Regulation of Cell Division in a Temperature-Sensitive Division Mutant of Escherichia coli

Escherichia coli fil ts forms multinucleate filaments when suspensions of about 10(7) organisms per ml are shifted from 37 to 43 C in rich medium. Occasional septation continues, chiefly at the poles, and immediately becomes more frequent when the filaments are returned to 37 C. The addition of chloramphenicol (200 mug/ml) at either temperature initially stimulates the formation of polar septa. When very dilute suspensions of the strain (<10(6) organisms per ml) are shifted to the restrictive temperature, the inhibition of septation is more complete and only seldom reversible. Conversely, cell division is little affected when suspensions of >10(8) organisms per ml, or microcolonies of several hundred organisms on agar, are incubated at 43 C; evidence is presented that this is a consequence of a slight reduction in the mutant's growth rate. In certain media, septation is blocked irreversibly by even brief exposure to 43 C, after which cell elongation without division proceeds at 37 C for some hours. Several findings, when considered together, suggest that the cytoplasmic membrane is normal at the restrictive temperature, and that the block in septation is caused by a defect in the cell wall: it is largely overcome by NaCl, but not by sucrose; in some circumstances the filaments become swollen and develop localized bulges in the wall, yet the membrane remains intact and retains its selective permeability; lastly, the strain is insensitive to deoxycholate at both temperatures. The mutation has been mapped between arg B and thr, at a locus which appears to be distinct from others known primarily to influence cell division.     

Influence of chromosome integrity on Escherichia coli cell division.

The antitumor agent cis-platinum(II)diamminodichloride (PDD) caused wild-type and recA+ deoxyribonucleic acid (DNA) repair-deficient mutant cells of Escherichia coli K-12 to grow as long, multinucleated filaments. At 5 micrograms/ml, the times required for reduction of viability to 37% for wild-type, polA, recB,C, uvrA, and recA organisms were > 200, 200, 120, 25, and 5 min, respectively. Only recA cells exhibited @reckless" degradation of DNA at this concentration of PDD. As shown by sedimentation in alkaline sucrose gradients, generation of single-strand breaks in DNA of the remaining organisms was a major consequence of growth in PDD. Upon incubation in fresh medium after removal of the compound and storage for 4 h at 4 degrees C, a respective lag of 3, 4, 6, and 9 h occurred before filaments of wild-type, polA, recB,C, and uvrA cells commenced cell division. Maintenance at 4 degrees C, which evidently delayed postshift initiation of chromosome replication, was only essential for fragmentation of uvrA filaments. In all cases, these periods of division delay corresponded to those required for restoration of normal chromosomal molecular weight as determined in alkaline sucrose gradients.     

Generation of buds, swellings, and branches instead of filaments after blocking the cell cycle of Rhizobium meliloti.

Inhibition of cell division in rod-shaped bacteria such as Escherichia coli and Bacillus subtilis results in elongation into long filaments many times the length of dividing cells. As a first step in characterizing the Rhizobium meliloti cell division machinery, we tested whether R. meliloti cells could also form long filaments after cell division was blocked. Unexpectedly, DNA-damaging agents, such as mitomycin C and nalidixic acid, caused only limited elongation. Instead, mitomycin C in particular induced a significant proportion of the cells to branch at the poles. Moreover, methods used to inhibit septation, such as FtsZ overproduction and cephalexin treatment, induced growing cells to swell, bud, or branch while increasing in mass, whereas filamentation was not observed. Overproduction of E. coli FtsZ in R. meliloti resulted in the same branched morphology, as did overproduction of R. meliloti FtsZ in Agrobacterium tumefaciens. These results suggest that in these normally rod-shaped species and perhaps others, branching and swelling are default pathways for increasing mass when cell division is blocked.     

Cell division in Escherichia coli: evidence for regulation of septation by effector molecules

Evidence regarding the regulation of cell division has been obtained from the study of septation in a mutant of Escherichia coli. The mutant, MX74T2 ts52, gradually stops dividing when transferred from 30 to 41°C in rich medium, but forms long filaments and continues to synthesize DNA and protein. These filaments serve as test objects for the investigation of the regulation of septation. A synchronous cell division of the filaments is induced after 15 minutes, even at 41°C, by the addition of chloramphenicol (100 μg/ml.), rifampicin (200 μg/ml.), or by transfer to minimal medium. Blocking of protein formation with puromycin (500 μg/ml.) or amino-acid analogues does not permit septation. Thus, septation appears to be coupled to inhibition of peptide bond formation rather than protein synthesis. A model for the control of cell division is proposed in which a small effector molecule that is related to peptide bond formation is needed for septation.     

Constriction and septation during cell division in caulobacters

Morphogenesis of the division site in caulobacters had been described as constrictive in Caulobacter spp. and septate in Asticcacaulis excentricus. However, subsequent studies of other gram-negative genera had implied that constrictive division was an artefact resulting from inadequate preservation of septa; exploration of alternatives to osmium fixation, particularly with aldehydes, was recommended. In this study, the appearance of sectioned division sites was reinvestigated in caulobacter cells prepared by 20 different procedures varying with respect to fixation agents, media, schedules, and temperatures, to dehydrating agents, and to embedding resins. Three types of division site morphogenesis were observed: constriction in C. bacteroides and C. crescentus, partial septation in C. leidyi, and complete, undivided septation in A. excentricus and A. biprosthecum. The anatomy of the division site depended on the bacterial strain, not on the method of preparation of the cells for sectioning. These studies confirm the earlier observations on osmium-fixed caulobacter cells and lead to the general conclusion that gram-negative bacteria with tapered poles probably divide by constriction, whereas septation results in blunt cell poles. A pattern of spiral, rather than circular, insertion of new envelope subunits at the cell equator is proposed as a basic developmental difference between constrictive and septate fission in gram-negative bacteria. Since caulobacter prosthecae can develop as extensions of tapered poles formed by constriction, whereas subpolar or lateral prosthecae occur in species with blunt poles resulting from septation, the site of formation of a thick septum appears unsuitable as a site of subsequent envelope outgrowth.     

Rule governing the division pattern in Escherichia coli minB and wild-type filaments.

Escherichia coli minB mutants form anucleate minicells and multinucleate filaments. We show here that the overwhelming majority of nucleate cells contain 2n (n = 0, 1, 2, ...) nucleoids, as determined by 4',6-diamidino-2-phenylindole staining, and 2n (n = 1, 2, 3, ...) copies of the replication origin, as determined by flow cytometry. This shows that division sites are not chosen randomly among the available sites in minB filaments. Similarly, wild-type cells contain 2n nucleoids, both during cell division inhibition and when furazlocillin-induced filaments are allowed to divide. We conclude that the min+ function is only to prevent septation only at polar sites; the placement of internal cell division sites must obey strict rules, which are the same in minB and wild-type cells.     

Requirement of a cell division step for stalk formation in Caulobacter crescentus.

Penicillin G at low concentrations blocked cell division in Caulobacter crescentus without inhibiting cell growth. The long filamentous cells formed after two to three generations under these conditions had a stalk at one pole and usually one or more flagella at the opposite pole. The failure of the filaments to form a second stalk at the flagellated pole indicates that stalk formation was dependent upon completion of a step that was also required for cell division. Two observations support this conclusion. (i) Penicillin did not stop the normal development of synchronous swarmer cells into stalked initiation and stalk elongation. (ii) When the action of penicillin was reversed by the addition of penicillinase to cultures of filaments, stalks were not formed at the nonstalked pole until after cell division had occurred; thus the normal order of development events was maintained: cell division leads to stalk formation. These results are consistent with a model in which the organization of the developmental program for stalk formation occurs before cell division as a consequence of steps that branch from the cell division pathway.     

Aip3p/Bud6p, a yeast actin-interacting protein that is involved in morphogenesis and the selection of bipolar budding sites.

A search for Saccharomyces cerevisiae proteins that interact with actin in the two-hybrid system and a screen for mutants that affect the bipolar budding pattern identified the same gene, AIP3/BUD6. This gene is not essential for mitotic growth but is necessary for normal morphogenesis. MATa/alpha daughter cells lacking Aip3p place their first buds normally at their distal poles but choose random sites for budding in subsequent cell cycles. This suggests that actin and associated proteins are involved in placing the bipolar positional marker at the division site but not at the distal tip of the daughter cell. In addition, although aip3 mutant cells are not obviously defective in the initial polarization of the cytoskeleton at the time of bud emergence, they appear to lose cytoskeletal polarity as the bud enlarges, resulting in the formation of cells that are larger and rounder than normal. aip3 mutant cells also show inefficient nuclear migration and nuclear division, defects in the organization of the secretory system, and abnormal septation, all defects that presumably reflect the involvement of Aip3p in the organization and/or function of the actin cytoskeleton. The sequence of Aip3p is novel but contains a predicted coiled-coil domain near its C terminus that may mediate the observed homo-oligomerization of the protein. Aip3p shows a distinctive localization pattern that correlates well with its likely sites of action: it appears at the presumptive bud site prior to bud emergence, remains near the tips of small bund, and forms a ring (or pair of rings) in the mother-bud neck that is detectable early in the cell cycle but becomes more prominent prior to cytokinesis. Surprisingly, the localization of Aip3p does not appear to require either polarized actin or the septin proteins of the neck filaments.     

Structural inhibition and reactivation of Escherichia coli septation by elements of the SOS and TER pathways.

The inhibition of cell division caused by induction of the SOS pathway in Escherichia coli structurally blocks septation, as deduced from two sets of results. Potential septation sites active at the time of SOS induction became inactivated, while those initiated during the following doubling time were active. Penicillin resistance increased in wild-type UV light-irradiated cells, a behavior similar to that observed in mutants in which structural blocks were introduced by inactivation of FtsA. Potential septation sites that have been structurally blocked by either the SOS division inhibitor, furazlocillin inhibition of PBP3, or inactivation of a TER pathway component, FtsA3, could be reactivated one doubling time after removal of the inhibitory agent in the presence of an active lon gene product. Reactivation of potential septation sites blocked by the presence of an inactivated FtsA3 was significantly lower when the lon protease was not active, suggesting that Lon plays a role in the removal of inactivated TER pathway products from the blocked potential septation sites.     

Immunofluorescence microscopy of the microtubule cytoskeleton during conjugate division in the dikaryon Pleurotus ostreatus N001

Fluorescence microscopy was used to describe the distribution of nuclei and the organization of the microtubule network in hyphae of Pleurotus ostreatus. Dikaryotic hyphae of P. ostreatus N001 grow by tip extension with two closely spaced nuclei moving slowly forward with the growing hyphal tip. During vegetative growth of the hyphae, cytoplasmic microtubules are found as long filaments oriented longitudinally within fungal hyphae. When the apical cell reaches a length of approximately 150 μm, the two nuclei divide synchronously. Mitosis occurs in association with clamp connection formation, with one of the nuclei dividing in the hook of the developing clamp connection and the other in the main hypha. After mitosis, two daughter nuclei move forward to approximately the center of the apical cell, while the other two move backward to a central position in the subapical cell. Two septa are formed, one in the clamp and the other across the main axis of the hypha to delimit the apical cell. The use of fluorescence microscopy made it possible to examine the changes in the cytoplasmic microtubules, the configuration of the mitotic apparatus, the site of septation and the post-mitotic nuclear migrations during conjugate division in P. ostreatus dikaryotic hyphae.     

A division inhibitor and a topological specificity factor coded for by the minicell locus determine proper placement of the division septum in E. coli

The E. coli minicell locus (minB) was shown to code for three gene products (MinC, MinD, and MinE) whose coordinate action is required for proper placement of the division spetum. Studies of the phenotypic effects of expression of the three genes, alone and in all possible combinations, indicated the following: cell poles contain potential division sites that will support additional septation events unless specifically inactivated; the minC and minD gene products act in concert to form a nonspecific inhibitor of septation that is capable of blocking cell division at all potential division sites; and the minE gene codes for a topological specificity factor that, in wild-type cells, prevents the division inhibitor from acting at internal division sites while permitting it to block septation at polar sites.     

Filamentous Cells of Escherichia coli Formed in the Presence of Mitomycin

The effects of mitomycin C on cell elongation of Escherichia coli B were studied. Filament formation was most marked in cultures treated with a moderate level (1 mug/ml) of the antibiotic, becoming less obvious at higher levels (10 mug/ml). Cells treated with a bacteriostatic concentration (0.1 mug/ml or less) of mitomycin C were also significantly elongated. The filamentous or elongated cells appeared to lack septa, since their spheroplasts were considerably larger than those formed from normal cells. The appearance of empty spheres also indicated some defects in the surfaces of the filamentous cells. Electron micrographs of the filaments revealed a characteristic difference in the arrangement of the nuclei in the filaments formed in the presence of low (0.1 mug/ml) and high (5 mug/ml) concentrations of mitomycin C. The filaments formed by the low level of mitomycin C had normal well-defined nuclear bodies distributed along the long axis, whereas those formed by the elevated level of the antibiotic contained smaller nuclei. The latter were characteristically confined to the center of the cells and did not extend out to the tips of the filaments.     

The structure of FtsZ filaments in vivo suggests a force-generating role in cell division

In prokaryotes, FtsZ (the filamentous temperature sensitive protein Z) is a nearly ubiquitous GTPase that localizes in a ring at the leading edge of constricting plasma membranes during cell division. Here we report electron cryotomographic reconstructions of dividing Caulobacter crescentus cells wherein individual arc-like filaments were resolved just underneath the inner membrane at constriction sites. The filaments' position, orientation, time of appearance, and resistance to A22 all suggested that they were FtsZ. Predictable changes in the number, length, and distribution of filaments in cells where the expression levels and stability of FtsZ were altered supported that conclusion. In contrast to the thick, closed-ring-like structure suggested by fluorescence light microscopy, throughout the constriction process the Z-ring was seen here to consist of just a few short (approximately 100 nm) filaments spaced erratically near the division site. Additional densities connecting filaments to the cell wall, occasional straight segments, and abrupt kinks were also seen. An 'iterative pinching' model is proposed wherein FtsZ itself generates the force that constricts the membrane in a GTP-hydrolysis-driven cycle of polymerization, membrane attachment, conformational change, depolymerization, and nucleotide exchange.     

Cell Division in Escherichia coli: Analysis of Double Mutants for Filamentation and Abnormal Septation of Deoxyribonucleic Acid-Less Cells

The link between chromosome termination, initiation of cell division, and choice of division sites was studied in Escherichia coli by preparing double mutants. Hybrid mutants containing div52-ts, a cell division initiation mutation, and min, mutations which affect the choice of division sites resulting in the septation of minicells, were characterized. The mutants produced minicells and normal cells coordinately under all conditions studied, although the fraction of minicells is half that of the parental minicell strain. The mutant gradually stopped dividing at both the median and minicell septation sites when transferred from 30 to 41 C in rich medium. A synchronous cell division of filaments was induced 15 min after addition of chloramphenicol to the medium, even at 41 C. Divisions were observed at both normal and minicell sites. These results indicate that div52-ts and min functions share a common step in a cell division pathway. A double mutant containing div52-ts and div27-ts, a dnaB mutant which divides in the absence of DNA synthesis, was characterized. The mutant continues to divide after a shift to the high temperature, although at a reduced rate. The behavior of this hybrid mutant suggests a hypothesis that the chromosome termination signal and div52-ts division initiation signal act on a single membrane site which is altered in div27-ts strains.     

Ultrastructural localization of anionic sites on the surface of yeast, hyphal and germ-tube forming cells of Candida albicans

The cell wall of Candida albicans contains chitin, beta-glucans and phosphorylated mannoproteins, and possesses a fuzzy coat which is thought to play a role in pathogenicity, phagocytosis, and adherence of this dimorphic yeast. Using scanning electron microscopy and the gold method, mannoproteins were detected on the whole surface of blastoconidia including the bud scars, but chitin was absent even after alpha-mannosidase treatment of the cells. The presence of surface beta-(1----6)glucan (but not beta(1----3)glucan) was observed only after extensive alpha-mannosidase and alkaline phosphatase treatments of blastoconidia. Using transmission and scanning electron microscopy, the locations of anionic sites were revealed by polycationic colloidal gold-chitosan complexes on the surface of blastoconidia, germ tubes and hyphae. Anionic sites were dispersed evenly over the surface of blastoconidia bearing bud scars. Depending upon the growth conditions, anionic sites could be detected on emerging buds and young cells. However, bud scars were always free of marking. When germ-tube formation was induced, anionic sites were present at different densities on all cell surfaces, the highest density being observed on cells with bud scars. Anionic sites were detected at a remarkably high density on all hyphal surfaces. An apical concentration of anionic sites was observed on germ tubes and hyphae. The distribution of anionic sites was not modified by endoglucosaminidase treatment of blastoconidia, germ tubes and hyphae. The anionic sites were associated with the fuzzy coat. As the hyphal form is regarded as possessing the greatest invasiveness, it is suggested that anionic sites play an important role in establishing tissue colonization by this human pathogen.     

Requirement of topoisomerase IV parC and parE genes for cell cycle progression and developmental regulation in Caulobacter crescentus

We have identified the parC and parE genes encoding DNA topoisomerase IV (Topo IV) in Caulobacter crescentus . We have also characterized the effect of conditional Topo IV mutations on cell division and morphology. Topo IV mutants of C. crescentus are unlike mutants of Escherichia coli and S. typhimurium , which form long filamentous cells that are defective in nucleoid segregation and divide frequently to produce anucleate cells. Topo IV mutants of C. crescentus are highly pinched at multiple sites (cell separation phenotype) and they do not divide to produce cells lacking DNA. These results suggest unique regulatory mechanisms coupling nucleoid partitioning and cell division in this aquatic bacterium. In addition, distinctive nucleoid-partitioning defects are not apparent in C. crescentus Topo IV mutants as they are in E. coli and S. typhimurium . However, abnormal nucleoid segregation in parE mutant cells could be demonstrated in a genetic background containing a conditional mutation in the C. crescentus ftsA gene, an early cell division gene that is epistatic to parE for cell division and growth. We discuss these results in connection with the possible roles of C. crescentus Topo IV in the regulation of cell division, chromosome partitioning, and late events in polar morphogenesis. Although the ParC and ParE subunits of Topo IV are very similar in sequence to the GyrA and GyrB subunits of DNA gyrase, we have used DNA sequence analysis to identify a highly conserved 'GyrA box' sequence that is unique to the GyrA proteins and may serve as a hallmark of the GyrA protein family.     

Role of Bud3p in producing the axial budding pattern of yeast

Yeast cells can select bud sites in either of two distinct spatial patterns. a cells and alpha cells typically bud in an axial pattern, in which both mother and daughter cells form new buds adjacent to the preceding division site. In contrast, a/alpha cells typically bud in a bipolar pattern, in which new buds can form at either pole of the cell. The BUD3 gene is specifically required for the axial pattern of budding: mutations of BUD3 (including a deletion) affect the axial pattern but not the bipolar pattern. The sequence of BUD3 predicts a product (Bud3p) of 1635 amino acids with no strong or instructive similarities to previously known proteins. However, immunofluorescence localization of Bud3p has revealed that it assembles in an apparent double ring encircling the mother-bud neck shortly after the mitotic spindle forms. The Bud3p structure at the neck persists until cytokinesis, when it splits to yield a single ring of Bud3p marking the division site on each of the two progeny cells. These single rings remain for much of the ensuing unbudded phase and then disassemble. The Bud3p rings are indistinguishable from those of the neck filament- associated proteins (Cdc3p, Cdc10p, Cdc11p, and Cdc12p), except that the latter proteins assemble before bud emergence and remain in place for the duration of the cell cycle. Upon shift of a temperature- sensitive cdc12 mutant to restrictive temperature, localization of both Bud3p and the neck filament-associated proteins is rapidly lost. In addition, a haploid cdc11 mutant loses its axial-budding pattern upon shift to restrictive temperature. Taken together, the data suggest that Bud3p and the neck filaments are linked in a cycle in which each controls the position of the other's assembly: Bud3p assembles onto the neck filaments in one cell cycle to mark the site for axial budding (including assembly of the new ring of neck filaments) in the next cell cycle. As the expression and localization of Bud3p are similar in a, alpha, and a/alpha cells, additional regulation must exist such that Bud3p restricts the position of bud formation in a and alpha cells but not in a/alpha cells.     

Septum Formation in Escherichia coli: Characterization of Septal Structure and the Effects of Antibiotics on Cell Division

Septa can be demonstrated in sections of Escherichia coli strains B and B/r after fixation with acrolein and glutaraldehyde. The septum consists of an ingrowth of the cytoplasmic membrane and the mucopeptide layer; the outer membrane is excluded from the septum until the cells begin to separate. Mesosomes have also been observed. The septum is highly labile and, except in the chain-forming strains, E. coli D22 env A and CRT 97, not easily preserved by standard procedures. The labile nature of the septum may be due to the presence of autolysin(s) located at the presumptive division site. Blocking division by addition of ampicillin (2 to 5 mug/ml) to cells of E. coli B/r produces a bulge at the middle of the cells; bulge formation is stopped by addition of chloramphenicol. Cephalosporins also induce bulge formation but may stop cell elongation as well as division. Bulge formation, due to the presumed action of an autolysin(s), may be an initial step in the septation sequence when the mucopeptide is modified to allow construction of the septum. In a nonseptate filament-forming strain, PAT 84, which ceases to divide at 42 C, bulge formation only occurs in the presence of ampicillin at the time of a shift-down at 30 C or at 42 C in the presence of NaCl (0.25 to 0.34 M). Experiments with chloramphenicol suggest that the filaments are fully compartmentalized but fail to divide owing to the inactivation, rather than loss of synthesis, of an autolysin at 42 C.     

Regulation of cell cycle events in asymmetrically dividing cells: functions required for DNA initiation and chain elongation in Caulobacter crescentus

To study the regulation of cell cycle events after asymmetric cell division in Caulobacter crescentus, we have identified functions that are required for DNA synthesis in the stalked cell produced at division and in the new stalked cell that develops from the swarmer cell 60 min after division. The initiation of DNA synthesis in the two progeny cells is dependent upon at least two common functions. One of these is a requirement for protein synthesis and the other is a gene product identified in a temperature-sensitive cell cycle mutant. DNA chain elongation requires a third common function. The characteristic pattern of DNA synthesis in C. crescentus appears to be controlled in part by the expression of these functions in the two stalked cells at different times after cell division. The age distribution for Caulobacter cells in an exponential population has been calculated (Appendix by Robert Tax) and used to analyze some of the results.