The Caulobacter crescentus FlbD protein acts at ftr sequence elements both to activate and to repress transcription of cell cycle-regulated flagellar genes

A Polar Flagellar Transcriptional Program Mediated by Diverse Two-Component Signal Transduction Systems and Basal Flagellar Proteins Is Broadly Conserved in Polar Flagellates

Relative to peritrichous bacteria, polar flagellates possess regulatory systems that order flagellar gene transcription differently and produce flagella in specific numbers only at poles. How transcriptional and flagellar biogenesis regulatory systems are interlinked to promote the correct synthesis of polar flagella in diverse species has largely been unexplored. We found evidence for many Gram-negative polar flagellates encoding two-component signal transduction systems with activity linked to the formation of flagellar type III secretion systems to enable production of flagellar rod and hook proteins at a discrete, subsequent stage during flagellar assembly. This polar flagellar transcriptional program assists, in some manner, the FlhF/FlhG flagellar biogenesis regulatory system, which forms specific flagellation patterns in polar flagellates in maintaining flagellation and motility when activity of FlhF or FlhG might be altered. Our work provides insight into the multiple regulatory processes required for polar flagellation.

Bacterial flagella are rotating nanomachines required for motility. Flagellar gene expression and protein secretion are coordinated for efficient flagellar biogenesis. Polar flagellates, unlike peritrichous bacteria, commonly order flagellar rod and hook gene transcription as a separate step after production of the MS ring, C ring, and flagellar type III secretion system (fT3SS) core proteins that form a competent fT3SS. Conserved regulatory mechanisms in diverse polar flagellates to create this polar flagellar transcriptional program have not been thoroughly assimilated. Using in silico and genetic analyses and our previous findings in Campylobacter jejuni as a foundation, we observed a large subset of Gram-negative bacteria with the FlhF/FlhG regulatory system for polar flagellation to possess flagellum-associated two-component signal transduction systems (TCSs). We present data supporting a general theme in polar flagellates whereby MS ring, rotor, and fT3SS proteins contribute to a regulatory checkpoint during polar flagellar biogenesis. We demonstrate that Vibrio cholerae and Pseudomonas aeruginosa require the formation of this regulatory checkpoint for the TCSs to directly activate subsequent rod and hook gene transcription, which are hallmarks of the polar flagellar transcriptional program. By reprogramming transcription in V. cholerae to more closely follow the peritrichous flagellar transcriptional program, we discovered a link between the polar flagellar transcription program and the activity of FlhF/FlhG flagellar biogenesis regulators in which the transcriptional program allows polar flagellates to continue to produce flagella for motility when FlhF or FlhG activity may be altered. Our findings integrate flagellar transcriptional and biogenesis regulatory processes involved in polar flagellation in many species.

Genetic and Transcriptional Analyses of the Flagellar Gene Cluster in Actinoplanes missouriensis

Actinoplanes missouriensis, a Gram-positive and soil-inhabiting bacterium, is a member of the rare actinomycetes. The filamentous cells produce sporangia, which contain hundreds of flagellated spores that can swim rapidly for a short period of time until they find niches for germination. These swimming cells are called zoospores, and the mechanism of this unique temporal flagellation has not been elucidated. Here, we report all of the flagellar genes in the bacterial genome and their expected function and contribution for flagellar morphogenesis. We identified a large flagellar gene cluster composed of 33 genes that encode the majority of proteins essential for assembling the functional flagella of Gram-positive bacteria. One noted exception to the cluster was the location of the fliQ gene, which was separated from the cluster. We examined the involvement of four genes in flagellar biosynthesis by gene disruption, fliQ, fliC, fliK, and lytA Furthermore, we performed a transcriptional analysis of the flagellar genes using RNA samples prepared from A. missouriensis grown on a sporangium-producing agar medium for 1, 3, 6, and 40 days. We demonstrated that the transcription of the flagellar genes was activated in conjunction with sporangium formation. Eleven transcriptional start points of the flagellar genes were determined using the rapid amplification of cDNA 5' ends (RACE) procedure, which revealed the highly conserved promoter sequence CTCA(N15-17)GCCGAA. This result suggests that a sigma factor is responsible for the transcription of all flagellar genes and that the flagellar structure assembles simultaneously.

IMPORTANCE

The biology of a zoospore is very interesting from the viewpoint of morphogenesis, survival strategy, and evolution. Here, we analyzed flagellar genes in A. missouriensis, which produces sporangia containing hundreds of flagellated spores each. Zoospores released from the sporangia swim for a short time before germination occurs. We identified a large flagellar gene cluster and an orphan flagellar gene (fliQ). These findings indicate that the zoospore flagellar components are typical of Gram-positive bacteria. However, the transcriptional analysis revealed that all flagellar genes are transcribed simultaneously during sporangium formation, a pattern differing from the orderly, regulated expression of flagellar genes in other bacteria, such as Salmonella and Escherichia coli These results suggest a novel regulatory mechanism for flagellar formation in A. missouriensis.

Themes and Variations: Regulation of RpoN-Dependent Flagellar Genes across Diverse Bacterial Species

Flagellar biogenesis in bacteria is a complex process in which the transcription of dozens of structural and regulatory genes is coordinated with the assembly of the flagellum. Although the overall process of flagellar biogenesis is conserved among bacteria, the mechanisms used to regulate flagellar gene expression vary greatly among different bacterial species. Many bacteria use the alternative sigma factor σ (54) (also known as RpoN) to transcribe specific sets of flagellar genes. These bacteria include members of the Epsilonproteobacteria (e.g., Helicobacter pylori and Campylobacter jejuni), Gammaproteobacteria (e.g., Vibrio and Pseudomonas species), and Alphaproteobacteria (e.g., Caulobacter crescentus). This review characterizes the flagellar transcriptional hierarchies in these bacteria and examines what is known about how flagellar gene regulation is linked with other processes including growth phase, quorum sensing, and host colonization.

Direct interaction of FliX and FlbD is required for their regulatory activity in Caulobacter crescentus

BACKGROUND

The temporal and spatial expression of late flagellar genes in Caulobacter crescentus is activated by the transcription factor FlbD and its partner trans-acting factor FliX. The physical interaction of these two proteins represents an alternative mechanism for regulating the activity of σ54 transcription factors. This study is to characterize the interaction of the two proteins and the consequences of the interaction on their regulatory activity.

RESULTS

FliX and FlbD form stable complexes, which can stand the interference of 2.65 M NaCl. The stability of FliX and FlbD was affected by the co-existence of each other. Five FliX mutants (R71A, L85K, Δ117-118, T130L, and L136K) were created by site-directed mutagenesis in conserved regions of the protein. All mutants were successfully expressed in both wild-type and ΔfliX Caulobacter strains. All but FliXL85K could rescue the motility and cell division defects of a ΔfliX mutant strain. The ability of FliX to regulate the transcription of class II and class III/IV flagellar promoters was fully diminished due to the L85K mutation. Co-immunoprecipitation experiment revealed that FliXL85K was unable to physically interact with FlbD.

CONCLUSIONS

FliX interacts with FlbD and thereby directly regulates the activity of FlbD in response to flagellar assembly. Mutations in highly conserved regions of FliX could severely affect the recognition between FliX and FlbD and hence interrupt the normal progression of flagellar synthesis and other developmental events in Caulobacter.

Deciphering bacterial flagellar gene regulatory networks in the genomic era

Synthesis of the bacterial flagellum is a complex process involving dozens of structural and regulatory genes. Assembly of the flagellum is a highly-ordered process, and in most flagellated bacteria the structural genes are expressed in a transcriptional hierarchy that results in the products of these genes being made as they are needed for assembly. Temporal regulation of the flagellar genes is achieved through sophisticated regulatory networks that utilize checkpoints in the flagellar assembly pathway to coordinate expression of flagellar genes. Traditionally, flagellar transcriptional hierarchies are divided into various classes. Class I genes, which are the first genes expressed, encode a master regulator that initiates the transcriptional hierarchy. The master regulator activates transcription a set of structural and regulatory genes referred to as class II genes, which in turn affect expression of subsequent classes of flagellar genes. We review here the literature on the expression and activity of several known master regulators, including FlhDC, CtrA, VisNR, FleQ, FlrA, FlaK, LafK, SwrA, and MogR. We also examine the Department of Energy Joint Genomes Institute database to make predictions about the distribution of these regulators. Many bacteria employ the alternative sigma factors sigma(54) and/or sigma(28) to regulate transcription of later classes of flagellar genes. Transcription by sigma(54)-RNA polymerase holoenzyme requires an activator, and we review the literature on the sigma(54)-dependent activators that control flagellar gene expression in several bacterial systems, as well as make predictions about other systems that may utilize sigma(54) for flagellar gene regulation. Finally, we review the prominent systems that utilize sigma(28) and its antagonist, the anti-sigma(28) factor FlgM, along with some systems that utilize alternative mechanisms for regulating flagellar gene expression.

Comparative genomic evidence for a close relationship between the dimorphic prosthecate bacteria Hyphomonas neptunium and Caulobacter crescentus

The dimorphic prosthecate bacteria (DPB) are alpha-proteobacteria that reproduce in an asymmetric manner rather than by binary fission and are of interest as simple models of development. Prior to this work, the only member of this group for which genome sequence was available was the model freshwater organism Caulobacter crescentus. Here we describe the genome sequence of Hyphomonas neptunium, a marine member of the DPB that differs from C. crescentus in that H. neptunium uses its stalk as a reproductive structure. Genome analysis indicates that this organism shares more genes with C. crescentus than it does with Silicibacter pomeroyi (a closer relative according to 16S rRNA phylogeny), that it relies upon a heterotrophic strategy utilizing a wide range of substrates, that its cell cycle is likely to be regulated in a similar manner to that of C. crescentus, and that the outer membrane complements of H. neptunium and C. crescentus are remarkably similar. H. neptunium swarmer cells are highly motile via a single polar flagellum. With the exception of cheY and cheR, genes required for chemotaxis were absent in the H. neptunium genome. Consistent with this observation, H. neptunium swarmer cells did not respond to any chemotactic stimuli that were tested, which suggests that H. neptunium motility is a random dispersal mechanism for swarmer cells rather than a stimulus-controlled navigation system for locating specific environments. In addition to providing insights into bacterial development, the H. neptunium genome will provide an important resource for the study of other interesting biological processes including chromosome segregation, polar growth, and cell aging.

A phosphorelay system controls stalk biogenesis during cell cycle progression in Caulobacter crescentus

A fundamental question in developmental biology is how morphogenesis is coordinated with cell cycle progression. In Caulobacter crescentus, each cell cycle produces morphologically distinct daughter cells, a stalked cell and a flagellated swarmer cell. Construction of both the flagellum and stalk requires the alternative sigma factor RpoN (sigma(54)). Here we report that a sigma(54)-dependent activator, TacA, is required for cell cycle regulated stalk biogenesis by collaborating with RpoN to activate gene expression. We have also identified the first histidine phosphotransferase in C. crescentus, ShpA, and show that it too is required for stalk biogenesis. Using a systematic biochemical technique called phosphotransfer profiling we have identified a multicomponent phosphorelay which leads from the hybrid histidine kinase ShkA to ShpA and finally to TacA. This pathway functions in vivo to phosphorylate and hence, activate TacA. Finally, whole genome microarrays were used to identify candidate members of the TacA regulon, and we show that at least one target gene, staR, regulates stalk length. This is the first example of a general method for identifying the connectivity of a phosphorelay and can be applied to any organism with two-component signal transduction systems.

The trans-acting flagellar regulatory proteins, FliX and FlbD, play a central role in linking flagellar biogenesis and cytokinesis in Caulobacter crescentus

The FliX/FlbD-dependent temporal transcription of late flagellar genes inCaulobacter crescentusrequires the assembly of an early, class II-encoded flagellar structure. Class II flagellar-mutant strains exhibit a delay in the completion of cell division, with the accumulation of filamentous cells in culture. It is shown here that this cell-division defect is attributable to an arrest in the final stages of cell separation. Normal cell morphology could be restored in class II mutants by gain-of-function alleles of FliX or FlbD, suggesting that the timely completion of cell division requires thesetrans-acting factors. In synchronized cultures, inhibition of cell division by depleting FtsZ resulted in normal initial expression of the late, FlbD-dependentfliKgene; however, the cell cycle-regulated cessation of transcription was delayed, indicating that cell division may be required to negatively regulate FlbD activity. Interestingly, prolonged depletion of FtsZ resulted in an eventual loss of FlbD activity that could be bypassed by a constitutive mutant of FlbD, but not of FliX, suggesting the possible existence of a second cell cycle-dependent pathway for FlbD activation.

Linking structural assembly to gene expression: a novel mechanism for regulating the activity of a σ54transcription factor

In Caulobacter crescentus, the temporal and spatial expression of late flagellar genes is regulated by the sigma54 transcriptional activator, FlbD. Genetic experiments have indicated that the trans-acting factor FliX regulates FlbD in response to the progression of flagellar assembly, repressing FlbD activity until an early flagellar basal body structure is assembled. Following assembly of this structure, FliX is thought to function as an activator of FlbD. Here we have investigated the mechanism of FliX-mediated regulation of FlbD activity. In vitro transcription experiments showed that purified FliX could function as a repressor of FlbD-activated transcription. Transcription activated by a gain-of-function mutant of FlbD (FlbD-1204) that is active in vivo in the absence of an early flagellar structure, was resistant to the repressive effects of FliX. DNA binding studies showed that FliX inhibited the interaction of wild-type FlbD with enhancer DNA but did not effect FlbD-catalysed ATPase activity. DNA binding activity of FlbD-1204 was relatively unaffected by FliX indicating that this mutant protein bypasses the transcriptional requirement for early flagellar assembly by escaping FliX-mediated negative regulation. Gel filtration and co-immunoprecipitation experiments indicated that FliX formed a stable complex with FlbD. These experiments demonstrate that regulation of FlbD activity is unusual among the well-studied sigma54 transcriptional activators, apparently combining a two-component receiver domain with additional control imposed via interaction with a partner protein, FliX.

Regulation of FlbD activity by flagellum assembly is accomplished through direct interaction with the trans-acting factor, FliX

The temporal and spatial transcription of late flagellar genes in Caulobacter crescentus is regulated by the sigma54 transcriptional activator, FlbD. One requirement for FlbD activity is the assembly of a structure encoded by early, class II flagellar genes. In this report, we show that the trans-acting factor FliX predominantly functions as a negative regulator of FlbD activity in the absence of the class II-encoded flagellar structure. In contrast, a mutant FliX that bypasses the transcriptional requirement for early flagellar assembly is incapable of repressing FlbD in a class II flagellar mutant. Expression of this mutant allele, fliX1, does not alter the temporal pattern of FlbD-dependent transcription. Remarkably, this mutation confers the correct cell cycle timing of hook operon transcription in a strain that cannot assemble the flagellum, indicating that the progression of flagellar assembly is a minor influence on temporal gene expression. Using a two-hybrid assay, we present evidence that FliX regulates FlbD through a direct interaction, a novel mechanism for this class of sigma54 transcriptional activator. Furthermore, increasing the cellular levels of FliX results in an increase in the concentration of FlbD, and a corresponding increase in FlbD-activated transcription, suggesting that FliX and FlbD form a stable complex in Caulobacter. FliX and FlbD homologues are present in several polar-flagellated bacteria, indicating that these proteins constitute an evolutionarily conserved regulatory pair in organisms where flagellar biogenesis is likely to be under control of the cell division cycle.

Role of integration host factor in the transcriptional activation of flagellar gene expression in Caulobacter crescentus

In the Caulobacter crescentus predivisional cell, class III and IV flagellar genes, encoding the extracytoplasmic components of the flagellum, are transcribed in the nascent swarmer compartment. This asymmetric expression pattern is attributable to the compartmentalized activity of the sigma54-dependent transcriptional activator FlbD. Additionally, these temporally transcribed flagellar promoters possess a consensus sequence for the DNA-binding protein integration host factor (IHF), located between the upstream FlbD binding site and the promoter sequences. Here, we deleted the C. crescentus gene encoding the beta-subunit of the IHF, ihfB (himD), and examined the effect on flagellar gene expression. The DeltaihfB strain exhibited a mild defect in cell morphology and impaired motility. Using flagellar promoter reporter fusions, we observed that expression levels of a subset of class III flagellar promoters were decreased by the loss of IHF. However, one of these promoters, fliK-lacZ, exhibited a wild-type cell cycle-regulated pattern of expression in the absence of IHF. Thus, IHF is required for maximal transcription of several late flagellar genes. The DeltaihfB strain was found to express significantly reduced amounts of the class IV flagellin, FljL, as a consequence of reduced transcriptional activity. Our results indicate that the motility defect exhibited by the DeltaihfB strain is most likely attributable to its failure to accumulate the class IV-encoded 27-kDa flagellin subunit, FljL.

Transcription of sigma54-dependent but not sigma28-dependent flagellar genes in Campylobacter jejuni is associated with formation of the flagellar secretory apparatus

We performed a genetic analysis of flagellar regulation in Campylobacter jejuni, from which we elucidated key portions of the flagellar transcriptional cascade in this bacterium. For this study, we developed a reporter gene system for C. jejuni involving astA, encoding arylsulphatase, and placed astA under control of the sigma 54-regulated flgDE2 promoter in C. jejuni strain 81-176. The astA reporter fusion combined with transposon mutagenesis allowed us to identify genes in which insertions abolished flgDE2 expression; genes identified were on both the chromosome and the plasmid pVir. Included among the chromosomal genes were genes encoding a putative sensor kinase and the sigma 54-dependent transcriptional activator, FlgR. In addition, we identified specific flagellar genes, including flhA, flhB, fliP, fliR and flhF, that are also required for transcription of flgDE2 and are presumably at the beginning of the C. jejuni flagellar transcriptional cascade. Deletion of any of these genes reduced transcription of both flgDE2 and another sigma 54-dependent flagellar gene, flaB, encoding a minor flagellin. Transcription of the sigma 28-dependent gene flaA, encoding the major flagellin, was largely unaffected in the mutants. Further examination of flaA transcription revealed significant sigma 28-independent transcription and only weak repressive activity of the putative anti-sigma 28 factor FlgM. Our study suggests that sigma 54-dependent transcription of flagellar genes in C. jejuni is linked to the formation of the flagellar secretory apparatus. A key difference in the C. jejuni flagellar transcriptional cascade compared with other bacteria that use sigma 28 for transcription of flagellar genes is that a mechanism to repress significantly sigma 28-dependent transcription of flaA in flagellar assembly mutants is absent in C. jejuni.

The small RNA chaperone Hfq and multiple small RNAs control quorum sensing in Vibrio harveyi and Vibrio cholerae

Quorum-sensing bacteria communicate with extracellular signal molecules called autoinducers. This process allows community-wide synchronization of gene expression. A screen for additional components of the Vibrio harveyi and Vibrio cholerae quorum-sensing circuits revealed the protein Hfq. Hfq mediates interactions between small, regulatory RNAs (sRNAs) and specific messenger RNA (mRNA) targets. These interactions typically alter the stability of the target transcripts. We show that Hfq mediates the destabilization of the mRNA encoding the quorum-sensing master regulators LuxR (V. harveyi) and HapR (V. cholerae), implicating an sRNA in the circuit. Using a bioinformatics approach to identify putative sRNAs, we identified four candidate sRNAs in V. cholerae. The simultaneous deletion of all four sRNAs is required to stabilize hapR mRNA. We propose that Hfq, together with these sRNAs, creates an ultrasensitive regulatory switch that controls the critical transition into the high cell density, quorum-sensing mode.

Mutations in FlbD that relieve the dependency on flagellum assembly alter the temporal and spatial pattern of developmental transcription in Caulobacter crescentus

The transcription factor FlbD regulates the temporal and spatial transcription of flagellar genes in the bacterium Caulobacter crescentus. Activation of FlbD requires cell cycle progression and the assembly of an early (class II) flagellum structure. In this report, we identify 20 independent gain-of-function mutations in flbD that relieve regulation by flagellar assembly. One of these, flbD-1204, contained a mutation in the receiver domain (V17M) and another, flbD-1231, in the DNA binding domain (V451G). Both of these mutations resulted in an aberrant pattern of cell cycle transcription. The presence of the FlbD-1204 allele also resulted in a loss of swarmer-pole-specific transcription. These results indicate that temporal and spatial transcription is influenced by the assembly of the nascent flagellar structure. The trans-acting positive and negative regulatory factor, FliX, couples flagellar assembly to the activation of FlbD and, as we show here, also influences temporal transcription. Furthermore, we show that FliX can suppress the activity of FlbD mutants that cannot be phosphorylated, and that FliX is required for FlbD stability, and vice versa. These results indicate that FliX may interact directly with FlbD to regulate its activity.

Regulation of late flagellar gene transcription and cell division by flagellum assembly in Caulobacter crescentus

Biogenesis of the single polar flagellum of Caulobacter crescentus is regulated by a complex interplay of cell cycle events and the progression of flagellum assembly. The expression of class III/IV flagellar genes requires the assembly of an early flagellar basal body structure, encoded by class II genes, and is activated by the transcription factor FlbD. Previous experiments indicated that the class II flagellar gene, flbE, encoded a trans-acting factor that was required for FlbD activity. Here, using mutant alleles of flbE we have determined that FlbE is either a structural component of the flagellum or is required for flagellar assembly and does not, as originally proposed, function as a trans-acting factor. We also demonstrate that two deleted derivatives of flbE have a dominant negative effect on the transcriptional activation of class III/IV flagellar genes that can be relieved by a gain-of-function mutation in flbD called bfa. This same mutation in flbD has been shown to restore class III/IV transcription in the absence of early class II flagellar assembly. These deleted mutants of flbE also exhibited a filamentous cell phenotype that was indistinguishable from that previously observed in class II flagellar mutants. Introduction of a flbD-bfa mutation into these cells expressing the deleted alleles of flbE, as well as several class II mutant strains, restored normal cell division and FtsZ localization. These results suggest that class III/IV transcription and a step in cell division are coupled to flagellar assembly by the same genetic pathway.

The Caulobacter crescentus flagellar gene, fliX, encodes a novel trans-acting factor that couples flagellar assembly to transcription

The first flagellar assembly checkpoint of Caulobacter crescentus couples assembly of the early class II components of the basal body complex to the expression of class III and IV genes, which encode extracytoplasmic structures of the flagellum. The transcription of class III/IV flagellar genes is activated by the response regulator factor, FlbD. Gain of function mutations in flbD, termed bfa, can bypass the transcriptional requirement for the assembly of class II flagellar structures. Here we show that the class II flagellar gene fliX encodes a trans-acting factor that couples flagellar assembly to FlbD-dependent transcription. We show that the overexpression of fliX can suppress class III/IV gene expression in both wild-type and flbD-bfa cells. Introduction of a bfa allele of flbD into cells possessing a deletion in fliX restores motility indicating that FliX is not a structural component of the flagellum, but rather a trans-acting factor. Furthermore, extragenic motile suppressors which arise in DeltafliX cells map to the flbD locus. These results indicate that FlbD functions downstream of FliX in activating class III/IV transcription. beta-Lactamase fusions to FliX and analysis of cellular fractions demonstrate that FliX is a cytosolic protein that demonstrates some peripheral association with the cytoplasmic membrane. In addition, we have isolated a mutant allele of fliX that exhibits a bfa-like phenotype, restoring flbD-dependent class III/IV transcription in strains that contain mutations in class II flagellar structural genes. Taken together, these results indicated both a positive and negative regulatory function for FliX in coupling the assembly of class II basal body components to gene expression.

FlbT, the post-transcriptional regulator of flagellin synthesis in Caulobacter crescentus, interacts with the 5' untranslated region of flagellin mRNA

Flagellar gene expression' in Caulobacter crescentus is regulated by a complex trans-acting hierarchy, in which the assembly of early structural proteins is required for the expression of later structural proteins. The flagellins that comprise the filament are regulated at both the transcriptional and the post-transcriptional levels. Post-transcriptional regulation is sensitive to the assembly of the flagellar basal body and hook structures. In mutant strains lacking these structures, flagellin genes are transcribed, but not translated. Mutations in the flagellar regulatory gene, flbT, restore flagellin translation in the absence of flagellar assembly. In this report, we investigate the mechanism of FlbT-mediated post-transcriptional regulation. We show that FlbT is associated with the 5' untranslated region (UTR) of fljK (25 kDa flagellin) mRNA and that this association requires a predicted loop structure in the transcript. Mutations within this loop abolished FlbT association and resulted in increased mRNA stability, indicating that FlbT promotes the degradation of flagellin mRNA by associating with the 5' UTR. We also assayed the effects on gene expression using mutant transcripts fused to lacZ. Interestingly, the mutant transcript that failed to associate with FlbT in vitro was still repressed in mutants defective in flagellum assembly, suggesting that other factors in addition to FlbT couple assembly to translation.

Regulation of quorum sensing in Vibrio harveyi by LuxO and sigma-54

The bioluminescent marine bacterium Vibrio harveyi controls light production (lux) by an elaborate quorum-sensing circuit. V. harveyi produces and responds to two different autoinducer signals (AI-1 and AI-2) to modulate the luciferase structural operon (luxCDABEGH) in response to changes in cell-population density. Unlike all other Gram-negative quorum-sensing organisms, V. harveyi regulates quorum sensing using a two-component phosphorylation-dephosphorylation cascade. Each autoinducer is recognized by a cognate hybrid sensor kinase (called LuxN and LuxQ). Both sensors transduce information to a shared phosphorelay protein called LuxU, which in turn conveys the signal to the response regulator protein LuxO. Phospho-LuxO is responsible for repression of luxCDABEGH expression at low cell density. In the present study, we demonstrate that LuxO functions as an activator protein via interaction with the alternative sigma factor, sigma54 (encoded by rpoN). Our results suggest that LuxO, together with sigma54, activates the expression of a negative regulator of luminescence. We also show that phenotypes other than lux are regulated by LuxO and sigma54, demonstrating that in Vibrio harveyi, quorum sensing controls multiple processes.

Molecular characterization of two-component systems of Helicobacter pylori

Two-component systems are frequently involved in the adaptation of bacteria to changing environmental conditions at the level of transcriptional regulation. Here we report the characterization of members of the two-component systems of the gastric pathogen Helicobacter pylori deduced from the genome sequence of strain 26695. We demonstrate that the response regulators HP166, HP1043, and HP1021 have essential functions, as disruption of the corresponding genes is lethal for the bacteria, irrespective of the fact that HP1043 and HP1021 have nonconserved substitutions in crucial amino acids of their receiver domains. An analysis of the in vitro phosphorylation properties of the two-component proteins demonstrates that HP244-HP703 and HP165-HP166 are cognate histidine kinase-response regulator pairs. Furthermore, we provide evidence that the variability of the histidine kinase HP165 caused by a poly(C) tract of variable length close to the 3' end of open reading frame 165/164 does not interfere with the kinase activity of the transmitter domain of HP165.

FlbT couples flagellum assembly to gene expression in Caulobacter crescentus

The biogenesis of the polar flagellum of Caulobacter crescentus is regulated by the cell cycle as well as by a trans-acting regulatory hierarchy that functions to couple flagellum assembly to gene expression. The assembly of early flagellar structures (MS ring, switch, and flagellum-specific secretory system) is required for the transcription of class III genes, which encode the remainder of the basal body and the external hook structure. Similarly, the assembly of class III gene-encoded structures is required for the expression of the class IV flagellins, which are incorporated into the flagellar filament. Here, we demonstrate that mutations in flbT, a flagellar gene of unknown function, can restore flagellin protein synthesis and the expression of fljK::lacZ (25-kDa flagellin) protein fusions in class III flagellar mutants. These results suggest that FlbT functions to negatively regulate flagellin expression in the absence of flagellum assembly. Deletion analysis shows that sequences within the 5' untranslated region of the fljK transcript are sufficient for FlbT regulation. To determine the mechanism of FlbT-mediated regulation, we assayed the stability of fljK mRNA. The half-life (t(1/2)) of fljK mRNA in wild-type cells was approximately 11 min and was reduced to less than 1.5 min in a flgE (hook) mutant. A flgE flbT double mutant exhibited an mRNA t(1/2) of greater than 30 min. This suggests that the primary effect of FlbT regulation is an increased turnover of flagellin mRNA. The increased t(1/2) of fljK mRNA in a flbT mutant has consequences for the temporal expression of fljK. In contrast to the case for wild-type cells, fljK::lacZ protein fusions in the mutant are expressed almost continuously throughout the C. crescentus cell cycle, suggesting that coupling of flagellin gene expression to assembly has a critical influence on regulating cell cycle expression.

Regulated expression of a highly conserved regulatory gene cluster is necessary for controlling photosynthesis gene expression in response to anaerobiosis in Rhodobacter capsulatus

We utilized primer extension analysis to demonstrate that the divergently transcribed regB and senC-regA-hvrA transcripts contain stable 5' ends 43 nucleotides apart within the regB-senC intergenic region. DNA sequence analysis indicates that this region contains two divergent promoters with overlapping sigma70 type -35 and -10 promoter recognition sequences. In vivo analysis of expression patterns of regB::lacZ and senC-regA-hvrA::lacZ reporter gene fusions demonstrates that the regB and senC-regA-hvrA transcripts are both negatively regulated by the phosphorylated form of the global response regulator RegA. DNase I protection assays with a constitutively active variant of RegA indicate that RegA binds between regB and senC overlapping -10 and -35 promoter recognition sequences. Two mutations were also isolated in a regB-deficient background that increased expression of the senC-regA-hvrA operon 10- and 5-fold, respectively. As a consequence of increased RegA expression, these mutants exhibited elevated aerobic and anaerobic photosynthesis (puf) gene expression, even in the absence of the sensor kinase RegB. These results indicate that autoregulation by RegA is a factor contributing to the maintenance of an optimal low level of RegA expression that allows responsiveness to activation by phosphorylation.

Regulation of podJ expression during the Caulobacter crescentus cell cycle

The polar organelle development gene, podJ, is expressed during the swarmer-to-stalked cell transition of the Caulobacter crescentus cell cycle. Mutants with insertions that inactivate the podJ gene are nonchemotactic, deficient in rosette formation, and resistant to polar bacteriophage, but they divide normally. In contrast, hyperexpression of podJ results in a lethal cell division defect. Nucleotide sequence analysis of the podJ promoter region revealed a binding site for the global response regulator, CtrA. Deletion of this site results in increased overall promoter activity, suggesting that CtrA is a negative regulator of the podJ promoter. Furthermore, synchronization studies have indicated that temporal regulation is not dependent on the presence of the CtrA binding site. Thus, although the level of podJ promoter activity is dependent on the CtrA binding site, the temporal control of podJ promoter expression is dependent on other factors.

Protein localization during the Caulobacter crescentus cell cycle

New research on bacterial cells has demonstrated that they have a dynamic and complex subcellular organization. Work in Caulobacter crescentus shows that essential and nonessential proteins localize to discrete positions in the cell as a function of cell-cycle progression. The flagellum and chemotaxis receptor are asymmetrically localized to a single pole in the predivisional cell by coordinated proteolysis and transcriptional regulation. Cell type- and compartment-specific localization of the CtrA global transcriptional regulator is essential for proper cell-cycle progression, and subcellular localization of key chromosome partitioning proteins is correlated with proper nucleoid segregation. Given this structural complexity, we are driven to ask how localization is achieved, and to what end.

A membrane-associated protein, FliX, is required for an early step in Caulobacter flagellar assembly

The ordered assembly of the Caulobacter crescentus flagellum is accomplished in part through the organization of the flagellar structural genes in a regulatory hierarchy of four classes. Class II genes are the earliest to be expressed and are activated at a specific time in the cell cycle by the CtrA response regulator. In order to identify gene products required for early events in flagellar assembly, we used the known phenotypes of class II mutants to identify new class II flagellar genes. In this report we describe the isolation and characterization of a flagellar gene, fliX. A fliX null mutant is nonmotile, lacks a flagellum, and exhibits a marked cell division defect. Epistasis experiments placed fliX within class II of the flagellar regulatory hierarchy, suggesting that FliX functions at an early stage in flagellar assembly. The fliX gene encodes a 15-kDa protein with a putative N-terminal signal sequence. Expression of fliX is under cell cycle control, with transcription beginning relatively early in the cell cycle and peaking in Caulobacter predivisional cells. Full expression of fliX was found to be dependent on ctrA, and DNase I footprinting analysis demonstrated a direct interaction between CtrA and the fliX promoter. The fliX gene is located upstream and is divergently transcribed from the class III flagellar gene flgI, which encodes the basal body P-ring monomer. Analysis of the fliX-flgI intergenic region revealed an arrangement of cis-acting elements similar to that of another set of Caulobacter class II and class III flagellar genes, fliL-flgF, that is also divergently transcribed. In parallel with the FliL protein, FliX copurifies with the membrane fraction, and although its expression is cell cycle controlled, the protein is present throughout the cell cycle.

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.

A gene coding for a putative sigma 54 activator is developmentally regulated in Caulobacter crescentus

In Caulobacter crescentus, the alternative sigma factor sigma54 plays an important role in the expression of late flagellar genes. Sigma54-dependent genes are temporally and spatially controlled, being expressed only in the swarmer pole of the predivisional cell. The only sigma54 activator described so far is the FlbD protein, which is involved in activation of the class III and IV flagellar genes and repression of the fliF promoter. To identify new roles for sigma54 in the metabolism and differentiation of C. crescentus, we cloned and characterized a gene encoding a putative sigma54 activator, named tacA. The deduced amino acid sequence from tacA has high similarity to the proteins from the NtrC family of transcriptional activators, including the aspartate residues that are phosphorylated by histidine kinases in other activators. The promoter region of the tacA gene contains a conserved sequence element present in the promoters of class II flagellar genes, and tacA shows a temporal pattern of expression similar to the patterns of these genes. We constructed an insertional mutant that is disrupted in tacA (strain SP2016), and an analysis of this strain showed that it has all polar structures, such as pili, stalk, and flagellum, and displays a motile phenotype, indicating that tacA is not involved in the flagellar biogenesis pathway. However, this strain has a high percentage of filamentous cells and shows a clear-plaque phenotype when infected with phage phiCb5. These results suggest that the TacA protein could mediate the effect of sigma54 on a different pathway in C. crescentus.

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.

Cell type-specific phosphorylation and proteolysis of a transcriptional regulator controls the G1-to-S transition in a bacterial cell cycle

The global transcriptional regulator CtrA controls multiple events in the Caulobacter cell cycle, including the initiation of DNA replication, DNA methylation, cell division, and flagellar biogenesis. CtrA is a member of the response regulator family of two component signal transduction systems and is activated by phosphorylation. We report here that this phosphorylation signal enters the cell cycle at mid S phase. In addition, CtrA function is modulated by temporally and spatially controlled proteolysis. When an active CtrA protein is present at the wrong time in the cell cycle, owing to expression of a mutant CtrA derivative that is active in the absence of phosphorylation and is not turned over during the cell cycle, the G1-to-S transition is blocked and the cell cycle aborts. Thus, both phosphorylation and proteolysis are critical determinants of bacterial cell cycle control in a manner that is analogous to the control of the eukaryotic cell cycle.

Posttranscriptional regulation of Caulobacter flagellin genes by a late flagellum assembly checkpoint

Flagellum formation in Caulobacter crescentus requires ca. 50 flagellar genes, most of which belong to one of three classes (II, III, or IV). Epistasis experiments suggest that flagellar gene expression is coordinated with flagellum biosynthesis by two assembly checkpoints. Completion of the M/S ring-switch complex is required for the transition from class II to class III gene expression, and completion of the basal body-hook structure is required for the transition from class III to class IV gene expression. In studies focused on regulation of the class IV flagellin genes, we have examined fljK and fljL expression in a large number of flagellar mutants by using transcription and translation fusions to lacZ, nuclease S1 assays, and measurements of protein stability. The fljK-lacZ and fljL-lacZ transcription fusions were expressed in all class III flagellar mutants, although these strains do not make detectable 25- or 27-kDa flagellins. The finding that the fljK-lacZ translation fusion was not expressed in the same collection of class III mutants confirmed that fljK is regulated posttranscriptionally. The requirement of multiple class III genes for expression of the fljK-lacZ fusion suggests that completion of the basal body-hook is an assembly checkpoint for the posttranscriptional regulation of this flagellin gene. Deletion analysis within the 5' untranslated region of fljK identified a sequence between +24 and +38 required for regulation of the fljK-lacZ fusion by class III genes, which implicates an imperfect 14-bp direct repeat in the posttranscriptional regulation of fljK. Our results show that fljL is also regulated posttranscriptionally by class III and unclassified flagellar genes, apparently by a mechanism different from the one regulating fljK.

Identification of an asymmetrically localized sensor histidine kinase responsible for temporally and spatially regulated transcription

Caulobacter crescentus undergoes asymmetric cell division, resulting in a stalked cell and a motile swarmer cell. The genes encoding external components of the flagellum are expressed in the swarmer compartment of the predivisional cell through the localized activation of the transcription factor FlbD. The mechanisms responsible for the temporal and spatial activation of FlbD were determined through identification of FlbE, a histidine kinase required for FlbD activity. FlbE is asymmetrically distributed in the predivisional cell. It is located at the pole of the stalked compartment and at the site of cell division in the swarmer compartment. These findings suggest that FlbE and FlbD are activated in response to a morphological change in the cell resulting from cell division events.

The control of temporal and spatial organization during the Caulobacter cell cycle

The Caulobacter cell cycle exhibits time-dependent expression of differentiation events. These include the morphological transition of a swarmer cell to a replication-competent stalked cell and the subsequent polarized distribution of specific gene products that results in an asymmetric predivisional cell. Cell division then yields a new swarmer cell and a stem-cell-like stalked cell. Two-component signal transduction proteins involved in cell cycle control and proteins required for cell division and flagellar biogenesis have been shown to be regulated temporally and spatially during the cell cycle. The mechanisms underlying this regulation include protein phosphorylation and proteolysis.

Vibrio parahaemolyticus FlaJ, a homologue of FliS, is required for production of a flagellin

The flaA locus of Vibrio parahaemolyticus encodes one of the four polar flagellin genes, the flagellum-capping protein HAP2, and three additional flagellar genes. Sequence analysis downstream of the gene encoding HAP2 revealed the region to be similar to the fliD (HAP2) locus of Pseudomonas aeruginosa. The deduced protein sequences for the newly identified genes suggest that one protein belongs to the family of transcriptional regulatory proteins known to interact with sigma (54), one may be a rod component of the flagellum, and one resembles the FliS protein. fliS is an essential flagellar gene in many bacteria; however its function is not clear. The V. parahaemolyticus polar flaC flagellin gene was poorly expressed in Escherichia coli Production of FlaC was stimulated by provision of the flaA locus in trans. Dissection of this locus revealed that the fliS-like gene, flaJ, was required for increased expression of flaC. Stimulation by FlaJ occurred in E.coli mutants defective in either the master flagellar-controlling operon or the gene encoding the flagellar sigma (28). Therefore the effect of FlaJ was not mediated through flagellar proteins. Nor was it mediated through sigma (54) for enhanced FlaC production was observed in mutants with defects in the gene encoding sigma (54).

Isolation, identification, and transcriptional specificity of the heat shock sigma factor sigma32 from Caulobacter crescentus

We report the identification of the Caulobacter crescentus heat shock factor sigma32 as a 34-kDa protein that copurifies with the RNA polymerase holoenzyme. The N-terminal amino acid sequence of this protein was determined and used to design a degenerate oligonucleotide as a probe to identify the corresponding gene, rpoH, which encodes a predicted protein with a molecular mass of 33,659 Da. The amino acid sequence of this protein is similar to those of known bacterial heat shock sigma factors of Escherichia coli (41% identity), Pseudomonas aeruginosa (40% identity), and Citrobacter freundii (38% identity). The isolated C. crescentus gene complements the growth defect of an E. coli rpoH deletion strain at 37 degrees C, and Western blot (immunoblot) analysis confirmed that the gene product is related to the E. coli sigma32 protein. The purified RpoH protein in the presence of RNA polymerase core enzyme specifically recognizes the heat shock-regulated promoter P1 of the C. crescentus dnaK gene, and base pair substitutions in either the -10 or -35 region of this promoter abolish transcription. S1 nuclease mapping indicates that rpoH transcripts originate from two promoters, P1 and P2, under the normal growth conditions. The P2 promoter is similar to the sigma32 promoter consensus, and the P2-specific transcript increases dramatically during heat shock, while the P1-specific transcript remains relatively constant. These results suggest that although the structure and function of C. crescentus sigma32 appear to be very similar to those of its E. coli counterpart, the C. crescentus rpoH gene contains a novel promoter structure and may be positively autoregulated in response to environmental stress.

Temporal and spatial regulation of fliP, an early flagellar gene of Caulobacter crescentus that is required for motility and normal cell division

In Caulobacter crescentus, the genes encoding a single polar flagellum are expressed under cell cycle control. In this report, we describe the characterization of two early class II flagellar genes contained in the orfX-fliP locus. Strains containing mutations in this locus exhibit a filamentous growth phenotype and fail to express class III and IV flagellar genes. A complementing DNA fragment was sequenced and found to contain two potential open reading frames. The first, orfX, is predicted to encode a 105-amino-acid polypeptide that is similar to MopB, a protein which is required for both motility and virulence in Erwinia carotovora. The deduced amino acid sequence of the second open reading frame, fliP, is 264 amino acids in length and shows significant sequence identity with the FliP protein of Escherichia coli as well as virulence proteins of several plant and mammalian pathogens. The FliP homolog in pathogenic organisms has been implicated in the secretion of virulence factors, suggesting that the export of virulence proteins and some flagellar proteins share a common mechanism. The 5' end of orfX-fliP mRNA was determined and revealed an upstream promoter sequence that shares few conserved features with that of other early Caulobacter flagellar genes, suggesting that transcription of orfX-fliP may require a different complement of trans-acting factors. In C. crescentus, orfX-fliP is transcribed under cell cycle control, with a peak of transcriptional activity in the middle portion of the cell cycle. Later in the cell cycle, orfX-fliP expression occurs in both poles of the predivisional cell. Protein fusions to a lacZ reporter gene indicate that FliP is specifically targeted to the swarmer compartment of the predivisional cell.

Global regulation of a sigma 54-dependent flagellar gene family in Caulobacter crescentus by the transcriptional activator FlbD

Biosynthesis of the Caulobacter crescentus polar flagellum requires the expression of a large number of flagellar (fla) genes that are organized in a regulatory hierarchy of four classes (I to IV). The timing of fla gene expression in the cell cycle is determined by specialized forms of RNA polymerase and the appearance and/or activation of regulatory proteins. Here we report an investigation of the role of the C. crescentus transcriptional regulatory protein FlbD in the activation of sigma 54-dependent class III and class IV fla genes of the hierarchy by reconstituting transcription from these promoters in vitro. Our results demonstrate that transcription from promoters of the class III genes flbG, flgF, and flgI and the class IV gene fliK by Escherichia coli E sigma 54 is activated by FlbD or the mutant protein FlbDS140F (where S140F denotes an S-to-F mutation at position 140), which we show here has a higher potential for transcriptional activation. In vitro studies of the flbG promoter have shown previously that transcriptional activation by the FlbD protein requires ftr (ftr for flagellar transcription regulation) sequence elements. We have now identified multiple ftr sequences that are conserved in both sequence and spatial architecture in all known class III and class IV promoters. These newly identified ftr elements are positioned ca. 100 bp from the transcription start sites of each sigma 54-dependent fla gene promoter, and our studies indicate that they play an important role in controlling the levels of transcription from different class III and class IV promoters. We have also used mutational analysis to show that the ftr sequences are required for full activation by the FlbD protein both in vitro and in vivo. Thus, our results suggest that FlbD, which is encoded by the class II flbD gene, is a global regulator that activates the cell cycle-regulated transcription from all identified sigma 54-dependent promoters in the C. crescentus fla gene hierarchy.

A mutation that uncouples flagellum assembly from transcription alters the temporal pattern of flagellar gene expression in Caulobacter crescentus

The transcription of flagellar genes in Caulobacter crescentus is regulated by cell cycle events that culminate in the synthesis of a new flagellum once every cell division. Early flagellar gene products regulate the expression of late flagellar genes at two distinct stages of the flagellar trans-acting hierarchy. Here we investigate the coupling of early flagellar biogenesis with middle and late flagellar gene expression. We have isolated mutants (bfa) that do not require early class II flagellar gene products for the transcription of middle or late flagellar genes. bfa mutant strains are apparently defective in a negative regulatory pathway that couples early flagellar biogenesis to late flagellar gene expression. The bfa regulatory pathway functions solely at the level of transcription. Although flagellin promoters are transcribed in class II/bfa double mutants, there is no detectable flagellin protein on immunoblots prepared from mutant cell extracts. This finding suggests that early flagellar biogenesis is coupled to gene expression by two distinct mechanisms: one that negatively regulates transcription, mediated by bfa, and another that functions posttranscriptionally. To determine whether bfa affects the temporal pattern of late flagellar gene expression, cell cycle experiments were performed in bfa mutant strains. In a bfa mutant strain, flagellin expression fails to shut off at its normal time in the cell division cycle. This experimental result indicates that bfa may function as a regulator of flagellar gene transcription late in the cell cycle, after early flagellar structures have been assembled.

The control of asymmetric gene expression during Caulobacter cell differentiation

The dimorphic bacterium Caulobacter crescentus provides a simple model for cellular differentiation. Each cell division produces two distinct cell types: a swarmer cell and a stalked cell. These cells possess distinct functional morphologies and differential programs of transcription and DNA replication. The synthesis of a single polar flagellum is restricted to the swarmer pole of the predivisional cell by a genetic hierarchy comprising at least 50 genes whose transcription is regulated by novel and ubiquitous promoters, cognate sigma factors, and auxiliary transcriptional regulators. Chromosome replication is restricted to the stalked cell by a unique chromosome origin of replication that may be regulated by a novel cell-specific transcriptional control system. Phosphorylation signals, DNA methylation, differential chromosome structures, protein targeting, and selective protein degradation are also involved in establishing and maintaining cellular asymmetry. The molecular details of these universal cellular processes in C. crescentus will provide paradigms applicable to many general aspects of cellular differentiation.

Activation of a temporally regulated Caulobacter promoter by upstream and downstream sequence elements

The flagellar genes of Caulobacter crescentus are expressed under cell-cycle control. Expression is regulated by both flagellar assembly cues and cell-cycle events. In this paper we define the sequences required for the expression of the flgF operon, a new class of sigma 54 flagellar promoter. This promoter type is expressed in the middle portion of the cell cycle and regulates the expression of basal-body genes. DNase I footprinting and mutagenesis demonstrates that an integration host factor (IHF)-binding site is required for maximal levels of transcription of the flgF promoter. In addition to containing a conventional upstream enhancer element (RE-1), this promoter is unusual in that it also requires sequences (element RE-2) immediately downstream of the transcriptional start site for maximal levels of gene expression. Cell-cycle experiments indicate that RE-1 and RE-2 contribute equally to the regulation of temporal transcription. The presence of two intact elements in the promoter results in a fourfold increase in promoter activity compared with a promoter containing only one intact element, suggesting that these two elements may function synergistically to activate transcription.

Regulation of the Caulobacter crescentus rpoN gene and function of the purified sigma 54 in flagellar gene transcription

The sequential transcription of flagellar (fla) genes in the Caulobacter crescentus cell cycle is controlled by the organization of these genes in a regulatory hierarchy of four levels (I-IV). Level III and level IV genes at the bottom of the hierarchy are dependent on level II genes and are transcribed late in the cell cycle from sigma 54-dependent promoters. To study the regulation of genes at levels III and IV, we have isolated and sequenced the rpoN gene in order to analyze its expression, purified the rpoN gene product, and examined the role of the RpoN protein in initiation of transcription from sigma 54-dependent promoters. We report here epistasis experiments that show rpoN is required for transcription of level III genes, but that the expression of the rpoN gene itself is not dependent on any of the fla genes examined; these results place rpoN at level II near the top of the hierarchy. Consistent with this conclusion were nuclease S1 assays that mapped the rpoN transcription start site and identified a sequence centered at -24, GTTA/TACCA/TT, which is similar to the core consensus sequence of the level IIB fliF, fliL, and fliQ promoters. We purified the full-length rpoN gene product to near homogeneity and demonstrated that the RpoN protein is required for transcription from the well-characterized sigma 54-dependent glnAp2 promoter of Escherichia coli and specifically recognizes the level III flbG gene promoter of C. crescentus. These last results confirm that rpoN encodes the C. crescentus sigma 54 factor and opens the way for the biochemical analysis of transcriptional regulation of level III and IV fla genes.

Regulation of cellular differentiation in Caulobacter crescentus

In Caulobacter crescentus, asymmetry is generated in the predivisional cell, resulting in the formation of two distinct cell types upon cell division: a motile swarmer cell and a sessile stalked cell. These progeny cell types differ in their relative programs of gene expression and DNA replication. In progeny swarmer cells, DNA replication is silenced for a defined period, but stalked cells reinitiate chromosomal DNA replication immediately following cell division. The establishment of these differential programs of DNA replication may be due to the polar localization of DNA replication proteins, differences in chromosome higher-order structure, or pole-specific transcription. The best-understood aspect of Caulobacter development is biogenesis of the polar flagellum. The genes encoding the flagellum are expressed under cell cycle control predominantly in the predivisional cell type. Transcription of flagellar genes is regulated by a trans-acting hierarchy that responds to both flagellar assembly and cell cycle cues. As the flagellar genes are expressed, their products are targeted to the swarmer pole of the predivisional cell, where assembly occurs. Specific protein targeting and compartmentalized transcription are two mechanisms that contribute to the positioning of flagellar gene products at the swarmer pole of the predivisional cell.

Caulobacter FliQ and FliR membrane proteins, required for flagellar biogenesis and cell division, belong to a family of virulence factor export proteins

The Caulobacter crescentus fliQ and fliR genes encode membrane proteins that have a role in an early step of flagellar biogenesis and belong to a family of proteins implicated in the export of virulence factors. These include the MopD and MopE proteins from Erwinia carotovora, the Spa9 and Spa29 proteins from Shigella flexneri, and the YscS protein from Yersinia pestis. Inclusion in this family of proteins suggests that FliQ and FliR may participate in an export pathway required for flagellum assembly. In addition, mutations in either fliQ or fliR exhibit defects in cell division and thus may participate directly or indirectly in the division process. fliQ and fliR are class II flagellar genes residing near the top of the regulatory hierarchy that determines the order of flagellar gene transcription. The promoter sequence of the fliQR operon differs from most known bacterial promoter sequences but is similar to other Caulobacter class II flagellar gene promoter sequences. The conserved nucleotides in the promoter region are clustered in the -10, -20 to -30, and -35 regions. The importance of the conserved bases for promoter activity was demonstrated by mutational analysis. Transcription of the fliQR operon is initiated at a specific time in the cell cycle, and deletion analysis revealed that the minimal sequence required for transcriptional activation resides within 59 bp of the start site.

Multiple structural proteins are required for both transcriptional activation and negative autoregulation of Caulobacter crescentus flagellar genes

The periodic and sequential expression of flagellar (fla) genes in the Caulobacter crescentus cell cycle depends on their organization into levels I to IV of a regulatory hierarchy in which genes at the top of the hierarchy are expressed early in the cell cycle and are required for the later expression of genes below them. In these studies, we have examined the regulatory role of level II fliF operon, which is located near the top of the hierarchy. The last gene in the fliF operon, flbD, encodes a transcriptional factor required for activation of sigma 54-dependent promoters at levels III and IV and negative autoregulation of the level II fliF promoter. We have physically mapped the fliF operon, identified four new genes in the transcription unit, and determined that the organization of these genes is 5'-fliF-fliG-flbE-fliN-flbD-3'. Three of the genes encode homologs of the MS ring protein (FliF) and two switch proteins (FliG and FliN) of enteric bacteria, and the fourth encodes a predicted protein (FlbE) without obvious similarities to known bacterial proteins. We have introduced nonpolar mutations in each of the open reading frames and shown that all of the newly identified genes (fliF, fliG, flbE, and fliN) are required in addition to flbD for activation of the sigma 54-dependent flgK and flbG promoters at level III. In contrast, fliF, fliG, and flbE, but not fliN, are required in addition to flbD for negative autoregulation of the level II fliF promoter. The simplest interpretation of these results is that the requirements of FlbD in transcriptional activation and repression are not identical, and we speculate that FlbD function is subject to dual or overlapping controls. We also discuss the requirement of multiple structural genes for regulation of levels II and III genes and suggest that fla gene expression in C. crescentus may be coupled to two checkpoints in flagellum assembly.

FlbD has a DNA-binding activity near its carboxy terminus that recognizes ftr sequences involved in positive and negative regulation of flagellar gene transcription in Caulobacter crescentus

FlbD is a transcriptional regulatory protein that negatively autoregulates fliF, and it is required for expression of other Caulobacter crescentus flagellar genes, including flaN and flbG. In this report we have investigated the interaction between carboxy-terminal fragments of FlbD protein and enhancer-like ftr sequences in the promoter regions of fliF, flaN, and flbG. FlbDc87 is a glutathione S-transferase (GST)-FlbD fusion protein that carries the carboxy-terminal 87 amino acids of FlbD, and FlbDc87 binds to restriction fragments containing the promoter regions of fliF, flaN, and flbG, whereas a GST-FlbD fusion protein carrying the last 48 amino acids of FlbD failed to bind to these promoter regions. DNA footprint analysis demonstrated that FlbDc87 is a sequence-specific DNA-binding protein that makes close contact with 11 nucleotides in ftr4, and 6 of these nucleotides were shown previously to function in negative regulation of fliF transcription in vivo (S. M. Van Way, A. Newton, A. H. Mullin, and D. A. Mullin, J. Bacteriol. 175:367-376, 1993). Three DNA fragments, each carrying an ftr4 mutation that resulted in elevated fliF transcript levels in vivo, were defective in binding to FlbDc87 in vitro. We also found that a missense mutation in the recognition helix of the putative helix-turn-helix DNA-binding motif of FlbDc87 resulted in defective binding to ftr4 in vitro. These data suggest that the binding of FlbDc87 to ftr4 is relevant to negative transcriptional regulation of fliF and that FlbD functions directly as a repressor. Footprint analysis showed that FlbDc87 also makes close contacts with specific nucleotides in ftr1, ftr2, and ftr3 in the flaN-flbG promoter region, and some of these nucleotides were shown previously to be required for regulated transcription of flaN and flbG (D. A. Mullin and A. Newton, J. Bacteriol. 175:2067-2076, 1993). Footprint analysis also revealed a new ftr-like sequence, ftr5, at -136 from the transcription start site of flbG. Our results demonstrate that FlbD contains a sequence-specific DNA-binding activity within the 87 amino acids at its carboxy terminus, and the results suggest that FlbD exerts its effect as a positive and negative regulator of C. crescentus flagellar genes by binding to ftr sequences.