The β-Lactam Resistance Protein Blr,a Small Membrane Polypeptide,Is a Component of the Escherichia coli Cell Division Machinery

In Escherichia coli, cell division is performed by a multimolecular machinery called the divisome, made of 10 essential proteins and more than 20 accessory proteins. Through a bacterial two-hybrid library screen, we identified the E. coli β-lactam resistance protein Blr, a short membrane polypeptide of 41 residues, as an interacting partner of the essential cell division protein FtsL. In addition to FtsL, Blr was found to associate with several other divisomal proteins, including FtsI, FtsK, FtsN, FtsQ, FtsW, and YmgF. Using fluorescently tagged Blr, we showed that this peptide localizes to the division septum and that its colocalization requires the presence of the late division protein FtsN. Although Blr is not essential, previous studies have shown that the inactivation of the blr gene increased the sensitivity of bacteria to β-lactam antibiotics or their resistance to cell envelope stress. Here, we found that Blr, when overproduced, restores the viability of E. coli ftsQ1(Ts) cells, carrying a thermosensitive allele of the ftsQ gene, during growth under low-osmotic-strength conditions (e.g., in synthetic media or in Luria-Bertani broth without NaCl). In contrast, the inactivation of blr increases the osmosensitivity of ftsQ1(Ts) cells, and blr ftsQ1 double mutants exhibit filamentous growth in LB broth even at a moderate salt concentration (0.5% NaCl) compared to parental ftsQ1(Ts) cells. Altogether, our results suggest that the small membrane polypeptide Blr is a novel component of the E. coli cell division apparatus involved in the stabilization of the divisome under certain stress conditions.     

Analysis of the length distribution of murein glycan strands in ftsZ and ftsI mutants of E. coli

The chain length distribution of murein glycan strands was analyzed in wild-type cells and in cells in which preseptal and/or septal murein synthesis was prevented in ftsZ84 and ftsI36 mutants of E. coli. This revealed a significant change in glycan chain lengths in newly synthesized murein associated with inactivation of the ftsZ gene product but not with inactivation of the ftsI gene product. This is the first reported abnormality in murein biosynthesis associated with mutation of an essential cell division gene.     

Isolation and characterization of Schizosaccharomyces pombe cutmutants that block nuclear division but not cytokinesis

By examining cytological phenotypes of 587 temperature-sensitive mutants of the fission yeast Schizosaccharomyces pombe, we obtained 18 mutants which cause cell division in the absence of nuclear division. By genetic analyses, these novel nuclear division arrest mutants can be classified into nine complementation groups (designated cut1 – cut9). The cytological phenotype of cut mutants is similar but not identical to that of DNA topoisomerase II mutants (top2). The cut1⁺ gene was cloned by transformation and shown to complement cut2 as well as cut1, indicating a functional relationship between the two genes. The cut genes are required for nuclear division, but their mutant phenotypes differ from most of the previously identified mutants which block nuclear division and also the subsequent cytokinesis. Fluorescence microscopy indicates that the mitotic chromosomes formed in cut mutant cells are abnormal and fail to separate properly. We suggest that cut mutations, like top2, block mitotic chromosome formation and concomitantly nuclear division, but that cytokinesis proceeds independently of the defects in nuclear division, demonstrating uncoordinated mitotic pathways. A novel mutant nuc1 is also described which shows a cytological phenotype similar to the double mutant of DNA topoisomerases I and II but contains normal levels of both DNA topoisomerase activities.     

A new dispensable genetic locus of the terminus region involved in control of cell division in Escherichia coli

Summary Temperature-sensitive mutants defective in cell division were isolated after localised mutagenesis of the terminus region of the Escherichia coli chromosome. The defective gene in one of these mutants, dicA, was mapped at 34.9 min by linkage with manA and with three physically characterized Tn10 insertions. Temperature-sensitivity conferred by mutation dicA1 in a recA backround was suppressed by the presence of hybrid plasmids carrying the wild-type gene. In addition, the mutation was suppressed either by tranposon inactivation of a nearby gene, dicB, or by deletion of the entire dicA-dicB interval. These results define the dicA-dicB locus as a new dispensable genetic cluster involved in the control of cell division.     

Twin‐arginine translocation system (tat) mutants of Salmonella are attenuated due to envelope defects,not respiratory defects

The twin‐arginine translocation system (Tat) transports folded proteins across the cytoplasmic membrane and is critical to virulence in Salmonella and other pathogens. Experimental and bioinformatic data indicate that 30 proteins are exported via Tat in Salmonella Typhimurium. However, there are no data linking specific Tat substrates with virulence. We inactivated every Tat‐exported protein and determined the virulence phenotype of mutant strains. Although a tat mutant is highly attenuated, no single Tat‐exported substrate accounts for this virulence phenotype. Rather, the attenuation is due primarily to envelope defects caused by failure to translocate three Tat substrates, the N‐acetylmuramoyl‐l ‐alanine amidases, AmiA and AmiC, and the cell division protein, SufI. Strikingly, neither the amiA amiC nor the sufI mutations alone conferred any virulence defect. Although AmiC and SufI have previously been localized to the divisome, the synthetic phenotypes observed are the first to suggest functional overlap. Many Tat substrates are involved in anaerobic respiration, but we show that a mutant completely deficient in anaerobic respiration retains full virulence in both the oral and systemic phases of infection. Similarly, an obligately aerobic mutant is fully virulent. These results suggest that in the classic mouse model of infection, S. Typhimurium is replicating only in aerobic environments.     

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.     

The Escherichia coli Cell Division Protein and Model Tat Substrate SufI (FtsP) Localizes to the Septal Ring and Has a Multicopper Oxidase-Like Structure

The Escherichia coli protein SufI (FtsP) has recently been proposed to be a component of the cell division apparatus. The SufI protein is also in widespread experimental use as a model substrate in studies of the Tat (twin arginine translocation) protein transport system. We have used SufI-GFP (green fluorescent protein) fusions to show that SufI localizes to the septal ring in the dividing cell. We have also determined the structure of SufI by X-ray crystallography to a resolution of 1.9 Å. SufI is structurally related to the multicopper oxidase superfamily but lacks metal cofactors. The structure of SufI suggests it serves a scaffolding rather than an enzymatic role in the septal ring and reveals regions of the protein likely to be involved in the protein-protein interactions required to assemble SufI at the septal ring.     

Genetic evidence for the functional redundancy of the calcineurin-and Mpk1-mediated pathways in the regulation of cellular events important for growth inSaccharomyces cerevisiae

Saccharomyces cerevisiae mutants which exhibit phenotypes (calcium resistance and vanadate sensitivity) similar to those of calcineurin-deficient mutants were isolated. The mutants were classified into four complementation groups (crv1,2,3 and4).crv1 was allelic tocnb1, a mutation in the regulatory subunit of calcineurin. The nucleotide sequences ofCRV2 andCRV3 genes which complemented thecrv2 andcrv3 mutations, respectively, are identical to those ofBCK1/SLK1/SKC1/SSP31 andMPK1/SLT2, respectively, which are both involved in the MAP kinase cascade. A calcineurin-deletion mutation (Δcnb1), which by itself has no detectable effect on growth and morphology, enhanced some phenotypes (slow growth and morphological abnormality) ofcrv2 andcrv3 mutants. These phenotypes ofcrv2 andcrv3 mutants were partially suppressed by Ca²⁺ or by overproduction of the calcineurin subunits (Cmp2 and Cnb1). Like the calcineurin-deficient mutant,crv2 andcrv3 mutants were defective in recovery from α-factor-induced growth arrest. The defect in recovery of the Δcnb1 mutant was suppressed by overexpression ofMPK1. These results indicated that the calcineurin-mediated and the Mpk1- (Bck1-) mediated signaling pathways act in parallel to regulate functionally redundant cellular events important for growth.     

AcrB,AcrD, and MdtABC Multidrug Efflux Systems Are Involved in Enterobactin Export in Escherichia coli

Escherichia coli produces the iron-chelating compound enterobactin to enable growth under iron-limiting conditions. After biosynthesis, enterobactin is released from the cell. However, the enterobactin export system is not fully understood. Previous studies have suggested that the outer membrane channel TolC is involved in enterobactin export. There are several multidrug efflux transporters belonging to resistance-nodulation-cell division (RND) family that require interaction with TolC to function. Therefore, several RND transporters may be responsible for enterobactin export. In this study, we investigated whether RND transporters are involved in enterobactin export using deletion mutants of multidrug transporters in E. coli. Single deletions of acrB, acrD, mdtABC, acrEF, or mdtEF did not affect the ability of E. coli to excrete enterobactin, whereas deletion of tolC did affect enterobactin export. We found that multiple deletion of acrB, acrD, and mdtABC resulted in a significant decrease in enterobactin export and that plasmids carrying the acrAB, acrD, or mdtABC genes restored the decrease in enterobactin export exhibited by the ΔacrB acrD mdtABC mutant. These results indicate that AcrB, AcrD, and MdtABC are required for the secretion of enterobactin.     

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

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

ATP-Binding Site Lesions in FtsE Impair Cell Division

FtsE and FtsX of Escherichia coli constitute an apparent ABC transporter that localizes to the septal ring. In the absence of FtsEX, cells divide poorly and several membrane proteins essential for cell division are largely absent from the septal ring, including FtsK, FtsQ, FtsI, and FtsN. These observations, together with the fact that ftsE and ftsX are cotranscribed with ftsY, which helps to target some proteins for insertion into the cytoplasmic membrane, suggested that FtsEX might contribute to insertion of division proteins into the membrane. Here we show that this hypothesis is probably wrong, because cells depleted of FtsEX had normal amounts of FtsK, FtsQ, FtsI, and FtsN in the membrane fraction. We also show that FtsX localizes to septal rings in cells that lack FtsE, arguing that FtsX targets the FtsEX complex to the ring. Nevertheless, both proteins had to be present to recruit further Fts proteins to the ring. Mutant FtsE proteins with lesions in the ATP-binding site supported septal ring assembly (when produced together with FtsX), but these rings constricted poorly. This finding implies that FtsEX uses ATP to facilitate constriction rather than assembly of the septal ring. Finally, topology analysis revealed that FtsX has only four transmembrane segments, none of which contains a charged amino acid. This structure is not what one would expect of a substrate-specific transmembrane channel, leading us to suggest that FtsEX is not really a transporter even though it probably has to hydrolyze ATP to support cell division.Cell division in Escherichia coli is carried out by ∼20 proteins that localize to the midcell, where they form a structure called the septal ring (also called the divisome or septalsome) (4, 27, 55, 57). One component of the septal ring is an apparent ABC transporter composed of the integral membrane protein FtsX and its associated cytoplasmic ATPase, FtsE (15, 47). FtsE and FtsX are widely conserved among gram-negative and gram-positive bacteria. ftsE and/or ftsX mutants exhibit division defects in E. coli, Neisseria gonorrhoeae, Aeromonas hydrophila, and Flavobacterium johnsoniae, indicating that FtsEX function in cell division is conserved in these organisms (33, 40, 43, 45). In contrast, FtsEX of Bacillus subtilis has no obvious role in cell division but instead regulates entry into sporulation (24).One interesting property of E. coli ftsEX null mutants is that they can be rescued by a variety of osmotic protectants (44). For example, when grown in LB containing >0.5% NaCl, an E. coli ftsEX null mutant is viable and only mildly filamentous, but upon shift to LB lacking NaCl, the cells become filamentous and die (20, 47). A shift to low-osmolarity medium is also accompanied by a dramatic slowing of the overall rate of growth (mass increase) (47). We suspect that ftsEX contributes to both cell division and growth, but it has proven difficult to exclude the possibility that the growth defect is caused by attempts at cell division that go awry.FtsEX contributes to cytokinesis by improving the assembly and/or stability of the septal ring. Septal ring assembly in an ftsEX mutant is fairly normal in LB that contains 1% NaCl but defective in LB that lacks NaCl (hereinafter referred to as LB0N) (47). More precisely, in LB0N, septal ring assemblies contain the “early” division proteins FtsZ, FtsA, and ZipA but lack the “late” proteins FtsK, FtsQ, FtsL, FtsI, and FtsN. The mechanism by which FtsEX contributes to septal ring assembly is still under investigation, but it probably involves protein-protein interactions, because FtsX has been shown to interact with FtsA and FtsQ in a bacterial two-hybrid system (31), while FtsE has been shown to interact with FtsZ in a coprecipitation assay (15). The FtsE-FtsZ interaction could be important for improving constriction rather than, or in addition to, septal ring assembly.Remarkably, nothing is known about FtsEX''s most obvious potential function—transporting a substrate involved in septum assembly. We are aware of only two studies that attempted to address this issue. The first concluded that FtsEX is needed for insertion of potassium transporters in the cytoplasmic membrane (54). However, in our view the data were not compelling and the connection to cell division, if any, is not obvious. The other study noted that ftsE and ftsX are cotranscribed with ftsY, which is a component of the signal recognition particle pathway for insertion of many proteins into the cytoplasmic membrane (20). That study therefore tested an ftsEX null mutant for defects in export of β-lactamase to the periplasm or insertion of leader peptidase into the cytoplasmic membrane. No such defects were found, so the authors concluded that FtsEX function is probably unrelated to FtsY. Besides these studies, at least one review article suggested that FtsEX might insert division proteins into the cytoplasmic membrane (8). Obviously, the finding that localization of several membrane proteins to the septal ring shows a leaky but pronounced dependence on FtsEX could be explained if the “missing” proteins were not getting into the membrane efficiently. Despite these speculations about potential FtsEX substrates, it is important to note that some members of the ABC “transporter” family do not move anything across cell membranes (reviewed in reference 19), so it cannot be taken for granted that FtsEX is a transporter at all.     

ftsE(Ts) Affects Translocation of K+-Pump Proteins into the Cytoplasmic Membrane of Escherichia coli

The ftsE(Ts) mutation of Escherichia coli causes defects in cell division and cell growth. We expressed alkaline phosphatase (PhoA) fusion proteins of KdpA, Kup, and TrkH, all of which proved functional in vivo as K⁺ ion pumps, in the mutant cells. During growth at 41°C, these proteins were progressively lost from the membrane fraction. The reduction in the abundance of these proteins inversely correlated with cell growth, but the preformed proteins in the membrane were stable at 41°C, indicating that the molecules synthesized at the permissive temperature were diluted in a growth-dependent manner at a high temperature. Pulse-chase experiments showed that KdpA-PhoA was synthesized, but the synthesized protein did not translocate into the membrane of the ftsE(Ts) cells at 41°C and degraded very rapidly. The loss of KdpA-PhoA from the membrane fractions of ftsE(Ts) cells was suppressed by a multicopy plasmid carrying the ftsE⁺ gene. While cell growth stopped when the abundance of these proteins decreased 15-fold, the addition of a high concentration of K⁺ ions specifically alleviated the growth defect of ftsE(Ts) cells but not cell division, and the cells elongated more than 100-fold. We conclude that one of the causes of growth cessation in the ftsE(Ts) mutants is a defect in the translocation of K⁺-pump proteins into the cytoplasmic membrane.     

Roles of Escherichia coli heat shock proteins DnaK, DnaJ and GrpE in mini-F plasmid replication

Summary A subset of Escherichia coli heat shock proteins, DnaK, DnaJ and GrpE were shown to be required for replication of mini-F plasmid. Strains of E. coli K12 carrying a missense mutation or deletion in the dnaK, dnaJ, or grpE gene were virtually unable to be transformed by mini-F DNA at the temperature (30° C) that permits cell growth. When excess amounts of the replication initiator protein (repE gene product) of mini-F were provided by means of a multicopy plasmid carrying repE, these mutant bacteria became capable of supporting mini-F replication under the same conditions. However, the copy number of a high copy number mini-F plasmid was reduced in these mutant bacteria as compared with the wild type in the presence of excess RepE protein. Furthermore, mini-F plasmid mutants that produce altered initiator protein and exhibit a very high copy number were able to replicate in strains deficient in any of the above heat shock proteins. These results indicate that the subset of heat shock proteins (DnaK, DnaJ and GrpE) play essential roles that help the functioning of the RepE initiator protein in mini-F DNA replication.     

AhpC Is Required for Optimal Production of Enterobactin by Escherichia coli

Escherichia coli alkyl hydroperoxide reductase subunit C (AhpC) is a peroxiredoxin that detoxifies peroxides. Here we show an additional role for AhpC in cellular iron metabolism of E. coli. Deletion of ahpC resulted in reduced growth and reduced accumulation of iron by cells grown in low-iron media. Liquid chromatography-mass spectroscopy (LC-MS) analysis of culture supernatants showed that the ahpC mutant secreted much less enterobactin, the siderophore that chelates and transports ferric iron under iron-limiting conditions, than wild-type E. coli did. The ahpC mutant produced less 2,3-dihydroxybenzoate, the intermediate in the enterobactin biosynthesis pathway, and providing 2,3-dihydroxybenzoate restored wild-type growth of the ahpC mutant. These data indicated that the defect was in an early step in enterobactin biosynthesis. Providing additional copies of entC, which functions in the first dedicated step of enterobactin biosynthesis, but not of other enterobactin biosynthesis genes, suppressed the mutant phenotype. Additionally, providing either shikimate or a mixture of para-aminobenzoate, tryptophan, tyrosine, and phenylalanine, which, like enterobactin, are synthesized from the precursor chorismate, also suppressed the mutant phenotype. These data suggested that AhpC affected the activity of EntC or the availability of the chorismate substrate.     

Negative control of cell division by mreB, a gene that functions in determining the rod shape of Escherichia coli cells.

Exponentially growing Escherichia coli cells containing additional copies of the shape-determining gene mreB were found to be elongated, whereas mreB mutant cells were spherical and overproduced penicillin-binding protein 3, a septum peptidoglycan synthetase. The effect of the mreB gene on expression of ftsI, the structural gene for penicillin-binding protein 3, was examined by using an ftsI-lacZ fusion gene on a plasmid. Formation of beta-galactosidase from the fusion gene was significantly increased in mreB129 mutant cells, and its overproduction was suppressed to a normal level by the presence of a plasmid containing the mreB gene. These results indicate a negative mechanism of control of cell division by this morphology gene and suggest that the gene functions in determining whether division or elongation of the cells occurs.     

A mutation in the gene for trigger factor suppresses the defect in cell division in the divE42 mutant of Escherichia coli K12

A total of sixteen spontaneously generated, independent suppressor mutants was isolated from a mutant (divE42) of Escherichia coli K12 that is defective in cell division. One of the suppressor mutants, designated TR4, had a novel phenotype: it was able to grow at 42°?C but not at 32°?C. The Kohara genomic library was screened for complementing clones. Clone 148 was able to complement the mutation responsible for the cold-sensitive phenotype, and the gene for trigger factor (tig), which encodes a ribosome-associated peptidyl-prolyl cis/trans isomerase, was identified as the mutated gene by deletion analysis with the insert DNA from clone 148. DNA sequencing revealed that the mutation in the tig gene of the TR4 suppressor mutant was a single nucleotide insertion (+A) at a distance of 834 nucleotides from the initiation codon for this enzyme. When the wild-type tig gene was introduced into the TR4 suppressor mutant, the bacteria were able to grow at 32°?C but not at 42°?C, an indication that the intergenic suppressor mutation was recessive to the wild-type allele. A model is proposed that accounts for the phenotypes of the divE42 mutant and the TR4 suppressor mutant.     

Involvement of the AtoS-AtoC signal transduction system in poly-(R)-3-hydroxybutyrate biosynthesis in Escherichia coli

The AtoS–AtoC signal transduction system in E. coli, which induces the atoDAEB operon for the growth of E. coli in short-chain fatty acids, can positively modulate the levels of poly-(R)-3-hydroxybutyrate (cPHB) biosynthesis, a biopolymer with many physiological roles in E. coli. Increased amounts of cPHB were synthesized in E. coli upon exposure of the cells to acetoacetate, the inducer of the AtoS–AtoC two-component system. While E. coli that overproduce both components of the signal transduction system synthesize higher quantities of cPHB (1.5–4.5 fold), those that overproduce either AtoS or AtoC alone do not display such a phenotype. Lack of enhanced cPHB production was also observed in cells overexpressing AtoS and phosphorylation-impaired AtoC mutants. The results were not affected by the nature of the carbon source used, i.e., glucose, acetate or acetoacetate. An E. coli strain with a deletion in the atoS–atoC locus (ΔatoSC) synthesized lower amounts of cPHB compared to wild-type cells. When the ΔatoSC strain was transformed with a plasmid carrying a 6.4-kb fragment encoding the AtoS–AtoC system, cPHB biosynthesis was restored to the level of the atoSC⁺ cells. Introduction of a multicopy plasmid carrying a functional atoDAEB operon, but not one with a promoterless operon, resulted in increased cPHB synthesis only in atoSC⁺ cells in the presence of acetoacetate. These results indicate that the presence of both a functional AtoS–AtoC two-component signal transduction system and a functional atoDAEB operon is critical for the enhanced cPHB biosynthesis in E. coli.     

Functional relationship between Escherichia coli RNase E and the CafA protein

We analyzed the functional relationship between the Escherichia coli RNase E and the CafA protein, which show extensive sequence similarity. The temperature-sensitive growth of the RNase E mutant strain ams1 was partially suppressed by multicopy plasmids bearing the cafA gene. Introduction of a cafA::cat mutation enhanced the temperature sensitivity of the ams1 mutant. These results suggest that there is a functional homology between these two proteins.     

Influence of recC and uvrD on ultraviolet-induced mutation to valine resistance in E. coli K12

The production of mutants in E. coli exposed to ultraviolet light is initiated by photochemical reactions, and completed by metabolic processes controlled by recA and other genes. Ultraviolet-induced mutagenesis to valine resistance was measured in cells carrying recC, uvrD, or both recC and uvrD. The spontaneous and UV-induced mutagenesis was slightly greater in those carrying uvrD, as compared to recC or wild-type. At low doses, UV mutagenesis in the recC uvrD double mutant was greater than in either recC or wild-type, and was comparable to that in the uvrD strain, although this double mutant was very UV-sensitive and showed poor survival at doses above 2 J/m².