Signal transduction in the cell cycle regulation of Caulobacter differentiation

A Landmark Protein Essential for Establishing and Perpetuating the Polarity of a Bacterial Cell

Polarity is often an intrinsic property of the cell, yet little is known about its origin or its maintenance over generations. Here we identify a landmark protein, TipN, which acts as a spatial and temporal cue for setting up the correct polarity in the bacterium Caulobacter crescentus. TipN marks the new pole throughout most of the cell cycle, and its relocation to the nascent poles at the end of division provides a preexisting reference point for orienting the polarity axis in the progeny. Deletion of tipN causes pleiotropic polarity defects, including frequently reversed asymmetry in progeny size and mislocalization of proteins and organelles. Ectopic localization of TipN along the lateral side of the cell creates new axes of polarity leading to cell branching and formation of competent cell poles. Localization defects of the actin-like protein MreB in the DeltatipN mutant suggest that TipN is upstream of MreB in regulating cell polarity.

The phagosomal transporter A couples threonine acquisition to differentiation and replication of Legionella pneumophila in macrophages

Differentiation in response to environmental cues is integral to the success of many intracellular pathogens. By characterizing a Legionella pneumophila mutant defective for differentiation in broth and replication in macrophages, we identified a subfamily of major facilitator superfamily transporters, here named Pht (phagosomal transporter), that also is conserved in two other vacuolar pathogens, Coxiella burnetii and Francisella tularensis. Biolog phenotype microarray analysis indicated that PhtA transports threonine, an essential amino acid. Either excess threonine or threonine peptides bypass phtA function. In minimal medium, phtA mutants do not replicate; in rich broth, the bacteria prematurely differentiate to the transmissive phase, as judged by the kinetics of flaA-gfp expression, heat resistance, and sodium sensitivity. PhtA is dispensable for transmissive L. pneumophila to establish and persist within a replication vacuole but is essential for their differentiation to the replicative phase, based on phenotypic and RT-PCR analysis. Accordingly, we propose that the Pht transporter family equips transmissive L. pneumophila, C. burnetii, and F. tularensis to assess their phagosomal nutrient supply before committing to reenter the cell cycle.

Cytokinesis monitoring during development; rapid pole-to-pole shuttling of a signaling protein by localized kinase and phosphatase in Caulobacter

For successful generation of different cell types by asymmetric cell division, cell differentiation should be initiated only after completion of division. Here, we describe a control mechanism by which Caulobacter couples the initiation of a developmental program to the completion of cytokinesis. Genetic evidence indicates that localization of the signaling protein DivK at the flagellated pole prevents premature initiation of development. Photobleaching and FRET experiments show that polar localization of DivK is dynamic with rapid pole-to-pole shuttling of diffusible DivK generated by the localized activities of PleC phosphatase and DivJ kinase at opposite poles. This shuttling is interrupted upon completion of cytokinesis by the segregation of PleC and DivJ to different daughter cells, resulting in disruption of DivK localization at the flagellated pole and subsequent initiation of development in the flagellated progeny. Thus, dynamic polar localization of a diffusible protein provides a control mechanism that monitors cytokinesis to regulate development.

Role of the GGDEF regulator PleD in polar development of Caulobacter crescentus

Several members of the two-component signal transduction family have been implicated in the control of polar development in Caulobacter crescentus: PleC and DivJ, two polarly localized histidine sensor kinases; and the response regulators DivK and PleD. The PleD protein was shown previously to be required during the swarmer-to-stalked cell transition for flagellar ejection and efficient stalk biogenesis. Here, we present data indicating that PleD also controls the onset of motility and a cell density switch immediately preceding cell division. Constitutively active alleles of pleD or wspR, an orthologue from Pseudomonas fluorescens, almost completely suppressed C. crescentus motility and inhibited the increase in swarmer cell density during cell differentiation. The observation that these alleles also had a dominant-negative effect on motility in a pleC divJ and a pleC divK mutant background indicated that PleD is located downstream of the other components in the signal transduction cascade, which controls the activity of the flagellar motor. In addition, the presence of a constitutive pleD or wspR allele resulted in a doubling of the average stalk length. Together, this is consistent with a model in which the active form of PleD, PleD approximately P, negatively controls aspects of differentiation in the late predivisional cell, whereas it acts positively on polar development during the swarmer-to-stalked cell transition. In agreement with such a model, we found that DivJ, which localizes to the stalked pole during cell differentiation, positively controlled the in vivo phosphorylation status of PleD, and the swarmer pole-specific PleC kinase modulated this status in a negative manner. Furthermore, domain switch experiments demonstrated that the WspR GGDEF output domain from P. fluorescens is active in C. crescentus, favouring a more general function for this novel signalling domain over a specific role such as DNA or protein interaction. Possible roles for PleD and its C-terminal output domain in modulating the polar cell surface of C. crescentus are discussed.

On the origin, evolution, and nature of programmed cell death: a timeline of four billion years

Programmed cell death is a genetically regulated process of cell suicide that is central to the development, homeostasis and integrity of multicellular organisms. Conversely, the dysregulation of mechanisms controlling cell suicide plays a role in the pathogenesis of a wide range of diseases. While great progress has been achieved in the unveiling of the molecular mechanisms of programmed cell death, a new level of complexity, with important therapeutic implications, has begun to emerge, suggesting (i) that several different self-destruction pathways may exist and operate in parallel in our cells, and (ii) that molecular effectors of cell suicide may also perform other functions unrelated to cell death induction and crucial to cell survival. In this review, I will argue that this new level of complexity, implying that there may be no such thing as a 'bona fide' genetic death program in our cells, might be better understood when considered in an evolutionary context. And a new view of the regulated cell suicide pathways emerges when one attempts to ask the question of when and how they may have become selected during evolution, at the level of ancestral single-celled organisms.

Polar flagellar motility of the Vibrionaceae

Polar flagella of Vibrio species can rotate at speeds as high as 100,000 rpm and effectively propel the bacteria in liquid as fast as 60 microm/s. The sodium motive force powers rotation of the filament, which acts as a propeller. The filament is complex, composed of multiple subunits, and sheathed by an extension of the cell outer membrane. The regulatory circuitry controlling expression of the polar flagellar genes of members of the Vibrionaceae is different from the peritrichous system of enteric bacteria or the polar system of Caulobacter crescentus. The scheme of gene control is also pertinent to other members of the gamma purple bacteria, in particular to Pseudomonas species. This review uses the framework of the polar flagellar system of Vibrio parahaemolyticus to provide a synthesis of what is known about polar motility systems of the Vibrionaceae. In addition to its propulsive role, the single polar flagellum of V. parahaemolyticus is believed to act as a tactile sensor controlling surface-induced gene expression. Under conditions that impede rotation of the polar flagellum, an alternate, lateral flagellar motility system is induced that enables movement through viscous environments and over surfaces. Although the dual flagellar systems possess no shared structural components and although distinct type III secretion systems direct the simultaneous placement and assembly of polar and lateral organelles, movement is coordinated by shared chemotaxis machinery.

Cycle-regulated genes and cell cycle regulation

The transcriptional profile of the entire Caulobacter crescentus genome over a synchronous cell cycle was recently described. The analysis reveals a stunning 553 cell-cycle-regulated genes or orfs, nearly 19% of the genome, including putative functions in virtually all biological activities. Over a quarter of these genes/orfs respond to the Caulobacter master regulator, CtrA, most of them apparently indirectly. The analysis confirms and extends earlier observations showing that many proteins involved in cell cycle functions are expressed at the cell age when they are needed. Conversely, the data suggest that proteins specifically expressed at a particular age may be involved in a process taking place then.

Cell cycle and positional constraints on FtsZ localization and the initiation of cell division in Caulobacter crescentus

Swarmer cells of Caulobacter crescentus are devoid of the cell division initiation protein FtsZ and do not replicate DNA. FtsZ is synthesized during the differentiation of swarmer cells into replicating stalked cells. We show that FtsZ first localizes at the incipient stalked pole in differentiating swarmer cells. FtsZ subsequently localizes at the mid-cell early in the cell cycle. In an effort to understand whether Z-ring formation and cell constriction are driven solely by the cell cycle-regulated increase in FtsZ concentration, FtsZ was artificially expressed in swarmer cells at a level equivalent to that found in predivisional cells. Immunofluorescence microscopy showed that, in these swarmer cells, simply increasing FtsZ concentration was not sufficient for Z-ring formation; Z-ring formation took place only in stalked cells. Expression of FtsZ in swarmer cells did not alter the timing of cell constriction initiation during the cell cycle but, instead, caused additional constrictions and a delay in cell separation. These additional constrictions were confined to sites close to the original mid-cell constriction. These results suggest that the timing and placement of Z-rings is tightly coupled to an early cell cycle event and that cell constriction is not solely dependent on a threshold level of FtsZ.

CtrA mediates a DNA replication checkpoint that prevents cell division in Caulobacter crescentus

Coordination of DNA replication and cell division is essential in order to ensure that progeny cells inherit a full copy of the genome. Caulobacter crescentus divides asymmetrically to produce a non-replicating swarmer cell and a replicating stalked cell. The global response regulator CtrA coordinates DNA replication and cell division by repressing replication initiation and transcription of the early cell division gene ftsZ in swarmer cells. We show that CtrA also mediates a DNA replication checkpoint of cell division by regulating the late cell division genes ftsQ and ftsA. CtrA activates transcription of the P(QA) promoter that co-transcribes ftsQA, thus regulating the ordered expression of early and late cell division proteins. Cells inhibited for DNA replication are unable to complete cell division. We show that CtrA is not synthesized in pre-divisional cells in which replication has been inhibited, preventing the transcription of P(QA) and cell division. Replication inhibition prevents the activation of the ctrA P2 promoter, which normally depends on CtrA phosphorylation. This suggests the possibility that CtrA phosphorylation may be affected by replication inhibition.

Analysis of the polar flagellar gene system of Vibrio parahaemolyticus

Vibrio parahaemolyticus has dual flagellar systems adapted for locomotion under different circumstances. A single, sheathed polar flagellum propels the swimmer cell in liquid environments. Numerous unsheathed lateral flagella move the swarmer cell over surfaces. The polar flagellum is produced continuously, whereas the synthesis of lateral flagella is induced under conditions that impede the function of the polar flagellum, e.g., in viscous environments or on surfaces. Thus, the organism possesses two large gene networks that orchestrate polar and lateral flagellar gene expression and assembly. In addition, the polar flagellum functions as a mechanosensor controlling lateral gene expression. In order to gain insight into the genetic circuitry controlling motility and surface sensing, we have sought to define the polar flagellar gene system. The hierarchy of regulation appears to be different from the polar system of Caulobacter crescentus or the peritrichous system of enteric bacteria but is pertinent to many Vibrio and Pseudomonas species. The gene identity and organization of 60 potential flagellar and chemotaxis genes are described. Conserved sequences are defined for two classes of polar flagellar promoters. Phenotypic and genotypic analysis of mutant strains with defects in swimming motility coupled with primer extension analysis of flagellar and chemotaxis transcription provides insight into the polar flagellar organelle, its assembly, and regulation of gene expression.

Cell cycle regulator phosphorylation stimulates two distinct modes of binding at a chromosome replication origin

In Caulobacter crescentus, the global response regulator CtrA controls chromosome replication and determines the fate of two different cell progenies. Previous studies proposed that CtrA represses replication by binding to five sites, designated [a-e], in the replication origin. We show that phosphorylated CtrA binds sites [a-e] with 35- to 100-fold lower K(d) values than unphosphorylated CtrA. CtrA phosphorylation stimulates two distinct modes of binding to the replication origin. Phosphorylation stimulates weak intrinsic protein-protein cooperation between half-sites and does not stimulate CtrA-P binding unless protein-DNA contacts are made at both half-sites. CtrA phosphorylation also stimulates cooperative binding between complete sites [a] and [b]. However, binding to each of the other CtrA-binding sites [c], [d] and [e] is completely independent and suggests a modular organization of replication control by CtrA. We therefore propose a model where a phosphorelay targets separate biochemical activities inside the replication origin through both cooperative and independent CtrA-binding sites.

A novel bacterial tyrosine kinase essential for cell division and differentiation

Protein kinases play central roles in the regulation of eukaryotic and prokaryotic cell growth, division, and differentiation. The Caulobacter crescentus divL gene encodes a novel bacterial tyrosine kinase essential for cell viability and division. Although the DivL protein is homologous to the ubiquitous bacterial histidine protein kinases (HPKs), it differs from previously studied members of this protein kinase family in that it contains a tyrosine residue (Tyr-550) in the conserved H-box instead of a histidine residue, which is the expected site of autophosphorylation. DivL is autophosphorylated on Tyr-550 in vitro, and this tyrosine residue is essential for cell viability and regulation of the cell division cycle. Purified DivL also catalyzes phosphorylation of CtrA and activates transcription in vitro of the cell cycle-regulated fliF promoter. Suppressor mutations in ctrA bypass the conditional cell division phenotype of cold-sensitive divL mutants, providing genetic evidence that DivL function in cell cycle and developmental regulation is mediated, at least in part, by the global response regulator CtrA. DivL is the only reported HPK homologue whose function has been shown to require autophosphorylation on a tyrosine, and, thus, it represents a new class of kinases within this superfamily of protein kinases.

Differential localization of two histidine kinases controlling bacterial cell differentiation

The bacterium C. crescentus coordinates cellular differentiation and cell cycle progression via a network of signal transduction proteins. Here, we demonstrate that the antagonistic DivJ and PleC histidine kinases that regulate polar differentiation are differentially localized as a function of the cell cycle. The DivJ kinase localizes to the stalked pole in response to a signal at the G1-to-S transition, while the PleC kinase is localized to the flagellar pole in swarmer and predivisional cells but is dispersed throughout the cell in the stalked cell. PleC, which is required for DivJ localization, may provide the cue at the G1-to-S transition that directs the polar positioning of DivJ. The dynamic positioning of signal transduction proteins may contribute to the regulation of polar differentiation at specific times during the bacterial cell cycle.

The histidine protein kinase superfamily

Signal transduction in microorganisms and plants is often mediated by His-Asp phosphorelay systems. Two conserved families of proteins are centrally involved: histidine protein kinases and phospho-aspartyl response regulators. The kinases generally function in association with sensory elements that regulate their activities in response to environmental signals. A sequence analysis with 348 histidine kinase domains reveals that this family consists of distinct subgroups. A comparative sequence analysis with 298 available receiver domain sequences of cognate response regulators demonstrates a significant correlation between kinase and regulator subfamilies. These findings suggest that different subclasses of His-Asp phosphorelay systems have evolved independently of one another.

Cell cycle expression and transcriptional regulation of DNA topoisomerase IV genes in caulobacter

DNA replication and differentiation are closely coupled during the Caulobacter crescentus cell cycle. We have previously shown that DNA topoisomerase IV (topo IV), which is encoded by the parE and parC genes, is required for chromosomal partitioning, cell division, and differentiation in this bacterium (D. Ward and A. Newton, Mol. Microbiol. 26:897-910, 1997). We have examined the cell cycle regulation of parE and parC and report here that transcription of these topo IV genes is induced during the swarmer-to-stalked-cell transition when cells prepare for initiation of DNA synthesis. The regulation of parE and parC expression is not strictly coordinated, however. The rate of parE transcription increases ca. 20-fold during the G1-to-S-phase transition and in this respect, its pattern of regulation is similar to those of several other genes required for chromosome duplication. Transcription from the parC promoter, by contrast, is induced only two- to threefold during this cell cycle period. Steady-state ParE levels are also regulated, increasing ca. twofold from low levels in swarmer cells to a maximum immediately prior to cell division, while differences in ParC levels during the cell cycle could not be detected. These results suggest that topo IV activity may be regulated primarily through parE expression. The presumptive promoters of the topo IV genes display striking similarities to, as well as differences from, the consensus promoter recognized by the major Caulobacter sigma factor sigma73. We also present evidence that a conserved 8-mer sequence motif located in the spacers between the -10 and -35 elements of the parE and parC promoters is required for maximum levels of parE transcription, which raises the possibility that it may function as a positive regulatory element. The pattern of parE transcription and the parE and parC promoter architecture suggest that the topo IV genes belong to a specialized subset of cell cycle-regulated genes required for chromosome replication.

Cell cycle-dependent degradation of a flagellar motor component requires a novel-type response regulator

The poles of each Caulobacter crescentus cell undergo morphological development as a function of the cell cycle. A single flagellum assembled at one pole during the asymmetric cell division is later ejected and replaced by a newly synthesized stalk when the motile swarmer progeny differentiates into a sessile stalked cell. The removal of the flagellum during the swarmer-to-stalked cell transition coincides with the degradation of the FliF flagellar anchor protein. We report here that the cell cycle-dependent turnover of FliF does not require the structural components of the flagellum itself, arguing that it is the initial event leading to the ejection of the flagellum. Analysis of a polar development mutant, pleD, revealed that the pleD gene was required for efficient removal of FliF and for ejection of the flagellar structure during the swarmer-to-stalked cell transition. The PleD requirement for FliF degradation was also not dependent on the presence of any part of the flagellar structure. In addition, only 25% of the cells were able to synthesize a stalk during cell differentiation when PleD was absent. The pleD gene codes for a member of the response regulator family with a novel C-terminal regulatory domain. Mutational analysis confirmed that a highly conserved motif in the PleD C-terminal domain is essential to promote both FliF degradation and stalk biogenesis during cell differentiation. Signalling through the C-terminal domain of PleD is thus required for C. crescentus polar development. A second gene, fliL, was shown to be required for efficient turnover of FliF, but not for stalk biogenesis. The possible roles of PleD and FliL in C. crescentus polar development are discussed.

Genetic analysis of mecillinam-resistant mutants of Caulobacter crescentus deficient in stalk biosynthesis

Stalk synthesis in Caulobacter crescentus is a developmentally controlled and spatially restricted event that requires the synthesis of peptidoglycan at the stalk-cell body junction. We show that the beta-lactam antibiotic mecillinam prevents stalk synthesis by inhibiting stalk elongation. In addition, mecillinam causes an increase in the diameter of the stalk at the stalk-cell body junction. We describe two mutations that confer resistance to mecillinam and that prevent stalk elongation. These mutations are probably allelic, and they map to a locus previously not associated with stalk synthesis.

Aberrant cell division and random FtsZ ring positioning in Escherichia coli cpxA* mutants

In Escherichia coli, certain mutations in the cpxA gene (encoding a sensor kinase of a two-component signal transduction system) randomize the location of FtsZ ring assembly and dramatically affect cell division. However, deletion of the cpxRA operon, encoding the sensor kinase and its cognate regulator CpxR, has no effect on division site biogenesis. It appears that certain mutant sensor kinases (CpxA*) either exhibit hyperactivity on CpxR or extend their signalling activity to one or more noncognate response regulators involved in cell division.

Ordered expression of ftsQA and ftsZ during the Caulobacter crescentus cell cycle

The mechanisms by which bacterial cell division and DNA replication are co-ordinated are still unknown. We have used the easily synchronizable bacterium Caulobacter crescentus to determine when the cell division genes ftsQ and ftsA are transcribed during the DNA replication cycle and to compare their transcription with that of ftsZ. Unlike the situation in Escherichia coli, transcription of ftsQ and ftsA does not extend into ftsZ in Caulobacter. ftsQ and ftsA are co-transcribed by a strong promoter, P(QA), present within the end of the ddl gene upstream of ftsQ. Transcription of P(QA) is turned on at the end of the DNA replication period, coincident with the end of the ftsZ transcription period. ftsA is also transcribed by another promoter, P(A), present between ftsQ and ftsA. P(A) transcription is approximately 10 times weaker than P(QA) and occurs during the DNA replication period. Transcription of ftsA by P(A) is sufficient for cell viability, but is not sufficient for normal cell division. When the transcription of ftsA is increased constitutively, cell division is inhibited and stalks are synthesized at aberrant positions. Thus, transcription of ftsA and ftsZ mimics their order of action in Caulobacter and proper transcription of ftsA has to be maintained for normal cell division and differentiation.

Cell cycle-dependent transcriptional and proteolytic regulation of FtsZ in Caulobacter

In the differentiating bacterium Caulobacter crescentus, the cell division initiation protein FtsZ is present in only one of the two cell types. Stalked cells initiate a new round of DNA replication immediately after cell division and contain FtsZ, whereas the progeny swarmer cells are unable to initiate DNA replication and do not contain FtsZ. We show that FtsZ expression is controlled by cell cycle-dependent transcription and proteolysis. Transcription of ftsZ is repressed in swarmer cells and is activated concurrently with the initiation of DNA replication. At the end of the DNA replication period, transcription of ftsZ decreases substantially. We show that the global cell cycle regulator CtrA is involved in the cell cycle control of ftsZ transcription. CtrA binds to a site that overlaps the ftsZ transcription start site. Removal of the CtrA-binding site results in transcription of the ftsZ promoter in swarmer cells. Decreasing the cellular concentration of CtrA increases ftsZ transcription and conversely, increasing the concentration of CtrA decreases ftsZ transcription. Because CtrA is present in swarmer cells, is degraded at the same time as ftsZ transcription begins, and reappears when ftsZ transcription decreases at the end of the cell cycle, we propose that CtrA is a repressor of ftsZ transcription. We show that proteolysis is an important determinant of cell type-specific distribution and cell cycle variation of FtsZ. FtsZ is stable when it is synthesized and assembles into the cytokinetic ring at the beginning of the cell cycle. After the initiation of cell division, the rate of FtsZ degradation increases as both the constriction site and the FtsZ ring decrease in diameter. When ftsZ is expressed constitutively from inducible promoters, the abundance of FtsZ still varies during the cell cycle. The coupling of transcription and proteolysis to cell division ensures that FtsZ is inherited only by the progeny cell that will begin DNA replication immediately after cell division.

An essential, multicomponent signal transduction pathway required for cell cycle regulation in Caulobacter

Cell differentiation and division in Caulobacter crescentus are regulated by a signal transduction pathway mediated by the histidine kinase DivJ and the essential response regulator DivK. Here we report genetic and biochemical evidence that the DivJ and DivK proteins function to control the activity of CtrA, a response regulator required for multiple cell cycle events, including flagellum biosynthesis, DNA replication, and cell division. Temperature-sensitive sokA (suppressor of divK) alleles were isolated as extragenic suppressors of a cold-sensitive divK mutation and mapped to the C terminus of the CtrA protein. The sokA alleles also suppress the lethal phenotype of a divK gene disruption and the cold-sensitive cell division phenotype of divJ mutants. The relationship between these signal transduction components and their target was further defined by demonstrating that the purified DivJ kinase phosphorylates CtrA, as well as DivK. Our studies also showed that phospho-CtrA activates transcription in vitro from the class II flagellar genes and that their promoters are recognized by the principal C. crescentus sigma factor sigma73. We propose that an essential signal transduction pathway mediated by DivJ, DivK, and CtrA coordinates cell cycle and developmental events in C. crescentus by regulating the level of CtrA phosphorylation and transcription from sigma73-dependent class II gene promoters. Our results suggest that an unidentified phosphotransfer protein or kinase (X) is responsible for phosphoryl group transfer to CtrA in the proposed DivJ --> DivK --> X --> CtrA phosphorelay pathway.

Roles of the histidine protein kinase pleC in Caulobacter crescentus motility and chemotaxis

The Caulobacter crescentus histidine kinase genes pleC and divJ have been implicated in the regulation of polar morphogenesis and cell division, respectively. Mutations in pleC also potentiate the cell division phenotype of divJ mutations. To investigate the involvement of the PleC kinase in motility and cell cycle regulation, we carried out a pseudoreversion analysis of the divJ332 allele, which confers a temperature-sensitive motility (Mot-) phenotype. All cold-sensitive pseudorevertants with a Mot+ phenotype at 37 degrees C and a cold-sensitive swarm phenotype in soft agar at 24 degrees C contained extragenic suppressors that were null mutations mapping to pleC. Instead of a cell division defect at the nonpermissive temperature, however, revertants displayed a cold-sensitive defect in chemotaxis (Che-). In addition, the mutant cells were also supermotile, a phenotype previously associated only with mutations in the response regulator gene pleD that block the loss of motility. We also found that the Mot- defect of pleC mutants is suppressed by a pleD301/pleD+ merodiploid and results in a similar, supermotile, cold-sensitive Che- phenotype. These results implicate signal transduction pathways mediated by PleC-DivK and DivJ-PleD in the regulation of chemotaxis as well as motility. We discuss these findings and the observation that although the PleC kinase does not play an indispensable role in cell division, a temperature-sensitive allele of pleC (pleC319) has severely reduced viability under stringent growth conditions.

Purification, characterization, and reconstitution of DNA-dependent RNA polymerases from Caulobacter crescentus

Cell differentiation in the Caulobacter crescentus cell cycle requires differential gene expression that is regulated primarily at the transcriptional level. Until now, however, a defined in vitro transcription system for the biochemical study of developmentally regulated transcription factors had not been available in this bacterium. We report here the purification of C. crescentus RNA polymerase holoenzymes and resolution of the core RNA polymerase from holoenzymes by chromatography on single-stranded DNA cellulose. The three RNA polymerase holoenzymes Esigma54, Esigma32, and Esigma73 were reconstituted exclusively from purified C. crescentus core and sigma factors. Reconstituted Esigma54 initiated transcription from the sigma54-dependent fljK promoter of C. crescentus in the presence of the transcription activator FlbD, and active Esigma32 specifically initiated transcription from the sigma32-dependent promoter of the C. crescentus heat-shock gene dnaK. For reconstitution of the Esigma73 holoenzyme, we overexpressed the C. crescentus rpoD gene in Escherichia coli and purified the full-length sigma73 protein. The reconstituted Esigma73 recognized the sigma70-dependent promoters of the E. coli lacUV5 and neo genes, as well as the sigma73-dependent housekeeping promoters of the C. crescentus pleC and rsaA genes. The ability of the C. crescentus Esigma73 RNA polymerase to recognize E. coli sigma70-dependent promoters is consistent with relaxed promoter specificity of this holoenzyme previously observed in vivo.

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.

Inactivation of FtsI inhibits constriction of the FtsZ cytokinetic ring and delays the assembly of FtsZ rings at potential division sites

A universally conserved event in cell division is the formation of a cytokinetic ring at the future site of division. In the bacterium Escherichia coli, this ring is formed by the essential cell division protein FtsZ. We have used immunofluorescence microscopy to show that FtsZ assembles early in the division cycle, suggesting that constriction of the FtsZ ring is regulated and supporting the view that FtsZ serves as a bacterial cytoskeleton. Assembly of FtsZ rings was heterogeneously affected in an ftsI temperature-sensitive mutant grown at the nonpermissive temperature, some filaments displaying a striking defect in FtsZ assembly and others displaying little or no defect. By using low concentrations of the beta-lactams cephalexin and piperacillin to specifically inhibit FtsI (PBP3), an enzyme that synthesizes peptidoglycan at the division septum, we show that FtsZ ring constriction requires the transpeptidase activity of FtsI. Unconstricted FtsZ rings are stably trapped at the midpoint of the cell for several generations after inactivation of FtsI, whereas partially constricted FtsZ rings are less effectively trapped. In addition, FtsZ rings are able to assemble in newborn cells in the presence of cephalexin, suggesting that newborn cells contain a site at which FtsZ can assemble (the nascent division site) and that the transpeptidase activity of FtsI is not required for assembly of FtsZ at these sites. However, aside from this first round of FtsZ ring assembly, very few additional FtsZ rings assemble in the presence of cephalexin, even after several generations of growth. One interpretation of these results is that the transpeptidase activity of FtsI is required, directly or indirectly, for the assembly of nascent division sites and thereby for future assembly of FtsZ rings.