Genetic control of the bacterial flagellar regulon

Assembly of the bacterial type III secretion machinery

Many bacteria that live in contact with eukaryotic hosts, whether as symbionts or as pathogens, have evolved mechanisms that manipulate host cell behaviour to their benefit. One such mechanism, the type III secretion system, is employed by Gram-negative bacterial species to inject effector proteins into host cells. This function is reflected by the overall shape of the machinery, which resembles a molecular syringe. Despite the simplicity of the concept, the type III secretion system is one of the most complex known bacterial nanomachines, incorporating one to more than hundred copies of up to twenty different proteins into a multi-MDa transmembrane complex. The structural core of the system is the so-called needle complex that spans the bacterial cell envelope as a tripartite ring system and culminates in a needle protruding from the bacterial cell surface. Substrate targeting and translocation are accomplished by an export machinery consisting of various inner membrane embedded and cytoplasmic components. The formation of such a multimembrane-spanning machinery is an intricate task that requires precise orchestration. This review gives an overview of recent findings on the assembly of type III secretion machines, discusses quality control and recycling of the system and proposes an integrated assembly model.

The bacterial flagella motor

The bacterial flagellum is probably the most complex organelle found in bacteria. Although the ribosome may be made of slightly more subunits, the bacterial flagellum is a more organized and complex structure. The limited number of flagella must be targeted to the correct place on the cell membrane and a structure with cytoplasmic, cytoplasmic membrane, outer membrane and extracellular components must be assembled. The process of controlled transcription and assembly is still not fully understood. Once assembled, the motor complex in the cytoplasmic membrane rotates, driven by the transmembrane ion gradient, at speeds that can reach many 100 Hz, driving the bacterial cell at several body lengths a second. This coupling of an electrochemical gradient to mechanical rotational work is another fascinating feature of the bacterial motor. A significant percentage of a bacterium's energy may be used in synthesizing the complex structure of the flagellum and driving its rotation. Although patterns of swimming may be random in uniform environments, in the natural environment, where cells are confronted with gradients of metabolites and toxins, motility is used to move bacteria towards their optimum environment for growth and survival. A sensory system therefore controls the switching frequency of the rotating flagellum. This review deals primarily with the structure and operation of the bacterial flagellum. There has been a great deal of research in this area over the past 20 years and only some of this has been included. We apologize in advance if certain areas are covered rather thinly, but hope that interested readers will look at the excellent detailed reviews on those areas cited at those points.

Cloning and characterization of the Helicobacter pylori flbA gene, which codes for a membrane protein involved in coordinated expression of flagellar genes

Flagellar motility has been shown to be an essential requirement for the ability of Helicobacter pylori to colonize the gastric mucosa. While some flagellar structural components have been studied in molecular detail, nothing was known about factors that play a role in the regulation of flagellar biogenesis. We have cloned and characterized an H. pylori homolog (named flbA) of the lcrD/flbF family of genes. Many proteins encoded by these genes are known to be involved in flagellar biogenesis or secretion of virulence-associated proteins via type III secretion systems. The H. pylori flbA gene (2,196 bp) is capable of coding for a predicted 732-amino-acid, 80.9-kDa protein that has marked sequence similarity with other known members of the LcrD/FlbF protein family. An isogenic strain with a mutation in the flbA gene was constructed by disruption of the gene with a kanamycin resistance cassette and electroporation-mediated allelic exchange mutagenesis. The mutant strain expressed neither the FlaA nor the FlaB flagellin protein. The expression of the FlgE hook protein was reduced in comparison with the wild-type strain, and the extent of this reduction was growth phase dependent. The flbA gene disruption was shown to downregulate the expression of these flagellar genes on the transcriptional level. The flbA mutants were aflagellate and completely nonmotile. Occasionally, assembled hook structures could be observed, indicating that export of axial flagellar filament components was still possible in the absence of the flbA gene product. The hydrophilic part of the FlbA protein was expressed in Escherichia coli, purified, and used to raise a polyclonal rabbit antiserum against the FlbA protein. Western blot experiments with this antiserum indicated that the FlbA protein is predominantly associated with the cytoplasmic membrane in H. pylori. The antiserum cross-reacted with two other proteins (97 and 43 kDa) whose expression was not affected by the flbA gene disruption and which might represent further H. pylori homologs of the LcrD/FlbF protein family.

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.

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.

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.

An unusual promoter controls cell-cycle regulation and dependence on DNA replication of the Caulobacter fliLM early flagellar operon

Transcription of flagellar genes in Caulobacter crecentus is programmed to occur during the predivisional stage of the cell cycle. The mechanism of activation of Class II flagellar genes, the highest identified genes in the Caulobacter flagellar hierarchy, is unknown. As a step toward understanding this process, we have defined cis-acting sequences necessary for expression of a Class II flagellar operon, fliLM. Deletion analysis indicated that a 55 bp DNA fragment was sufficient for normal, temporally regulated promoter activity. Transcription from this promoter-containing fragment was severely reduced when chromosomal DNA replication was inhibited. Extensive mutational analysis of the promoter region from -42 to -5 identified functionally important nucleotides at -36 and -35, between -29 and -22, and at -12, which correlates well with sequences conserved between fliLM and the analogous regions of two other Class II flagellar operons. The promoter sequence does not resemble that recognized by any known bacterial sigma factor. Models for regulation of Caulobacter early flagellar promoters are discussed in which RNA polymerase containing a novel sigma subunit interacts with an activation factor bound to the central region of the promoter.

Organization and ordered expression of Caulobacter genes encoding flagellar basal body rod and ring proteins

The biogenesis of the polar flagellum in Caulobacter crescentus is limited to a specific time in the cell cycle and to a specific site on the cell. The basal body is the first part of the flagellum to be assembled. In this report we identify a cluster of genes encoding basal body components and describe their transcriptional regulation. The genes in this cluster form an operon whose expression is controlled temporally. The first two genes encode homologs of FlgF and FlgG, which are the proximal and distal rod proteins, respectively. The sequences of the N and C termini of the Salmonella typhimurium flagellar axial proteins, rod, hook and HAP-1, known to be highly conserved, share a high degree of sequence identity with the FlgF and FlgG rod proteins of the distantly related, C. crescentus. Two additional genes in the flgF, flgG operon, flaD and flgH, both encode proteins with potentially cleavable signal sequences. The flgH gene, encoding the L-ring protein, is also transcribed from an internal promoter. Transcription from the flgF promoter initiates prior to initiation at the internal flgH promoter. The internal promoter and its activator site reside within the C-terminal coding sequence of the upstream flaD gene. This type of gene overlap is also observed in bacterial genes involved in cell division. Flagellum biogenesis, like cell division, is a morphogenic event that requires the orderly assembly of component proteins and the overlapping gene organization may affect this "ordering" of assembly. The promoters for the flgF operon and the flgH gene use sigma 54 to initiate transcription. The use of sigma 54 promoters, known to require cognate binding proteins, could allow the fine-tuning that provides the temporal ordering of flagellar gene transcription. In this context, we have found that the flgF operon and the distal flgI gene encoding the P-ring, share a sigma 54 activator sequence (class IIA) that differs from the flgH L-ring gene sigma 54 activator site (class IIB) and the hook cluster (class IIC) sigma 54 activator site. The sequential activation of these three subgroups of structural genes reflects the order of assembly of their gene products into the flagellum.