, but not the cytoplasmic proteins ZO-1 and ZO-2, were concentrated in the midbody between the daughter cells and were observed at cell borders between the daugher and neighboring cells. These results indicate that the integral tight junction proteins are regulated in a different manner from the cytoplasmic proteins ZO-1 and ZO-2 during cytokinesis.     

Extracellular control of cell size

Both cell growth (cell mass increase) and progression through the cell division cycle are required for sustained cell proliferation. Proliferating cells in culture tend to double in mass before each division, but it is not known how growth and division rates are co-ordinated to ensure that cell size is maintained. The prevailing view is that coordination is achieved because cell growth is rate-limiting for cell-cycle progression. Here, we challenge this view. We have investigated the relationship between cell growth and cell-cycle progression in purified rat Schwann cells, using two extracellular signal proteins that are known to influence these cells. We find that glial growth factor (GGF) can stimulate cell-cycle progression without promoting cell growth. We have used this restricted action of GGF to show that, for cultured Schwann cells, cell growth rate alone does not determine the rate of cell-cycle progression and that cell size at division is variable and depends on the concentrations of extracellular signal proteins that stimulate cell-cycle progression, cell growth, or both.     

Early targeting of Min proteins to the cell poles in germinated spores of Bacillus subtilis: evidence for division apparatus-independent recruitment of Min proteins to the division site

The earliest event in bacterial cell division is the assembly of a tubulin-like protein, FtsZ, at mid-cell to form a ring. In rod-shaped bacteria, the Min system plays an important role in division site placement by inhibiting FtsZ ring formation specifically at the polar regions of the cell. The Min system comprises MinD and MinC, which form an inhibitor complex and, in Bacillus subtilis, DivIVA, which ensures that division is inhibited only in the polar regions. All three proteins localize to the division site at mid-cell and to cell poles. Their recruitment to the division site is dependent on localization of both 'early' and 'late' division proteins. We have examined the temporal and spatial localization of DivIVA relative to that of FtsZ during the first and second cell division after germination and outgrowth of B. subtilis spores. We show that, although the FtsZ ring assembles at mid-cell about halfway through the cell cycle, DivIVA assembles at this site immediately before cell division and persists there during Z-ring constriction and completion of division. We also show that both DivIVA and MinD localize to the cell poles immediately upon spore germination, well before a Z ring forms at mid-cell. Furthermore, these proteins were found to be present in mature, dormant spores. These results suggest that targeting of Min proteins to division sites does not depend directly on the assembly of the division apparatus, as suggested previously, and that potential polar division sites are blocked at the earliest possible stage in the cell cycle in germinated spores as a mechanism to ensure that equal-sized daughter cells are produced upon cell division.     

FtsZ and the division of bacterial cell

In this review we have tried to describe proteins and supermolecular structures which take part in the division of bacterial cell. The principal cell division protein of the most of prokaryotes is FtsZ, a homologue of eukaryotic tubulin. FtsZ just as tubulin is capable to bind and hydrolyze GTP. The division of bacterial cell begins with forming of so called divisome. The basis of such divisome is a contractile ring (Z ring); the ring encircles the cell about midcell. Z ring consists of a bundle of laterally bound protofilaments, which have been formed as a result of FtsZ polymerization. Z ring is rigidly bounded to cytozolic side of inner membrane with participation of FtsA, ZipA, FtsW and many other cell division proteins of divisome. The ring directs the process of cytokinesis transmitting power of constriction to membrane. Primary structures of members of the family of prokaryotic FtsZs differ from eukaryotic tubulines significantly except the region, where the site of GTP binding is placed. There is high degree of homology between structures of these proteins in the region. FtsZ is one of the most conservative proteins in prokaryotes, but ftsZ genes have not been found in completely sequenced genomes of several species of microorganisms. There are 2 species of mycoplasmas (Ureaplasma parvum and Mycoplasma mobile), Prostecobacter dejongeii, 10 species of chlamydia and 5 species of archaea among them. So these organisms divide without FtsZ. There are many open reading frames which encode proteins with unknown functions in genomes of U. parvum and M. mobile. The comparison of primary structures of these hypothetical proteins with structures of cell division proteins did not allow researchers to find similar proteins among them. We suppose that the process of cell division of these organisms should recruit proteins with function similar to FtsZ and having homologous with FtsZ or other cell division proteins spatial structures.     

Linking cell division to cell growth in a spatiotemporal model of the cell cycle

Cell division must be tightly coupled to cell growth in order to maintain cell size, yet the mechanisms linking these two processes are unclear. It is known that almost all proteins involved in cell division shuttle between cytoplasm and nucleus during the cell cycle; however, the implications of this process for cell cycle dynamics and its coupling to cell growth remains to be elucidated. We developed mathematical models of the cell cycle which incorporate protein translocation between cytoplasm and nucleus. We show that protein translocation between cytoplasm and nucleus not only modulates temporal cell cycle dynamics, but also provides a natural mechanism coupling cell division to cell growth. This coupling is mediated by the effect of cytoplasmic-to-nuclear size ratio on the activation threshold of critical cell cycle proteins, leading to the size-sensing checkpoint (sizer) and the size-independent clock (timer) observed in many cell cycle experiments.     

Controlling the switches: Rho GTPase regulation during animal cell mitosis

Animal cell division is a fundamental process that requires complex changes in cytoskeletal organization and function. Aberrant cell division often has disastrous consequences for the cell and can lead to cell senescence, neoplastic transformation or death. As important regulators of the actin cytoskeleton, Rho GTPases play major roles in regulating many aspects of mitosis and cytokinesis. These include centrosome duplication and separation, generation of cortical rigidity, microtubule–kinetochore stabilization, cleavage furrow formation, contractile ring formation and constriction, and abscission. The ability of Rho proteins to function as regulators of cell division depends on their ability to cycle between their active, GTP-bound and inactive, GDP-bound states. However, Rho proteins are inherently inefficient at fulfilling this cycle and require the actions of regulatory proteins that enhance GTP binding (RhoGEFs), stimulate GTPase activity (RhoGAPs), and sequester inactive Rho proteins in the cytosol (RhoGDIs). The roles of these regulatory proteins in controlling cell division are an area of active investigation. In this review we will delineate the current state of knowledge of how specific RhoGEFs, RhoGAPs and RhoGDIs control mitosis and cytokinesis, and highlight the mechanisms by which their functions are controlled.     

Interaction network among Escherichia coli membrane proteins involved in cell division as revealed by bacterial two-hybrid analysis

Formation of the Escherichia coli division septum is catalyzed by a number of essential proteins (named Fts) that assemble into a ring-like structure at the future division site. Several of these Fts proteins are intrinsic transmembrane proteins whose functions are largely unknown. Although these proteins appear to be recruited to the division site in a hierarchical order, the molecular interactions underlying the assembly of the cell division machinery remain mostly unspecified. In the present study, we used a bacterial two-hybrid system based on interaction-mediated reconstitution of a cyclic AMP (cAMP) signaling cascade to unravel the molecular basis of septum assembly by analyzing the protein interaction network among E. coli cell division proteins. Our results indicate that the Fts proteins are connected to one another through multiple interactions. A deletion mapping analysis carried out with two of these proteins, FtsQ and FtsI, revealed that different regions of the polypeptides are involved in their associations with their partners. Furthermore, we showed that the association between two Fts hybrid proteins could be modulated by the coexpression of a third Fts partner. Altogether, these data suggest that the cell division machinery assembly is driven by the cooperative association among the different Fts proteins to form a dynamic multiprotein structure at the septum site. In addition, our study shows that the cAMP-based two-hybrid system is particularly appropriate for analyzing molecular interactions between membrane proteins.     

FtsZ and bacterial cell division

In this review we describe proteins and supermolecular structures which take part in the division of bacterial cells. FtsZ, a eukaryotic tubulin homolog is a key cell division protein in most prokaryotes. FtsZ, as well as tubulin, is capable of binding and hydrolyzing GTP. The division of a bacterial cell begins with the forming of a so-called divisome. The basis of such a divisome is a contractile ring (Z ring) which encircles the cell about midcell. The Z-ring consists of a bundle of laterally bound protofilaments formed in result of FtsZ polymerization. Z-ring is rigidly bounded to the cytosolic side of the inner membrane with the participation of FtsA, ZipA, FtsW and many other divisome cell division proteins. The ring directs the process of cytokinesis transmitting constriction power to the membrane. The primary structures of the prokaryotic FtsZ family members significantly differ from eukaryotic tubulins except for the sites of GTP binding. There is a high degree of structural homology between these proteins in the region. FtsZ is one of the most conserved proteins in prokaryotes. However, ftsZ genes have not been found in several species of microorganisms with completely sequenced genomes. They include two species of mycoplasmas (Ureaplasma parvum and Mycoplasma mobile), Prostecobacter dejongeii, 10 species of chlamydia and 5 species of archaea. Consequently, these organisms divide without FtsZ participation. The genomes of U. parvum and M. mobile have many open reading frames which encode proteins with unknown functions. A comparison of the primary structures of these hypothetical proteins did not identify any known cell division proteins. We hypothesize that the process of cell division in these organisms should involve proteins similar to FtsZ in function and homologous to FtsZ or other cell division proteins in structure.     

A new cell division operon in Escherichia coli

Summary At 76 min on theE. coli genetic map there is a cluster of genes affecting essential cellular functions, including the heat shock response and cell division. A combination ofin-vivo andin-vitro genetic analysis of cell division mutants suggests that the cell division genefts E is the second gene in a 3 gene operon. A cold-sensitive mutant, defective in the third gene, is also unable to divide at the restrictive temperature, and we designate this new cell division genefts X. Another cell division gene,fts S, is very close to, but distinct from, the 3 genes of the operon. Thefts E product is a 24.5 Kd polypeptide which shows strong homology with a small group of proteins involved in transport. Both thefts E product and the protein coded by the first gene (fts Y) in the operon have a sequence motif found in a wide range of heterogeneous proteins, including the Ras proteins of yeast. This common domain is indicative of a nucleotide-binding site.     

Themes and variations in prokaryotic cell division

Perhaps the biggest single task facing a bacterial cell is to divide into daughter cells that contain the normal complement of chromosomes. Recent technical and conceptual breakthroughs in bacterial cell biology, combined with the flood of genome sequence information and the excellent genetic tools in several model systems, have shed new light on the mechanism of prokaryotic cell division. There is good evidence that in most species, a molecular machine, organized by the tubulin-like FtsZ protein, assembles at the site of division and orchestrates the splitting of the cell. The determinants that target the machine to the right place at the right time are beginning to be understood in the model systems, but it is still a mystery how the machine actually generates the constrictive force necessary for cytokinesis. Moreover, although some cell division determinants such as FtsZ are present in a broad spectrum of prokaryotic species, the lack of FtsZ in some species and different profiles of cell division proteins in different families suggests that there are diverse mechanisms for regulating cell division.     

Transposon insertions in the Flavobacterium johnsoniae ftsX gene disrupt gliding motility and cell division

Flavobacterium johnsoniae is a gram-negative bacterium that exhibits gliding motility. To determine the mechanism of flavobacterial gliding motility, we isolated 33 nongliding mutants by Tn4351 mutagenesis. Seventeen of these mutants exhibited filamentous cell morphology. The region of DNA surrounding the transposon insertion in the filamentous mutant CJ101-207 was cloned and sequenced. The transposon was inserted in a gene that was similar to Escherichia coli ftsX. Two of the remaining 16 filamentous mutants also carried insertions in ftsX. Introduction of the wild-type F. johnsoniae ftsX gene restored motility and normal cell morphology to each of the three ftsX mutants. CJ101-207 appears to be blocked at a late stage of cell division, since the filaments produced cross walls but cells failed to separate. In E. coli, FtsX is thought to function with FtsE in translocating proteins involved in potassium transport, and perhaps proteins involved in cell division, into the cytoplasmic membrane. Mutations in F. johnsoniae ftsX may prevent translocation of proteins involved in cell division and proteins involved in gliding motility into the cytoplasmic membrane, thus resulting in defects in both processes. Alternatively, the loss of gliding motility may be an indirect result of the defect in cell division. The inability to complete cell division may alter the cell architecture and disrupt gliding motility by preventing the synthesis, assembly, or functioning of the motility apparatus.     

Relationship between cell proliferation, chromatin template activity and accumulation of nuclear proteins

Trypsinization of confluent monolayers of WI-38 cells causes an extensive loss of nuclear proteins. The loss of nuclear proteins is restored only several hours after the cells have been replated at a lower density in 10% serum. When trypsinized fibroblasts are replated at a lower density in 10% serum, there is also a sustained progressive leading to DNA synthesis and cell division. If 0.3% serum is used instead of 10%, there is a modest increase in nuclear template activity, but not accumulation of nuclear proteins and no DNA synthesis or cell division.     

Endosymbiosis and evolution of the plant cell

The bacterial origins of plastid division and protein import by plastids are beginning to emerge - thanks largely to the availability of a total genome sequence for a cyanobacterium. Despite existing for hundreds of millions of years within the plant cell host, the chloroplast endosymbiont retains clear hallmarks of its bacterial ancestry. Plastid division relies on proteins that are also responsible for bacterial division, although may of the genes for these proteins have been confiscated by the host. Plastid protein import on the other hand relies on proteins that seem to have functioned originally as exporters but that have now been persuaded to operate in the reverse direction to traffic proteins from the host cell into the endosymbiont.     

Effects of reduction of auxin and destruction of microtubules on cell wall proteins and cell morphology of the BY-2 line of tobacco cells

Variations of cell wall proteins and proteins in the medium associated with changes in cell morphology were investigated in the BY-2 line of cultured cells. BY-2 cells cultured in LS medium grew as long chains of cells, with the plane of division perpendicular to the longitudinal axis. Reduction in the levels of auxin in the medium resulted in inhibition of cell division and promotion of cell elongation. Levels of cell wall proteins in cell walls decreased and relative levels of cell wall proteins and proteins in the medium changed. Upon treatment with the anti-microtubule drug, propyzamide, cells expanded laterally. Level of cell wall proteins and relative levels of individual cell wall proteins did not change very much, but levels of proteins in the culture medium increased. In both cases, levels of acid and basic peroxidases in cell walls increased and isozyme patterns of these changed.     

Beyond the plasma membrane: New functions for heterotrimeric G-protein signaling in asymmetric and symmetric cell division

Plasma membrane heterotrimeric G proteins transduce extracellular signal from seven transmembrane receptors to downstream effectors. In addition, G proteins and their regulators localize at multiple intracellular sites and play crucial roles in cell division. In model organisms such as Caenorhabditis elegans and Drosophila receptor-independent heterotrimeric G protein function is vital for the orientation of mitotic spindle, generation of microtubule pulling force, aster-induced cytokinesis, and centration of the nucleus-centrosome complex. This new paradigm is now being extended to mammalian cells. Mammalian G protein signaling components localize in centrosomes and at the midbody, and altered function or expression of these proteins can cause cell division defects. Here, we highlight the role and possible mechanisms of G protein signaling in mammalian cell division in conjunction with recent findings in model organisms. Together the evidence argues for a more direct role of non-canonical heterotrimeric G protein signaling in microtubule- and actin cytoskeleton-mediated cellular processes.     

Characterization of YmgF, a 72-residue inner membrane protein that associates with the Escherichia coli cell division machinery

Formation of the Escherichia coli division septum is catalyzed by a number of essential proteins (named Fts) that assemble into a ring-like structure at the future division site. Many of these Fts proteins are intrinsic transmembrane proteins whose functions are largely unknown. In the present study, we attempted to identify a novel putative component(s) of the E. coli cell division machinery by searching for proteins that could interact with known Fts proteins. To do that, we used a bacterial two-hybrid system based on interaction-mediated reconstitution of a cyclic AMP (cAMP) signaling cascade to perform a library screening in order to find putative partners of E. coli cell division protein FtsL. Here we report the characterization of YmgF, a 72-residue integral membrane protein of unknown function that was found to associate with many E. coli cell division proteins and to localize to the E. coli division septum in an FtsZ-, FtsA-, FtsQ-, and FtsN-dependent manner. Although YmgF was previously shown to be not essential for cell viability, we found that when overexpressed, YmgF was able to overcome the thermosensitive phenotype of the ftsQ1(Ts) mutation and restore its viability under low-osmolarity conditions. Our results suggest that YmgF might be a novel component of the E. coli cell division machinery.     

Taking shape: control of bacterial cell wall biosynthesis

The characteristic shape of a bacterial cell is a function of the three dimensional architectures of the cell envelope and is determined by the balance between lateral wall extension and synthesis of peptidoglycan at the division septum. The three dimensional patterns of cell wall synthesis in the bacterium Bacillus subtilis is influenced by actin-like proteins that form helical coils in the cell and by the MreCD membrane proteins that link the cytoskeletal elements with the penicillin-binding proteins that carry out peptidoglycan synthesis. Recent genetic studies have provided important clues as to how these proteins are arranged in the cell and how they function to regulate cell shape.     

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.