Structure and expression of the cell division genes ftsQ, ftsA and ftsZ

Gene-Directed FtsZ Ring Assembly Generates Constricted Liposomes with Stable Membrane Necks

Mimicking bacterial cell division in well-defined cell-free systems has the potential to elucidate the minimal set of proteins required for cytoskeletal formation, membrane constriction, and final abscission. Membrane-anchored FtsZ polymers are often regarded as a sufficient system to realize this chain of events. By using purified FtsZ and its membrane-binding protein FtsA or the gain-of-function mutant FtsA* expressed in PURE (Protein synthesis Using Reconstituted Elements) from a DNA template, it is shown in this study that cytoskeletal structures are formed, and yield constricted liposomes exhibiting various morphologies. However, the resulting buds remain attached to the parental liposome by a narrow membrane neck. No division events can be monitored even after long-time tracking by fluorescence microscopy, nor when the osmolarity of the external solution is increased. The results provide evidence that reconstituted FtsA-FtsZ proto-rings coating the membrane necks are too stable to enable abscission. The prospect of combining a DNA-encoded FtsZ system with assisting mechanisms to achieve synthetic cell division is discussed.

Cell division in Corynebacterineae

Bacterial cells must coordinate a number of events during the cell cycle. Spatio-temporal regulation of bacterial cytokinesis is indispensable for the production of viable, genetically identical offspring. In many rod-shaped bacteria, precise midcell assembly of the division machinery relies on inhibitory systems such as Min and Noc. In rod-shaped Actinobacteria, for example Corynebacterium glutamicum and Mycobacterium tuberculosis, the divisome assembles in the proximity of the midcell region, however more spatial flexibility is observed compared to Escherichia coli and Bacillus subtilis. Actinobacteria represent a group of bacteria that spatially regulate cytokinesis in the absence of recognizable Min and Noc homologs. The key cell division steps in E. coli and B. subtilis have been subject to intensive study and are well-understood. In comparison, only a minimal set of positive and negative regulators of cytokinesis are known in Actinobacteria. Nonetheless, the timing of cytokinesis and the placement of the division septum is coordinated with growth as well as initiation of chromosome replication and segregation. We summarize here the current knowledge on cytokinesis and division site selection in the Actinobacteria suborder Corynebacterineae.

Asymmetric constriction of dividing Escherichia coli cells induced by expression of a fusion between two min proteins

The Min system, consisting of MinC, MinD, and MinE, plays an important role in localizing the Escherichia coli cell division machinery to midcell by preventing FtsZ ring (Z ring) formation at cell poles. MinC has two domains, MinCn and MinCc, which both bind to FtsZ and act synergistically to inhibit FtsZ polymerization. Binary fission of E. coli usually proceeds symmetrically, with daughter cells at roughly 180° to each other. In contrast, we discovered that overproduction of an artificial MinCc-MinD fusion protein in the absence of other Min proteins induced frequent and dramatic jackknife-like bending of cells at division septa, with cell constriction predominantly on the outside of the bend. Mutations in the fusion known to disrupt MinCc-FtsZ, MinCc-MinD, or MinD-membrane interactions largely suppressed bending division. Imaging of FtsZ-green fluorescent protein (GFP) showed no obvious asymmetric localization of FtsZ during MinCc-MinD overproduction, suggesting that a downstream activity of the Z ring was inhibited asymmetrically. Consistent with this, MinCc-MinD fusions localized predominantly to segments of the Z ring at the inside of developing cell bends, while FtsA (but not ZipA) tended to localize to the outside. As FtsA is required for ring constriction, we propose that this asymmetric localization pattern blocks constriction of the inside of the septal ring while permitting continued constriction of the outside portion.

Essential biological processes of an emerging pathogen: DNA replication, transcription, and cell division in Acinetobacter spp

Within the last 15 years, members of the bacterial genus Acinetobacter have risen from relative obscurity to be among the most important sources of hospital-acquired infections. The driving force for this has been the remarkable ability of these organisms to acquire antibiotic resistance determinants, with some strains now showing resistance to every antibiotic in clinical use. There is an urgent need for new antibacterial compounds to combat the threat imposed by Acinetobacter spp. and other intractable bacterial pathogens. The essential processes of chromosomal DNA replication, transcription, and cell division are attractive targets for the rational design of antimicrobial drugs. The goal of this review is to examine the wealth of genome sequence and gene knockout data now available for Acinetobacter spp., highlighting those aspects of essential systems that are most suitable as drug targets. Acinetobacter spp. show several key differences from other pathogenic gammaproteobacteria, particularly in global stress response pathways. The involvement of these pathways in short- and long-term antibiotic survival suggests that Acinetobacter spp. cope with antibiotic-induced stress differently from other microorganisms.

The bacterium endosymbiont of Crithidia deanei undergoes coordinated division with the host cell nucleus

In trypanosomatids, cell division involves morphological changes and requires coordinated replication and segregation of the nucleus, kinetoplast and flagellum. In endosymbiont-containing trypanosomatids, like Crithidia deanei, this process is more complex, as each daughter cell contains only a single symbiotic bacterium, indicating that the prokaryote must replicate synchronically with the host protozoan. In this study, we used light and electron microscopy combined with three-dimensional reconstruction approaches to observe the endosymbiont shape and division during C. deanei cell cycle. We found that the bacterium replicates before the basal body and kinetoplast segregations and that the nucleus is the last organelle to divide, before cytokinesis. In addition, the endosymbiont is usually found close to the host cell nucleus, presenting different shapes during the protozoan cell cycle. Considering that the endosymbiosis in trypanosomatids is a mutualistic relationship, which resembles organelle acquisition during evolution, these findings establish an excellent model for the understanding of mechanisms related with the establishment of organelles in eukaryotic cells.

A homologue of the Drosophila female sterile homeotic (fsh) gene in the class II region of the human MHC

The RING3 gene maps in the class II region of the human major histocompatibility complex, at a CpG island distal of the HLA-DNA gene. RING3 cDNAs were obtained from a T cell cDNA library and the longest (4 kb) was sequenced. The sequence contained an open reading frame encoding a protein of 754 amino acids. A screen of protein databases revealed striking homology between the RING3 protein and the Drosophila female sterile homeotic gene (fsh) which is implicated in the establishment of segments in the early embryo. Partial sequence homology was also observed with some other proteins involved in cell cycle control (CCG1), cell division (ftsA) and regulation of cell growth (gamma interferons). This highly conserved gene may play an important role in human development. In addition, its location in the MHC class II region may be related to some HLA-associated diseases.

Bacterial cell division protein FtsZ is stable against degradation by AAA family protease FtsH in Escherichia coli cells

We have found that FtsH protease of Escherichia coli could degrade E. coli cell division protein FtsZ in an ATP- and Zn(2+)-dependent manner in vitro and that the degradation did not show specificity for the N-terminus or C-terminus of FtsZ, like in the case of degradation of its conventional substrate sigma(32) protein. In continuation of these observations, in the present study, we examined whether FtsH would affect the stability and turnover of FtsZ in vivo. We found that FtsZ levels were not elevated in E. coli AR754 (ftsH1 ts) cells at nonpermissive temperature as compared to the levels in an FtsH-active isogenic AR753 strain. Neither did FtsH degrade ectopically expressed FtsZ in AR754 strain nor did ectopic expression of FtsH reduced FtsZ levels in E. coli AR5090 ftsH null strain (ftsH::kan, sfhC21). Pulse chase experiments in AR754 and AR5090 strains showed that there were no compensatory changes in FtsZ turnover, in case FtsZ degradation had occurred. Even under cell division arrested conditions, wherein FtsZ was not required, FtsH protease did not degrade unutilized FtsZ. These experiments demonstrate that either FtsH protease may not have a role in regulating the levels of FtsZ in vivo under the conditions tested or that some cellular component(s) might be stabilising FtsZ against FtsH protease.

The Microtubule Analog Protein, FtsZ, in the Endosymbiont of Trypanosomatid Protozoa

Blastocrithidia culicis and Crithidia deanei are trypanosomatids that harbor an endosymbiotic bacterium in their cytoplasm. In prokaryotes, numerous proteins are essential for cell division, such as FtsZ, which is encoded by filament-forming temperature-sensitive (fts) genes. FtsZ is the prokaryotic homolog of eukaryotic tubulin and is present in bacteria and archaea, and has also been identified in mitochondria and chloroplasts. FtsZ plays a key role in the initiation of cytokinesis. It self-assembles into the Z ring, which establishes the division plane during septation. In this study, immunoblotting analysis using a FtsZ polyclonal antibody, revealed a 40-kDa band characteristic of FtsZ in endosymbiont fractions and in whole trypanosomatid homogenates, but not in whole cell extracts of aposymbiotic strains. Confocal microscopy and ultrastructural analysis revealed a specific and dispersed labeling over the endosymbiont. Bars and ring-like structures, which are suggestive of the presence of Z-rings, were never observed, even during the division of the symbiont. This peculiar distribution of FtsZ may represent an arrangement of cytoskeleton protein intermediate between prokaryotic and eukaryotic cells. The endosymbiont ftsz gene was completely sequenced after amplification of DNA from symbiont-bearing trypanosomatids or from pure endosymbiont fractions, using PCR and specific primers. The sequences obtained from the endosymbionts from C. deanei and B. culicis were very similar, and were most closely related to bacteria from the genus Pseudomonas.

Identification and Characterization of theDdlB,FtsQandFtsAGenes Upstream ofFtsZinBartonella bacilliformisandBartonella henselae

Homologues of the cell division protein FtsZ were previously identified in Bartonella bacilliformis and Bartonella henselae. We report herein that ftsZ is located at the distal end of an operon that includes ddlB, ftsQ, and ftsA. These genes code for homologues of D-alanine D-alanine ligase, an enzyme involved in cell wall biosynthesis, and FtsQ, and FtsA, which are involved in cell division. The DdlB, FtsQ, and FtsA proteins from Bartonella species are most homologous to proteins in closely related species from the Order Rhizobiales, such as Brucella sp., Agrobacterium tumefaciens, and M. loti. The organization of the genes within the ddlB-ftsZ operon of B. bacilliformis and B. henselae (5'ddlB-ftsQ-ftsA-ftsZ 3') is similar to that of Mesorhizobium loti and Escherichia coli. We report the localization of three promoter regions within the ddlB-ftsA sequence of B. bacilliformis that may enhance the transcription of ftsZ mRNA. A promoter region was also identified upstream of the ddlB gene.

Characterization of the ftsZ gene from Ehrlichia chaffeensis, Anaplasma phagocytophilum, and Rickettsia rickettsii, and use as a differential PCR target

Degenerate primers corresponding to highly conserved regions of previously characterized ftsZ genes were used to PCR amplify a portion of the ftsZ gene from the genomic DNA of Ehrlichia chaffeensis (ftsZ(Ech)), Anaplasma phagocytophilum (ftsZ(Ap)), and Rickettsia rickettsii (ftsZ(Rr)). Genome walking was then used to amplify the 5' and 3' termini of the genes. The DNA sequences of the resulting amplification products yielded open reading frames coding for proteins with molecular masses of 42.0, 45.7, and 48.3 kDa for A. phagocytophilum, E. chaffeensis, and R. rickettsii, respectively. These homologs are 20 to 70 amino acids longer than the FtsZ proteins characterized in bacteria such as Escherichia coli and Bacillus subtilis, but do not possess the large extended carboxyl-termini found in the FtsZ proteins of Bartonella, Rhizobium, and Agrobacterium species. The functional domains important for FtsZ activity are conserved within the ehrlichial and rickettsial FtsZ protein sequences. The R. rickettsii FtsZ sequence is highly homologous to the FtsZ protein previously described for Rickettsia prowazekii (89% identity), and identical to the FtsZ protein of Rickettsia conorii. The percent identity observed between the A. phagocytophilum and E. chaffeensis FtsZ proteins is only 79% and is particularly low in the carboxyl-terminal region (15.8% identity). Primers were designed to PCR amplify a portion of the variable carboxyl-terminal region of the ftsZ gene, and used to differentiate each agent based on the size of the amplicons: A. phagocytophilum, 278 bp; E. chaffeensis, 341 bp; and Rickettsia spp., 425 bp.

Selected amplification of the cell division genes ftsQ-ftsA-ftsZ in Escherichia coli

Rapidly growing Escherichia coli is unable to divide in the presence of the antibiotic mecillinam, whose direct target is penicillin-binding protein 2 (PBP2), responsible for the elongation of the cylindrical portion of the cell wall. Division can be restored in the absence of PBP2 activity by increasing the concentration of the cell division proteins FtsQ, FtsA, and FtsZ. We tried to identify regulators of the ftsQ-ftsA-ftsZ operon among mecillinam-resistant mutants, which include strains overexpressing these genes. By insertional mutagenesis with mini-Tn10 elements, we selected for insertions that conferred mecillinam resistance. Among 15 such mutants, 7 suppressed the thermosensitivity of the ftsZ84(Ts) mutant, strongly suggesting that they had increased FtsZ activity. In all 7 cases, however, the mutants resulted from a duplication of the ftsQAZ region. These duplications seemed to result from multiple events, suggesting that no simple insertional inactivation can result in a mutant with sufficiently amplified ftsQAZ expression to confer mecillinam resistance. The structure of the duplications suggests a general method for constructing directed duplications of precise sequences.

Control of division gene expression in Escherichia coli

Duplication of the Escherichia coli bacterial cell culminates in the formation of a division septum that splits the progenitor cell into two identical daughter cells. Invagination of the cell envelope is brought about by the co-ordinated interplay of a family of septation-specific proteins that act locally at mid-cell at a specific time in the cell cycle. The majority of the genes known to be required for septum formation are found within the large mra cluster located at 2 min on the E. coli genetic map (nucleotides 89552-107474). Examination of the controls exerted on the mra operon shows that E. coli uses an extraordinary range of strategies to co-ordinate the expression of the cell division genes with respect to each other and to the cell cycle.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Roles of FtsA and FtsZ in activation of division sites

Increasing FtsZ induces the formation of minicells at cell poles but does not increase the frequency or timing of central divisions. A coordinate increase in both FtsZ and FtsA, however, increases the frequency of both polar and central divisions.

Interactions between heterologous FtsA and FtsZ proteins at the FtsZ ring

FtsZ and FtsA are essential for cell division in Escherichia coli and colocalize to the septal ring. One approach to determine what regions of FtsA and FtsZ are important for their interaction is to identify in vivo interactions between FtsA and FtsZ from different species. As a first step, the ftsA genes of Rhizobium meliloti and Agrobacterium tumefaciens were isolated and characterized. In addition, an FtsZ homolog that shared the unusual C-terminal extension of R. meliloti FtsZ1 was found in A. tumefaciens. In order to visualize their localization in cells, we tagged these proteins with green fluorescent protein (GFP). When R. meliloti FtsZ1-GFP or A. tumefaciens FtsZ-GFP was expressed at low levels in E. coli, they specifically localized only to the E. coli FtsZ ring, possibly by coassembly. When A. tumefaciens FtsA-GFP or R. meliloti FtsA-GFP was expressed in E. coli, they failed to localize detectably to the E. coli FtsZ ring. However, when R. meliloti FtsZ1 was coexpressed with them, fluorescence localized to a band at the midcell division site, strongly suggesting that FtsA from either A. tumefaciens or R. meliloti can bind directly to its cognate FtsZ. As expected, GFP-tagged FtsZ1 and FtsA from either R. meliloti or A. tumefaciens localized to the division site in A. tumefaciens cells. Therefore, the 61 amino acid changes between A. tumefaciens FtsA and R. meliloti FtsA do not prevent their direct interaction with FtsZ1 from either species, suggesting that those residues are not essential for protein-protein contacts. Moreover, the failure of the two non-E. coli FtsA derivatives to interact strongly with E. coli FtsZ in this in vivo system unless their cognate FtsZ was also present suggests that FtsA-FtsZ interactions have coevolved and that the residues which differ between the E. coli proteins and those of the two other species may be important for specific interactions.

A promoter for the first nine genes of the Escherichia coli mra cluster of cell division and cell envelope biosynthesis genes, including ftsI and ftsW

We constructed a null allele of the ftsI gene encoding penicillin-binding protein 3 of Escherichia coli. It caused blockage of septation and loss of viability when expression of an extrachromosomal copy of ftsI was repressed, providing a final proof that ftsI is an essential cell division gene. In order to complement this null allele, the ftsI gene cloned on a single-copy mini-F plasmid required a region 1.9 kb upstream, which was found to contain a promoter sequence that could direct expression of a promoterless lacZ gene on a mini-F plasmid. This promoter sequence lies at the beginning of the mra cluster in the 2 min region of the E. coli chromosome, a cluster of 16 genes which, except for the first 2, are known to be involved in cell division and cell envelope biosynthesis. Disruption of this promoter, named the mra promoter, on the chromosome by inserting the lac promoter led to cell lysis in the absence of a lac inducer. The defect was complemented by a plasmid carrying a chromosomal fragment ranging from the mra promoter to ftsW, the fifth gene downstream of ftsI, but not by a plasmid lacking ftsW. Although several potential promoter sequences in this region of the mra cluster have been reported, we conclude that the promoter identified in this study is required for the first nine genes of the cluster to be fully expressed.

Identification, characterization, and chromosomal organization of cell division cycle genes in Caulobacter crescentus

We report a detailed characterization of cell division cycle (cdc) genes in the differentiating gram-negative bacterium Caulobacter crescentus. A large set of temperature-sensitive cdc mutations was isolated after treatment with the chemical mutagen N-methyl-N'-nitro-N-nitrosoguanidine. Analysis of independently isolated mutants at the nonpermissive temperature identified a variety of well-defined terminal phenotypes, including long filamentous cells blocked at various stages of the cell division cycle and two unusual classes of mutants with defects in both cell growth and division. The latter strains are uniformly arrested as either short bagel-shaped coils or large predivisional cells. The polar morphology of these cdc mutants supports the hypothesis that normal cell cycle progression is directly responsible for developmental regulation in C. crescentus. Genetic and physical mapping of the conditional cdc mutations and the previously characterized dna and div mutations identified at least 21 genes that are required for normal cell cycle progression. Although most of these genes are widely scattered, the genetically linked divA, divB, and divE genes were shown by genetic complementation and physical mapping to be organized in one gene cluster at 3200 units on the chromosome. DNA sequence analysis and marker rescue experiments demonstrated that divE is the C. crescentus ftsA homolog and that the ftsZ gene maps immediately adjacent to ftsA. On the basis of these results, we suggest that the C. crescentus divA-divB-divE(ftsA)-ftsZ gene cluster corresponds to the 2-min fts gene cluster of Escherichia coli.

RNase E processing of essential cell division genes mRNA in Escherichia coli

The ratio of the FtsZ to FtsA proteins determines the correct initiation of cell division in Escherichia coli. The genes for these proteins are contiguous on the chromosome. Although both genes are transcribed from common promoters, the presence of ftsZ-specific promoters, along with differences in the efficiency of translation of their respective mRNAs, contribute to the increased relative expression of ftsZ. We report here that the polycistronic ftsA-ftsZ transcripts are cleaved by RNase E and that this cleavage affects the decay of ftsA and ftsZ mRNA. As a consequence of the cleavage, RNase E also contributes to the differential expression of the two genes.

Isolation of an ftsZ homolog from the archaebacterium Halobacterium salinarium: implications for the evolution of FtsZ and tubulin

We have isolated a homolog of the cell division gene ftsZ from the extremely halophilic archaebacterium Halobacterium salinarium. The predicted protein of 39 kDa is divergent relative to eubacterial homologs, with 32% identity to Escherichia coli FtsZ. No other eubacterial cell division gene homologs were found adjacent to H. salinarium ftsZ. Expression of the ftsZ gene region in H. salinarium induced significant morphological changes leading to the loss of rod shape. Phylogenetic analysis demonstrated that the H. salinarium FtsZ protein is more related to tubulins than are the FtsZ proteins of eubacteria, supporting the hypothesis that FtsZ may have evolved into eukaryotic tubulin.

Characterization of genes required for pilus expression in Pseudomonas syringae pathovar phaseolicola

Nonpiliated, phage phi 6-resistant mutants of Pseudomonas syringae pv. phaseolicola were generated by Tn5 transposon mutagenesis. A P. syringae pv. phaseolicola LR700 cosmid library was screened with Tn5-containing EcoRI fragments cloned from nonpiliated mutants. The cosmid clone pVK253 complemented the nonpiliated mutant strain HB2.5. A 3.8-kb sequenced region spanning the Tn5 insertion site contained four open reading frames. The transposon-inactivated gene, designated pilP, is 525 bp long, potentially encoding a 19.1-kDa protein precursor that contains a typical membrane lipoprotein leader sequence. Generation of single mutations in each of the three remaining complete open reading frames by marker exchange also resulted in a nonpiliated phenotype. Expression of this gene region by the T7 expression system in Escherichia coli resulted in four polypeptides of approximately 39, 26, 23, and 18 kDa, in agreement with the sizes of the open reading frames. The three genes upstream of pilP were designated pilM (39 kDa), pilN (23 kDa), and pilO (26 kDa). The processing of the PilP precursor into its mature form was shown to be inhibited by globomycin, a specific inhibitor of signal peptidase II. The gene region identified shows a high degree of homology to a gene region reported to be required for Pseudomonas aeruginosa type IV pilus production.

Relationship between ftsZ gene expression and chromosome replication in Escherichia coli

Transcriptional levels within the ftsQAZ region of the Escherichia coli chromosome were correlated with chromosome replication and the division cycle. The transcripts were measured either in synchronous cultures generated by the baby machine technique or in dnaC2(Ts) mutants that had been aligned for initiation of chromosome replication by temperature shifts. Transcription within the ftsZ reading frame was found to fluctuate during the cell cycle, with maximal levels about midcycle and a minimum level at division, in cells growing with a doubling time of 24 min at 37 degrees C. Examination of transcription in dnaC(Ts) mutants aligned for chromosome replication indicated that the periodicity was due to a reduction in transcripts coincident with replication of the ftsQAZ region. Transcription originating upstream of the ftsA gene exhibited the periodicity and accounted for a significant proportion of the transcripts entering ftsZ. The most obvious interpretation of the data is that replication of the region transiently inhibits transcription, but alternative explanations have not been ruled out. However, no other relationship between transcription and either replication or division was detected.

Rhizobium meliloti contains a novel second homolog of the cell division gene ftsZ

We have identified a second homolog of the cell division gene, ftsZ, in the endosymbiont Rhizobium meliloti. The ftsZ2 gene was cloned by screening a genomic lambda library with a probe derived from PCR amplification of a highly conserved domain. It encodes a 36-kDa protein which shares a high level of sequence similarity with the FtsZ proteins of Escherichia coli and Bacillus subtilis and FtsZ1 (Z1) of R. meliloti but lacks the carboxy-terminal region conserved in other FtsZ proteins. The identity of the ftsZ2 gene product was confirmed both by in vitro transcription-translation in an R. meliloti S-30 extract and by overproduction in R. meliloti cells. As with Z1, the overproduction of FtsZ2 in E. coli inhibited cell division and induced filamentation, although to a lesser extent than with Z1. However, the expression of ftsZ2 in E. coli under certain conditions caused some cells to coil dramatically, a phenotype not observed during Z1 overproduction. Although several Tn3-GUS (glucuronidase) insertions in a plasmid-borne ftsZ2 gene failed to cross into the chromosome, one interruption in the chromosomal ftsZ2 gene was isolated, suggesting that ftsZ2 is nonessential for viability. The two ftsZ genes were genetically mapped to the R. meliloti main chromosome, approximately 100 kb apart.

Penicillin-binding protein 2 inactivation in Escherichia coli results in cell division inhibition, which is relieved by FtsZ overexpression

Aminoacyl-tRNA synthetase mutants of Escherichia coli are resistant to amdinocillin (mecillinam), a beta-lactam antibiotic which specifically binds penicillin-binding protein 2 (PBP2) and prevents cell wall elongation with concomitant cell death. The leuS(Ts) strain, in which leucyl-tRNA synthetase is temperature sensitive, was resistant to amdinocillin at 37 degrees C because of an increased guanosine 5'-diphosphate 3'-diphosphate (ppGpp) pool resulting from partial induction of the stringent response, but it was sensitive to amdinocillin at 25 degrees C. We constructed a leuS(Ts) delta (rodA-pbpA)::Kmr strain, in which the PBP2 structural gene is deleted. This strain grew as spherical cells at 37 degrees C but was not viable at 25 degrees C. After a shift from 37 to 25 degrees C, the ppGpp pool decreased and cell division was inhibited; the cells slowly carried out a single division, increased considerably in volume, and gradually lost viability. The cell division inhibition was reversible when the ppGpp pool increased at high temperature, but reversion required de novo protein synthesis, possibly of septation proteins. The multicopy plasmid pZAQ, overproducing the septation proteins FtsZ, FtsA, and FtsQ, conferred amdinocillin resistance on a wild-type strain and suppressed the cell division inhibition in the leuS(Ts) delta (rodA-pbpA)::Kmr strain at 25 degrees C. The plasmid pAQ, in which the ftsZ gene is inactivated, did not confer amdinocillin resistance. These results lead us to hypothesize that the nucleotide ppGpp activates ftsZ expression and thus couples cell division to protein synthesis.

Cloning and characterization of ftsN, an essential cell division gene in Escherichia coli isolated as a multicopy suppressor of ftsA12(Ts)

A new cell division gene, ftsN, was identified in Escherichia coli as a multicopy suppressor of the ftsA12(Ts) mutation. Remarkably, multicopy ftsN suppressed ftsI23(Ts) and to a lesser extent ftsQ1(Ts); however, no suppression of the ftsZ84(Ts) mutation was observed. The suppression of ftsA12(Ts), ftsI23(Ts), and ftsQ1(Ts) suggests that FtsN may interact with these gene products during cell division. The ftsN gene was located at 88.5 min on the E. coli genetic map just downstream of the cytR gene. ftsN was essential for cell division, since expression of a conditional null allele led to filamentation and cell death. DNA sequence analysis of the ftsN gene revealed an open reading frame of 319 codons which would encode a protein of 35,725 Da. The predicted gene product had a hydrophobic sequence near its amino terminus similar to the noncleavable signal sequences found in several other Fts proteins. The presumed extracellular domain was unusual in that it was rich in glutamine residues. A 36-kDa protein that was localized to the membrane fraction was detected in minicells containing plasmids with the ftsN gene, confirming that FtsN was a membrane protein.

Cell division and transcription of ftsZ

For normal cell division, the ftsZ gene must be transcribed from a number of promoters that are located within the proximal upstream genes (ddlB, ftsQ, and ftsA). We show that the main promoters have identical responses to changes in growth rate, i.e., under all conditions, the frequency of transcription per septum formed is approximately constant and independent of cell size or growth rate per se. We also show that transcription from these promoters is independent of stationary-phase transcription factor sigma s.

Two developmentally controlled promoters of Streptomyces coelicolor A3(2) that resemble the major class of motility-related promoters in other bacteria

Experiments were designed to allow isolation of Streptomyces coelicolor promoters that depend on the whiG sporulation gene, which encodes a putative sigma factor important in the sporulation of aerial hyphae. The strategy, based on earlier evidence that sigma WhiG is limiting for sporulation (K. F. Chater, C. J. Burton, K. A. Plaskitt, M. J. Buttner, C. Méndez, and J. Helmann, Cell 59:133-143, 1989) was to seek DNA fragments that inhibit sporulation in aerial hyphae when present at a high copy number. In a suitable Sau3AI-generated library of DNA from S. coelicolor A3(2), two inserts were found to inhibit sporulation. Both inserts caused expression of the adjacent xylE reporter gene present in the vector in a developmentally normal strain of S. coelicolor, but there was no xylE expression in an otherwise isogenic whiG mutant. S1 nuclease protection experiments were done with RNAs isolated from these plasmid-bearing strains or from the wild-type strain lacking either recombinant plasmid. In each case, an apparent transcription start site was found upstream of an apparent open reading frame (ORF) and just downstream of sequences that resemble consensus features of promoters for motility-related genes in Bacillus subtilis and coliform bacteria. Such promoters depend on sigma factors (sigma D and sigma F, respectively) particularly similar to the deduced whiG gene product. Each of the putative whiG-dependent promoters is within an ORF that is upstream of, and potentially translationally coupled to, the putative whiG-dependent ORF (although use of one of the promoters would necessitate the use of a different start codon, further downstream). Thus, in unknown circumstances, the whiG-dependent ORFs may be expressed from a more remote promoter as part of a complex transcription unit.

Escherichia coli cell division protein FtsZ is a guanine nucleotide binding protein

FtsZ is an essential cell division protein in Escherichia coli that forms a ring structure at the division site under cell cycle control. The dynamic nature of the FtsZ ring suggests possible similarities to eukaryotic filament forming proteins such as tubulin. In this study we have determined that FtsZ is a GTP/GDP binding protein with GTPase activity. A short segment of FtsZ is homologous to a segment in tubulin believed to be involved in the interaction between tubulin and guanine nucleotides. A lethal ftsZ mutation, ftsZ3 (Rsa), that leads to an amino acid alteration in this homologous segment decreased GTP binding and hydrolysis, suggesting that interaction with GTP is essential for ftsZ function.

Identification, cloning, and characterization of rcsF, a new regulator gene for exopolysaccharide synthesis that suppresses the division mutation ftsZ84 in Escherichia coli K-12

A new gene, designated rcsF, was located adjacent to drpA at the 5.2-min position of the genetic map of Escherichia coli. The deduced amino acid sequence encoded by the rcsF gene indicates a small protein of 133 amino acid residues with a calculated pI of 10.8 that is rich in proline, serine, alanine, and cysteine residues. When overexpressed as a result of its presence on a multicopy plasmid, rcsF confers a mucoid phenotype and restores colony formation to ftsZ84 mutant cells on L agar medium containing no added NaCl. These two phenotypes are not observed in rcsB mutant cells. Ion mutant cells harboring an rcsF mutation accumulate considerably lower levels of exopolysaccharides, whereas the presence of a multicopy rcsF plasmid not only increases capsule synthesis but also confers a mucoid phenotype at 37 degrees C, a temperature at which ion mutant cells are known not to form mucoid colonies. RcsF does not stimulate the expression of rcsB, indicating that it exerts its action through the RcsB protein, possibly by phosphorylation. It is also shown that RcsF stimulation of capsule synthesis is RcsA-dependent, whereas colony formation of ftsZ84 mutant cells can be restored by RcsF in the absence of RcsA.

The proper ratio of FtsZ to FtsA is required for cell division to occur in Escherichia coli

Interactions among cell division genes in Escherichia coli were investigated by examining the effect on cell division of increasing the expression of the ftsZ, ftsA, or ftsQ genes. We determined that cell division was quite sensitive to the levels of FtsZ and FtsA but much less so to FtsQ. Inhibition of cell division due to an increase in FtsZ could be suppressed by an increase in FtsA. Inhibition of cell division due to increased FtsA could be suppressed by an increase in FtsZ. In addition, although wild-type strains were relatively insensitive to overexpression of ftsQ, we observed that cell division was sensitized to ftsQ overexpression in ftsI, ftsA, and ftsZ mutants. Among these, the ftsI mutant was the most sensitive. These results suggest that these gene products may interact and that the proper ratio of FtsZ to FtsA is critical for cell division to occur.

Inhibition of cell division initiation by an imbalance in the ratio of FtsA to FtsZ

Elevated levels of FtsA protein block cell division at a very early stage, similar to that caused by inhibition of the action of FtsZ. In contrast, overexpression of FtsA and FtsZ together does not block division. A specific ratio of FtsA to FtsZ protein, therefore, is required for cell division.

Quantitative determination of FtsA at different growth rates in Escherichia coli using monoclonal antibodies

FtsA is an essential cell division protein in Escherichia coli. Its synthesis in low amounts makes the investigation of its functions difficult. Partially purified FtsA protein was obtained by solubilizing cellular inclusion bodies after overexpression of the ftsA gene for the purpose of raising monoclonal antibodies. Mice were immunized with this FtsA protein fraction and their spleen cells were fused to Sp2/0-AG14 mouse myeloma cells. Hybrid cells were screened and two clones were positively identified as FtsA monoclonal antibody producers by enzyme-linked immunosorbent assay and Western blotting. A quantitative assay using these monoclonal antibodies indicated that the average number of FtsA molecules per cell to be between 50 and 200. However, the concentration of FtsA protein normalized to total cell protein was constant over a wide range of growth rates. This finding is in agreement with the hypothesized role of FtsA protein as a stoichiometric component of the septum.

C-shaped cells caused by expression of an ftsA mutation in Escherichia coli

A plasmid, pDLL4, was isolated from a Tn5tac1 mutagenesis experiment with plasmid pZAQ. When pDLL4 was transformed into wild-type rod-shaped cells, it caused cells in the population to become curved (C-shaped or convoluted). The Tn5tac1 transposon was integrated within the carboxyl end of the ftsA gene in pDLL4. This mutation was designated ftsAc. Subcloning ftsAc DNA into another plasmid vector verified that the curved-cell phenotype was caused by the expression of this altered gene. DNA sequence analysis of the ftsAc mutation revealed that the transposition event changed the DNA so that the last 28 amino acids of the FtsA protein were lost and 5 new amino acids were added. A radioactive peptide band corresponding to this truncated FtsAc protein was identified by a T7 promoter-T7 polymerase protein labeling system. Observations of thin sections of these curved cells with an electron microscope revealed aggregates of striated cylindrical structures traversing the cytoplasm. The ends of these aggregates appear to be at or near the cell membrane. The linear periodicity of the cylinders was approximately 11 nm, and the diameter of a cylinder was about 15 nm. Aggregates of as many as five cylinders were arrayed diagonally to the long axis of the curved cells, a finding that suggests that some type of internal organization may be causing the curved cell shape.

Regulation of transcription of the cell division gene ftsA during sporulation of Bacillus subtilis

Three distinct 5' ends of ftsA mRNA were identified by S1 mapping and by primer extension analysis. These are thought to represent three transcription start sites. The transcripts from the downstream and upstream sites were detected throughout growth. The transcript from the middle site was not detected during exponential growth but was detected within 30 min of the start of sporulation, when it was the predominant transcript. Insertion of a cat cassette in the middle promoter, ftsAp2 (p2), did not affect vegetative growth but prevented postexponential symmetrical division and spore formation. Transcription from p2 was dependent on RNA polymerase containing sigma H, and promoter p2 resembled the consensus sigma H promoter. Transcription from p2 did not require expression of the spo0A, spo0B, spo0E, spo0F, or spo0K loci. Northern (RNA) blot analysis indicated that ftsA is cotranscribed with the adjacent ftsZ gene. Multiple promoters provide a mechanism by which essential vegetative genes can be subjected to sporulation control independent of control during vegetative growth. In the case of ftsA,Z, the promoters provide a mechanism to permit septum formation in conditions of nutrient depletion that might be expected to shut down the vegetative division machinery.

The rcsB gene, a positive regulator of colanic acid biosynthesis in Escherichia coli, is also an activator of ftsZ expression

Wild-type genes which, when overexpressed, are capable of restoring the growth deficiency of the division mutant ftsZ84 of Escherichia coli on L medium containing no added NaCl have been isolated. One of these genes is rcsB, a positive regulator of colanic acid biosynthesis. A direct relationship between rcsB expression and FtsZ activity was observed, suggesting that RcsB specifically increases transcription of ftsZ, thus accounting for the restoration of colony formation by ftsZ84 mutant cells. Analysis of the 5' upstream sequence of rcsB revealed, in addition to the sigma 54 promoter sequence previously reported, a presumptive sigma 70 promoter and LexA-binding site plus an upstream sequence that is found to be essential for the expression of rcsB on a plasmid. The absence of the sigma 54 factor does not have a negative effect on the transcription of rcsB. The RcsB protein is an activator of its own synthesis, particularly in the presence of NaCl. Evidence which suggests that RcsB can be phosphorylated by a presumably modified EnvZ or PhoM sensor protein leading to a suppression of the growth deficiency of ftsZ84 mutant cells and to an increase in colanic acid production was obtained. We also demonstrated that the level of colanic acid is reduced when the cells carry a multicopy rcsC plasmid, suggesting that the RcsC sensor has phosphatase activity.

Developmental regulation of transcription of the Bacillus subtilis ftsAZ operon

The products of the ftsA and ftsZ genes play a major role in septum formation in Escherichia coli. Their homologues have been found in various bacterial species, such as Bacillus subtilis where they are involved in septation during vegetative growth as well as during sporulation, a developmental process that is initiated by the formation of an asymmetrically positioned septum. Transcription of the B. subtilis ftsAZ operon was studied during exponential growth and sporulation by monitoring beta-galactosidase synthesis in strains harboring fusions of the E. coli lacZ gene with various fragments of the ftsAZ regulatory region. Transcription of the ftsAZ operon was found to be controlled by three promoters which were mapped by primer extension and characterized by their temporal pattern of expression. Two of these promoters, P1 and P3, are dependent on sigma A, the major vegetative sigma factor, and are expressed mainly during growth. The third one, P2, is recognized by sigma H associated RNA polymerase and its activity increases three- to four-fold around the onset of sporulation. The post-exponential enhancement of P2-driven transcription is abolished in a spo0A mutant but partially restored in an abrB spo0A double mutant. After inactivation by oligonucleotide-directed mutagenesis mutated copies of P1 and P2 were introduced into the chromosome upstream from the ftsAZ operon. Transformants could be obtained only when ftsAZ transcription was controlled by a combination of two intact promoters, neither P1, P2 nor P3 being essential for viability. The sporulation efficiency was found to be dependent on the level of transcription of ftsAZ, the absence of P2 still allowing 30% of the normal sporulation rate. Therefore the post-exponential burst of synthesis of the FtsA and FtsZ proteins is not an absolute requirement for the successful completion of the asymmetric septum.

An amino-proximal domain required for the localization of FtsQ in the cytoplasmic membrane, and for its biological function in Escherichia coli

The location of FtsQ, an Escherichia coli protein essential for cell division, is, under physiological conditions, in the cytoplasmic membrane facing towards the periplasmic space. An amino-proximal hydrophobic domain is required for FtsQ to reach its location and for its activity in the cell. Overexpression of modified forms of FtsQ is deleterious for the cell.

The absence of branched-chain amino acid and growth rate control at the internal ilvEp promoter of the ilvGMEDA operon

The question of whether the promoter ilvEp, located in the coding region of ilvM, the second structural gene in the ilvGMEDA operon, is subject to either amino acid- or growth rate-mediated regulation is examined. The experiments described here were performed with ilvEp-cat and ilvEp-lac fusions carried as single copies on the chromosome. The activity of the ilvEp promoter was found to respond neither to the availability of branched-chain amino acids nor to a wide range of growth rates between 35 to 390 min. In the absence of any known role for the products of the ilvGMEDA operon when repressing levels of branched-chain amino acids are present, there appears to be only a gratuitous role for the transcription at ilvEp.

Isolation and characterization of intragenic suppressors of an Escherichia coli ftsA mutation

Mutagenesis of a strain of Escherichia coli carrying a temperature-sensitive (Ts) mutation in the cell division gene ftsA yielded a number of temperature-resistant variants. In certain cases, restoration of viability at the restrictive temperature could not be attributed to suppressor mutations occurring in other genes or to structural gene reversion. DNA sequencing of the variants demonstrated the continuing presence of the original Ts mutation (ftsA13) and revealed secondary mutations within the same gene. These secondary mutations are able to rescue the ftsA13 mutation in cis, but not in trans.

ftsZ is an essential cell division gene in Escherichia coli

The ftsZ gene is thought to be an essential cell division gene in Escherichia coli. We constructed a null allele of ftsZ in a strain carrying additional copies of ftsZ on a plasmid with a temperature-sensitive replication defect. This strain was temperature sensitive for cell division and viability, confirming that ftsZ is an essential cell division gene. Further analysis revealed that after a shift to the nonpermissive temperature, cell division ceased when the level of FtsZ started to decrease, indicating that septation is very sensitive to the level of FtsZ. Subsequent studies showed that nucleoid segregation was normal while FtsZ was decreasing and that ftsZ expression was not autoregulated. The null allele could not be complemented by lambda 16-2, even though this bacteriophage can complement the thermosensitive ftsZ84 mutation and carries 6 kb of DNA upstream of the ftsZ gene.

The FtsQ protein of Escherichia coli: membrane topology, abundance, and cell division phenotypes due to overproduction and insertion mutations

The ftsQ gene is one of several genes thought to be specifically required for septum formation in Escherichia coli. Published work on the cell division behavior of ftsQ temperature-sensitive mutants suggested that the FtsQ product is required throughout the whole process of septum formation. Here we provide additional support for this hypothesis based on microscopic observations of the cell division defects resulting from insertional and temperature-sensitive mutations in the ftsQ gene, and constitutive overexpression of its gene product. On the basis of the published, predicted amino acid sequence of the FtsQ protein and our analysis of fusion proteins of the FtsQ protein to bacterial alkaline phosphatase, we conclude that FtsQ is a simple cytoplasmic membrane protein with a approximately 25-amino-acid cytoplasmic domain and a approximately 225-amino-acid periplasmic domain. We estimate that the FtsQ protein is present at about 22 copies per cell.

The Escherichia coli cell cycle: one cycle or multiple independent processes that are co-ordinated?

In the life cycle of a bacterium there are several key processes: cellular growth, chromosome replication and decatenation, nucleoid partition, septum formation, and cell division. These processes have to be carefully controlled and co-ordinated both with respect to each other and to the growth of the cell, and could be viewed as parts of a single cycle in which each step is dependent upon the previous one. Alternatively, they could be independently controlled and carefully tuned to each other without actually constituting a true cycle. In this review, using Escherichia coli as model system, we discuss these two ways of describing the bacterial life cycle. The evidence supporting independent control of the processes is presented, and some of the key questions in the elucidation of the regulation of the bacterial life cycle are discussed.

FtsZ in Bacillus subtilis is required for vegetative septation and for asymmetric septation during sporulation

A Bacillus subtilis strain was constructed in which the cell division gene, ftsZ, was placed under control of the isopropyl-beta-D-thiogalactoside (IPTG)-inducible spac promoter. This strain was dependent upon the presence of IPTG for cell division and colony formation indicating that ftsZ is an essential cell division gene in this organism. In sporulation medium this strain increased in mass and reached stationary phase in the presence or absence of IPTG, but only sporulated in the presence of IPTG. The expression of the sporulation genes spoIIG, spoIIA, and spoIIE occurred normally in the absence of IPTG as monitored by spo-lacZ fusions. However, expression of lacZ fusions to genes normally induced later in the developmental pathway, and that required processed pro-sigma E for expression, was inhibited. Immunoblot analysis revealed that pro-sigma E was not processed to its active form (sigma E) under these experimental conditions. Electron microscopy revealed that these FtsZ-depleted cells did not initiate asymmetric septation, suggesting that FtsZ has a common role in the initiation of both the vegetative and sporulation septa.

Synchronous division induced in Escherichia coli K12 by phage Mu: analysis of DNA topology and gene expression during the cell cycle

Bacteriophage Mu mutants in gene gem (Mu gemts2) induce cycles of synchronous divisions after infection of a bacterial population in steady-state conditions. In this paper, two classes of gyrB mutants, synchronizable and non-synchronizable, are described. The existence of the non-synchronizable class suggests that the gyrase B subunit is involved with Gem in the process of synchronization. Cyclical variations in DNA topology of a resident multicopy plasmid occur during synchronous growth and correlate with a modulation of the chromosomal lacZ gene expression. Transcription data for the cell division genes, ftsZ and envA, obtained studying first steps in synchronous growth after infection, show that synthesis of the two mRNA is not constant. The specific mRNA of envA seems to be stimulated soon after infection, whereas the two transcripts initiating upstream from ftsZ apparently decrease to a basal level. In both cases, however, synthesis of the mRNA virtually doubles at the time of cell division.

Alkaline phosphatase fusions in the study of cell division genes

Alkaline phosphatase fusions have been used to analyse plasmid- or phage-carried genes from the two-minute region of the Escherichia coli chromosome. These studies have revealed the following: 1) Bacteriophage lambda carries two genes for cell envelope proteins, lom and bor, that are expressed in lysogens and probably contribute to the pathogenicity of its E. coli host. 2) The ftsQ and ftsl gene products are integral proteins of the cytoplasmic membrane with small cytoplasmic domains and large periplasmic domains. 3) The ftsQ and ftsl gene products are made in very small amounts, on the order of 25 molecules per cell. 4) The ftsQ gene product is essential for cell growth and is required throughout the formation of the cell septum. 5) An open reading frame just upstream from ftsl, thought to be involved in cell division, is expressed and probably codes for a cytoplasmic membrane protein.

A novel rho promoter::Tn10 mutation suppresses and ftsQ1(Ts) missense mutation in an essential Escherichia coli cell division gene by a mechanism not involving polarity suppression

An extragenic suppressor of the Escherichia coli cell division gene ftsQ1(Ts) was isolated. The suppressor is a Tn10 insertion into the -35 promoter consensus sequence of the rho gene, designated rho promoter::Tn10. The ftsQ1(Ts) mutation was also suppressed by the rho-4 mutant allele. The rho promoter::Tn10 strain does not exhibit rho mutant polarity suppressor phenotypes. In addition, overexpression of the ftsQ1(Ts) mutation does not reverse temperature sensitivity. Furthermore, DNA sequence analysis of the ftsQ1(Ts) allele revealed that the salt-remediable, temperature-sensitive phenotype arose from a single missense mutation. The most striking phenotype of the rho promoter::Tn10 mutant strain is an increase in the level of negative supercoiling. On the basis of these observations, we conclude that the ftsQ1(Ts) mutation may be suppressed by a change in supercoiling.