Synthesis and assembly of flagellar components by Caulobacter crescentus motility mutants

Mutations in Sugar-Nucleotide Synthesis Genes Restore Holdfast Polysaccharide Anchoring to Caulobacter crescentus Holdfast Anchor Mutants

Attachment is essential for microorganisms to establish interactions with both biotic and abiotic surfaces. Stable attachment of Caulobacter crescentus to surfaces requires an adhesive polysaccharide holdfast, but the exact composition of the holdfast is unknown. The holdfast is anchored to the cell envelope by outer membrane proteins HfaA, HfaB, and HfaD. Holdfast anchor gene mutations result in holdfast shedding and reduced cell adherence. Translocation of HfaA and HfaD to the cell surface requires HfaB. The Wzx homolog HfsF is predicted to be a bacterial polysaccharide flippase. An hfsF deletion significantly reduced the amount of holdfast produced per cell and slightly reduced adherence. A ΔhfsF ΔhfaD double mutant was completely deficient in adherence. A suppressor screen that restored adhesion in the ΔhfsF ΔhfaD mutant identified mutations in three genes: wbqV, rfbB, and rmlA Both WbqV and RfbB belong to a family of nucleoside-diphosphate epimerases, and RmlA has similarity to nucleotidyltransferases. The loss of wbqV or rfbB in the ΔhfsF ΔhfaD mutant reduced holdfast shedding but did not restore holdfast synthesis to parental levels. Loss of wbqV or rfbB did not restore adherence to a ΔhfsF mutant but did restore adherence and holdfast anchoring to a ΔhfaD mutant, confirming that suppression occurs through restoration of holdfast anchoring. The adherence and holdfast anchoring of a ΔhfaA ΔhfaD mutant could be restored by wbqV or rfbB mutation, but such mutations could not suppress these phenotypes in the ΔhfaB mutant. We hypothesize that HfaB plays an additional role in holdfast anchoring or helps to translocate an unknown factor that is important for holdfast anchoring.IMPORTANCE Biofilm formation results in increased resistance to both environmental stresses and antibiotics. Caulobacter crescentus requires an adhesive holdfast for permanent attachment and biofilm formation, but the exact mechanism of polysaccharide anchoring to the cell and the holdfast composition are unknown. Here we identify novel polysaccharide genes that affect holdfast anchoring to the cell. We identify a new role for the holdfast anchor protein HfaB. This work increases our specific knowledge of the polysaccharide adhesin involved in Caulobacter attachment and the general knowledge regarding production and anchoring of polysaccharide adhesins by bacteria. This work also explores the interactions between different polysaccharide biosynthesis and secretion systems in bacteria.

Flagellar glycosylation - a new component of the motility repertoire?

The biosynthesis, assembly and regulation of the flagellar apparatus has been the subject of extensive studies over many decades, with considerable attention devoted to the peritrichous flagella of Escherichia coli and Salmonella enterica. The characterization of flagellar systems from many other bacterial species has revealed subtle yet distinct differences in composition, regulation and mode of assembly of this important subcellular structure. Glycosylation of the major structural protein, the flagellin, has been shown most recently to be an important component of numerous flagellar systems in both Archaea and Bacteria, playing either an integral role in assembly or for a number of bacterial pathogens a role in virulence. This review focuses on the structural diversity in flagellar glycosylation systems and demonstrates that as a consequence of the unique assembly processes, the type of glycosidic linkage found on archaeal and bacterial flagellins is distinctive.

The conserved flaF gene has a critical role in coupling flagellin translation and assembly in Caulobacter crescentus

The expression of the flagellin proteins in Caulobacter crescentus is regulated by the progression of flagellar assembly both at the transcriptional and post-transcriptional levels. An early basal body structure is required for the transcription of flagellin genes, whereas the ensuing assembly of a hook structure is required for flagellin protein synthesis. Previous experiments have shown that the negative regulatory protein, FlbT, operates this second post-transcriptional checkpoint by associating with the 5' untranslated region (UTR) of the fljK flagellin transcript, inhibiting translation and destabilizing the mRNA. In this paper we examine the role of flaF in flagellar biogenesis. The flaF gene, which is conserved in several speices of flagellated alpha-proteobacteria, is required for motility and flagellin protein synthesis. A deletion of flbT in a DeltaflaF strain restored flagellin protein expression, but not motility, indicating that FlaF functions in filament assembly. Mutant strains with a deletion in flaF had no detectable fljK mRNA, the levels of which were restored by an additional mutation in flbT. Assay of fljK gene expression using transcription and translation reporter fusions indicated that FlaF was essential for the translation of fljK mRNA. FlaF protein levels were under cell cycle control, peaking during the period of flagellin expression and filament assembly, whereas FlbT was present throughout the cell cycle. These results suggest that FlbT and FlaF activities oppose one another in the regulation of flagellin expression in response to both the progression of flagellar assembly and the cell cycle.

Pseudaminic acid, the major modification on Campylobacter flagellin, is synthesized via the Cj1293 gene

Flagellins from Campylobacter jejuni 81-176 and Campylobacter coli VC167 are heavily glycosylated. The major modifications on both flagellins are pseudaminic acid (Pse5Ac7Ac), a nine carbon sugar that is similar to sialic acid, and an acetamidino-substituted analogue of pseudaminic acid (PseAm). Previous data have indicated that PseAm is synthesized via Pse5Ac7Ac in C. jejuni 81-176, but that the two sugars are synthesized using independent pathways in C. coli VC167. The Cj1293 gene of C. jejuni encodes a putative UDP-GlcNAc C6-dehydratase/C4-reductase that is similar to a protein required for glycosylation of Caulobacter crescentus flagellin. The Cj1293 gene is expressed either under the control of a sigma 54 promoter that overlaps the coding region of Cj1292 or as a polycistronic message under the control of a sigma 70 promoter upstream of Cj1292. A mutant in gene Cj1293 in C. jejuni 81-176 was non-motile and non-flagellated and accumulated unglycosylated flagellin intracellularly. This mutant was complemented in trans with the homologous C. jejuni gene, as well as the Helicobacter pylori homologue, HP0840, which has been shown to encode a protein with UDP-GlcNAc C6-dehydratase/C4-reductase activity. Mutation of Cj1293 in C. coli VC167 resulted in a fully motile strain that synthesized a flagella filament composed of flagellin in which Pse5Ac7Ac was replaced by PseAm. The filament from the C. coli Cj1293 mutant displayed increased solubility in SDS compared with the wild-type filament. A double mutant in C. coli VC167, defective in both Cj1293 and ptmD, encoding part of the independent PseAm pathway, was also non-motile and non-flagellated and accumulated unglycosylated flagellin intracellularly. Collectively, the data indicate that Cj1293 is essential for Pse5Ac7Ac biosynthesis from UDP-GlcNAc, and that glycosylation is required for flagella biogenesis in campylobacters.

Structural, genetic and functional characterization of the flagellin glycosylation process in Helicobacter pylori

Mass spectrometry analyses of the complex polar flagella from Helicobacter pylori demonstrated that both FlaA and FlaB proteins are post-translationally modified with pseudaminic acid (Pse5Ac7Ac, 5,7-diacetamido-3,5,7,9-tetradeoxy-l-glycero-l-manno -n o n-ulosonic acid). Unlike Campylobacter, flagellar glycosylation in Helicobacter displays little heterogeneity in isoform or glycoform distribution, although all glycosylation sites are located in the central core region of the protein monomer in a manner similar to that found in Campylobacter. Bioinformatic analysis revealed five genes (HP0840, HP0178, HP0326A, HP0326B, HP0114) homologous to other prokaryote genes previously reported to be involved in motility, flagellar glycosylation or polysaccharide biosynthesis. Insertional mutagenesis of four of these homologues in Helicobacter (HP0178, HP0326A, HP0326B, HP0114) resulted in a non-motile phenotype, no structural flagella filament and only minor amounts of flagellin protein detectable by Western immunoblot. However, mRNA levels for the flagellin structural genes remained unaffected by each mutation. In view of the combined bioinformatic and structural evidence indicating a role for these gene products in glycan biosynthesis, subsequent investigations focused on the functional characterization of the respective gene products. A novel approach was devised to identify biosynthetic sugar nucleotide precursors from intracellular metabolic pools of parent and isogenic mutants using capillary electrophoresis-electrospray mass spectrometry (CE-ESMS) and precursor ion scanning. HP0326A, HP0326B and the HP0178 gene products are directly involved in the biosynthesis of the nucleotide-activated form of Pse, CMP-Pse. Mass spectral analyses of the cytosolic extract from the HP0326A and HP0326B isogenic mutants revealed the accumulation of a mono- and a diacetamido trideoxyhexose UDP sugar nucleotide precursor.

The genetics of glycosylation in Gram-negative bacteria

In recent years there has been a dramatic increase in reports of glycosylation of proteins in various Gram-negative systems including Neisseria meningitidis, Neisseria gonorrhoeae, Campylobacter jejuni, Pseudomonas aeruginosa, Escherichia coli, Caulobacter crescentus, Aeromonas caviae and Helicobacter pylori. Although this growing list contains many important pathogens (reviewed by Benz and Schmidt [Mol. Microbiol. 45 (2002) 267-276]) and the glycosylations are found on proteins important in pathogenesis such as pili, adhesins and flagella the precise role(s) of the glycosylation of these proteins remains to be determined. Furthermore, the details of the glycosylation biosynthetic process have not been determined in any of these systems. The definition of the precise role of glycosylation and the mechanism of biosynthesis will be facilitated by a detailed understanding of the genes involved.

A family of six flagellin genes contributes to the Caulobacter crescentus flagellar filament

The Caulobacter crescentus flagellar filament is assembled from multiple flagellin proteins that are encoded by six genes. The amino acid sequences of the FljJ and FljL flagellins are divergent from those of the other four flagellins. Since these flagellins are the first to be assembled in the flagellar filament, one or both might have specialized to facilitate the initiation of filament assembly.

A new class of Caulobacter crescentus flagellar genes

Eight Caulobacter crescentus flagellar genes, flmA, flmB, flmC, flmD, flmE, flmF, flmG, and flmH, have been cloned and characterized. These eight genes are clustered in pairs (flmAB, flmCD, flmEF, and flmGH) that appear to be structurally organized as operons. Homology comparisons suggest that the proteins encoded by the flm genes may be involved in posttranslational modification of flagellins or proteins that interact with flagellin monomers prior to their assembly into a flagellar filament. Expression of the flmAB, flmEF, and flmGH operons was shown to occur primarily in predivisional cells. In contrast, the flmCD operon was expressed throughout the cell cycle, with only a twofold increase in predivisional cells. The expression of the three temporally regulated operons was subject to positive regulation by the CtrA response regulator protein. Mutations in class II and III flagellar genes had no significant effect on the expression of the flm genes. Furthermore, the flm genes did not affect the expression of class II or class III flagellar genes. However, mutations in the flm genes did result in reduced synthesis of the class IV flagellin proteins. Taken together, these data indicate that the flm operons belong to a new class of flagellar genes.

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.

Information essential for cell-cycle-dependent secretion of the 591-residue Caulobacter hook protein is confined to a 21-amino-acid sequence near the N-terminus

Recent findings suggest that axial flagellar proteins and virulence proteins of Gram-negative bacteria are exported from the cytoplasm via conserved translocation systems. To identify residues essential for secretion of flagellar axial proteins we examined the 591-residue Caulobacter crescentus flagellar hook protein. Western blot assays of the culture media of strains producing mutant hook proteins show that only residues 38-58 are essential for its secretion to the cell surface. We discuss the observation that this unprocessed 21-residue sequence is not conserved in other axial proteins and does not correspond to the SGL-, ANNLAN- and heptad repeat motifs that are located just upstream of the essential secretion information in the hook protein and are conserved near the N-termini of other axial proteins. These motifs, for which an essential role in export or assembly has been proposed, are required for motility. However, we also demonstrate that hook protein can only be secreted when the flagellar basal body is present in the cell envelope. The cell-cycle regulation of hook protein secretion confirms the specificity of the assay used in these studies and suggests that the basal body itself may serve as a secretion channel for the hook protein.

A three-start helical sheath on the flagellar filament of Caulobacter crescentus

An unusual feature in preparations of the Caulobacter crescentus flagellar filaments is that some filaments are surrounded by a set of three windings that form a sheath. We provide evidence that the sheath is composed of subunits having a molecular mass of 24,000 Da. We suggest that the sheath could be composed of protofilaments of flagellin wound around the filament.

The Caulobacter crescentus flaFG region regulates synthesis and assembly of flagellin proteins encoded by two genetically unlinked gene clusters

At a specific time in the Caulobacter crescentus cell cycle, a single flagellar filament and multiple receptor sites for the swarmer-specific phage phi Cbk are assembled at one pole of the predivisional cell. One cluster of genes required for this morphogenesis, the flaYG region, includes the flgJKL genes, which encode structural proteins of the flagellar filament. These flagellin genes are flanked by genes required for filament assembly, the flaYE genes at one end and the flaF-flbT-flbA-flaG genes at the other. In this study, we characterized mutants carrying large chromosomal deletions within this region. Several of these strains are phi CbK resistant and produce a novel 22-kDa flagellin that is not assembled into flagella. Merodiploid strains containing either the entire flaFG region or individual fla transcription units from this region were constructed. These strains were used to correlate the presence or absence of specific gene products to changes in flagellin synthesis, filament assembly, or phage sensitivity. As a result of these studies, we were able to conclude that (i) the production of the 22-kDa flagellin results from the absence of the flbA and flaG gene products, which appear to be components of a flagellin-processing pathway common to the 25-, 27-, and 29-kDa flagellins; (ii) flbT negatively modulates the synthesis of the 27- and 25-kDa flagellins from two genetically unlinked gene clusters; (iii) flgL is the only flagellin gene able to encode the 27-kDa flagellin, and this flagellin appears to be required for the efficient assembly of the 25-kDa flagellins; (iv) flaF is required for filament assembly; and (v) phi CbK resistance results from the deletion of at least two genes in the flaFG region.

Molecular genetics of the flgI region and its role in flagellum biosynthesis in Caulobacter crescentus

The differentiating bacterium Caulobacter crescentus has been studied extensively to understand how a relatively simple life form can govern the timing of expression of genes needed for the production of stage-specific structures. In this study, a clone containing the 5.3-kb flaP region was shown to contain the flgI, cheL, and flbY genes arranged in an operon with transcription proceeding from flgI to flbY. The predicted flgI polypeptide shows remarkable identity (44%) to the flagellar basal body P-ring protein encoded by the flgI gene of Salmonella typhimurium. flgI mutations case a reduction in the levels of flagellin production and the overproduction of the hook proteins. Therefore, the flgI-encoded P-ring protein is required for normal flagellin and hook protein synthesis, suggesting that basal body assembly may play a role in the regulation of flagellar gene expression. The flbY gene probably is a basal body component as well, since flbY mutants have flagellin and hook protein synthesis patterns similar to those exhibited by other basal body mutants. The smaller cheL gene complements a mutant that is unable to respond to chemotactic signals despite possessing a functional flagellum. This is the first example of an operon containing both flagellar and chemotaxis genes in C. crescentus.

Expression of an early gene in the flagellar regulatory hierarchy is sensitive to an interruption in DNA replication

Genes involved in the biogenesis of the flagellum in Caulobacter crescentus are expressed in a temporal order and are controlled by a trans-acting regulatory hierarchy. Strains with mutations in one of these genes, flaS, cannot transcribe flagellar structural genes and divide abnormally. This gene was cloned, and it was found that its transcription is initiated early in the cell cycle. Subclones that restored motility to FlaS mutants also restored normal cell division. Although transcription of flaS was not dependent on any other known gene in the flagellar hierarchy, it was autoregulated and subject to mild negative control by other genes at the same level of the hierarchy. An additional level of control was revealed when it was found that an interruption of DNA replication caused the inhibition of flaS transcription. The flaS transcript initiation site was identified, and an apparently unique promoter sequence was found to be highly conserved among the genes at the same level of the hierarchy. The flagellar genes with this conserved 5' region all initiate transcription early in the cell cycle and are all sensitive to a disruption in DNA replication. Mutations in these genes also cause an aberrant cell division phenotype. Therefore, flagellar genes at or near the top of the hierarchy may be controlled, in part, by a unique transcription factor and may be responsive to the same DNA replication cues that mediate other cell cycle events, such as cell division.

Genetic switching in the flagellar gene hierarchy of Caulobacter requires negative as well as positive regulation of transcription

Caulobacter crescentus flagellar (fla, flb, or flg) genes are periodically expressed in the cell cycle and they are organized in a regulatory hierarchy. We have analyzed the genetic interactions required for fla gene expression by determining the effect of mutations in 30 known fla genes on transcription from four operons in the hook gene cluster. These results show that the flaO (transcription unit III) and flbF (transcription unit IV) operons are located at or near the top of the hierarchy. They also reveal an extensive network of negative transcriptional controls that are superimposed on the positive regulatory cascade described previously. The strong negative autoregulation observed for the flaN (transcription unit I), flbG (transcription unit II), and flaO (transcription unit III) promoters provides one possible mechanism for turning off fla gene expression at the end of the respective synthetic periods. We suggest that these positive and negative transcriptional interactions are components of genetic switches that determine the sequence in which fla genes are turned on and off in the C. crescentus cell cycle.

Negative transcriptional regulation in the Caulobacter flagellar hierarchy

The Caulobacter crescentus flagellum is formed at a specific time in the cell cycle and its assembly requires the ordered expression of a large number of genes. These genes are controlled in a positive trans-acting hierarchy that reflects the order of assembly of the flagellum. Using plasmids carrying transcriptional fusions of either a neo or a lux reporter gene to the promoters of three flagellar genes representing different ranks in the hierarchy (the hook operon, a basal body gene flbN, and the flaO gene), we have measured the level of chimeric gene expression in 13 flagellar mutant backgrounds. Mutants in the hook operon or in basal body genes caused overproduction of both hook operon and basal body gene chimeric mRNAs, suggesting that negative regulation is superimposed on the positive trans-acting control for these early events in the flagellar hierarchy. Mutants in the structural genes and in genes involved in flagellar assembly had no effect on flaO expression, placing the flaO gene near the top of the hierarchy. However, flaO expression appears to be under negative control by two regulatory genes flaS and flaW. Negative control, as a response to the completion of specific steps in the assembly process, may be an important mechanism used by the cell to turn off flagellar gene expression once the gene product is no longer needed.

Cell-cycle-dependent polar morphogenesis in Caulobacter crescentus: roles of phospholipid, DNA, and protein syntheses

During swarmer cell differentiation in Caulobacter crescentus, morphogenesis at the swarmer pole is characterized by the loss of the flagellum, by the loss of phage receptor activity (PRA) (the ability of the cell to adsorb phage phi CbK), and finally by the initiation of stalk outgrowth at the site formerly occupied by the flagellum and the PRA. We show here that each of these events is a cell cycle-dependent event requiring continuous protein synthesis for its execution but occurring normally in the absence of DNA synthesis or phospholipid synthesis. During stalked-cell differentiation, the flagellum and PRA reappear and the stalk elongates considerably. We show here that these events are also cell cycle dependent, requiring not only de novo protein synthesis but also DNA and phospholipid syntheses. When synchronous cells dividing 160 min after collection were used, PRA reappearance occurred at 110 min. This PRA reappearance was dependent on a phospholipid synthesis-requiring event occurring at 70 min, a DNA synthesis-requiring event occurring at 95 min, and a protein synthesis-requiring event occurring at 108 min. In the absence of net phospholipid synthesis, stalk elongation appeared more or less normal, but the stalks eventually became fragile, and by 240 min, most of the stalks had broken off, leaving only stubs attached to the cell body.

The organization of the Caulobacter crescentus flagellar filament

The structural organization of the flagellar filament of Caulobacter crescentus, as revealed by immunoelectron microscopy, shows five antigenically distinct regions within the hook-filament complex. The first region is the hook. The second region is adjacent to the hook and is approximately 10 nm in length. On the basis of its location in the hook-filament complex, this region may contain hook-associated proteins. Next to this is the third region, which is approximately 60 nm in length. Antibody decoration experiments using mutant strains with deletions of the structural gene for the 29 x 10(3) Mr flagellin (flgJ) showed that the presence of this region is correlated with the expression of the 29 x 10(3) Mr flagellin gene. The next region (region IV), of length approximately 1 to 2 microns, appears to contain the 27.5 x 10(3) Mr flagellin, but at its distal end includes, in gradually increasing amounts, the 25 x 10(3) Mr flagellin. The rest of the filament (region V) is made up predominantly, if not completely, of the 25 x 10(3) Mr flagellin. Except for the hook, there are no morphological features that would otherwise distinguish these regions. A functional flagellum, having the wild-type length and morphology, is assembled by mutant strains deficient in the 29 x 10(3) Mr flagellin and 27.5 x 10(3) Mr flagellin.

Organization of the flaFG gene cluster and identification of two additional genes involved in flagellum biogenesis in Caulobacter crescentus

In Caulobacter crescentus, mutations have been isolated in more than 30 flagellar genes (fla, flb, and flg) which are required in the cell cycle event of flagellum biogenesis. The flaF and flaG mutations and two newly identified mutations, flbT and flbA (P.V. Schoenlein and B. Ely, J. Bacteriol. 171:000-000, 1989), have been localized to the flaFG region. In this study, the genetic and physical organization of this region was analyzed, using the cloned 4.0-kilobase flaFG region in the recombinant plasmid pPLG727. Plasmid pPLG727 complemented flaF, flaG, flbA, and flbT mutations. Further complementation studies with pPLG727 derivatives indicated that flaF and flbT are unique but overlapping transcription units, whereas flbA and flaG constitute a single transcription unit. To determine the direction of transcription of the putative flbA-flaG operon, the promoterless chloramphenicol transacetylase gene was inserted into various positions in the flbA-flaG region, and merodiploid strains containing these transcriptional fusions were assayed for gene function and expression of chloramphenicol resistance. These studies showed that transcription proceeds from flbA to flaG. To confirm the complementation analysis, Southern analyses were performed on chromosomal DNAs isolated from strains containing insertion and deletion mutations. Taken together, these studies defined the relative gene order at one end of the flaYG flagellar gene cluser as flgL-flaF-flbT-flbA-flaG.

Characterization of strains containing mutations in the contiguous flaF, flbT, or flbA-flaG transcription unit and identification of a novel fla phenotype in Caulobacter crescentus

During the Caulobacter crescentus cell cycle, flagellin synthesis and filament assembly are temporally controlled events which require the products encoded by the contiguous flaF, flbT, and flbA-flaG transcription units (P.V. Schoenlein, L.S. Gallman, and B. Ely, J. Bacteriol. 171:000-000, 1989). To better define the functions of these genes, immunoprecipitation studies, Western blot (immunoblot) analyses, and electron microscopic analyses characterized flagellin synthesis and assembly in mutant and merodiploid strains. Mutations in the flaF or flbA-flaG transcription unit resulted in reduced synthesis of the 25- and 27-kilodalton (kDa) flagellins. In contrast, mutations in flbT resulted in overproduction of these flagellins. The FlbT phenotype is unique, since all other identified C. crescentus fla mutations cause a reduction in the levels of the 25- and 27-kDa flagellins. Furthermore, the flbT mutant showed a chemotaxis deficiency even though it was motile. Thus, the flbT gene product appears to be involved in the regulation of both flagellin synthesis and chemotactic function. Mutations in the flbT and flbA-flaG transcription units also resulted in the production of a 22-kDa flagellin species that is not normally detected in wild-type cells. This flagellin species was not detected in the flbT filaments. Furthermore, the 22-kDa flagellin was no longer detected in flbA pseudorevertants that assembled functional filaments. Thus, the 22-kDa flagellin does not appear to be assembled into filaments. Since many of the flbT filaments are shorter than wild-type filaments, we discuss the possibility that the 22-kDa flagellin species may adversely affect flagellin assembly in this mutant.

Image reconstruction of the flagellar basal body of Caulobacter crescentus

The bacterium Caulobacter crescentus has a single polar flagellum, which is present for only a portion of its cell cycle. The flagellum is ejected from the swarmer cell and then synthesized de novo later in the cell cycle. The flagellum is composed of a transmembrane basal body, a hook and a filament. Single-particle averaging and image reconstruction methods were applied to the electron micrographs of negatively stained basal bodies from C. crescentus. These basal bodies have five rings threaded on a rod. The L and P rings are connected by a bridge of material at their outer radii. The E ring is a thin, flat disk. The S ring has a triangular cross section, the sides of the triangle abutting the E ring, the rod and the M ring. The M ring, which is at the inner membrane of the cell, has a different structure depending on the method of preparation. With one method, the M ring makes a snug contact with the S ring and is often capped by an axial button, a new component apparently distinct from the M ring. With the other method, the M ring is similar to that of S. typhimurium; that is, it contacts the S ring only at an outer radius and lacks the button. Averages of the rod-hook-filament subassembly ejected by swarmer cells reveal that the rod consists of two parts with the E ring marking the approximate position of the break. The structures of basal bodies from two mutants defective in the hook assembly were found to be indistinguishable from wild-type basal bodies, suggesting that the assembly of the basal body is independent of the hook or filament assembly.

Three-dimensional reconstruction of the flagellar filament of Caulobacter crescentus. A flagellin lacking the outer domain and its amino acid sequence lacking an internal segment

We obtained a three-dimensional reconstruction of the flagellar filament of Caulobacter crescentus CB15 from electron micrographs of negatively stained preparations. The C. crescentus filament appears, both in negative stain and in the frozen-hydrated state, significantly smoother and narrower than other filaments. Its helical symmetry, and unit cell size, however, are similar to that of other filaments. Although the molecular weight of the C. crescentus flagellin is about half that of other plain flagellins, there is only one monomer per unit cell as indicated by diffraction studies and by linear mass density measurements with the scanning transmission electron microscope. Alignment of the primary amino acid sequences of Salmonella typhimurium (serotype i) and C. crescentus (29,000 Mr) flagellins shows that whereas there is homology at the amino and carboxyterminal ends of the two sequences, the central segment of the S. typhimurium sequence has no homology to that of C. crescentus. A correlated comparison between the three-dimensional reconstructions of the two filaments and primary amino acid sequences of the two flagellins suggests that: (1) the C. crescentus subunit is missing the outer molecular domain but is, otherwise, similar to that of S. typhimurium; (2) the outer molecular domain in S. typhimurium corresponds, therefore, to a central stretch of the primary amino acid sequence; and (3) the outer molecular domain, missing in C. crescentus, is not obligatory for flagellar motility.

Cascade regulation of Caulobacter flagellar and chemotaxis genes

The assembly of a functional flagellum in the bacterium Caulobacter crescentus requires the protein products of approximately 30 genes expressed in a temporally discrete and spatially distinct manner. Our current understanding of this system has been limited by the fact that purified protein products are available for only about one-fifth of these genes. A genetically engineered transposon promoter probe, Tn5-VB32, containing a promoterless gene encoding neomycin phosphotransferase II (NPTase II) was used to generate a series of non-motile (fla-), kanamycin resistant strains of C. crescentus. These transcription-fusions allow the expression of NPTase II to be controlled by flagellar promoters, and thus questions of temporal regulation of flagellar genes can be addressed without the need to obtain purified protein products. The flagellar promoters accessed by Tn5-VB32 exhibited temporal regulation analogous to the known flagellar and chemotaxis gene products. The expression of NPTase II in these mutants is read from a chimeric mRNA that initiates in a chromosomal fla promoter and continues through the inserted NPTase II gene. Thus, temporal regulation is controlled by modulating either the initiation of transcription, or transcript turnover, at specific times in the cell cycle. Epistatic interactions between the genes accessed by the promoter probe and other flagellar loci were studied in double fla mutants generated by transducing the promoter-probe mutations into spontaneously derived second-site fla-mutant backgrounds. The synthesis of both natural fla gene products and the accessed NPTase II was assayed in these strains using antisera to purified components of the flagellum and to purified NPTase II. On the basis of these interactions, a trans-acting hierarchy of flagellar and chemotaxis gene expression is proposed.

Identification of a gene cluster involved in flagellar basal body biogenesis in Caulobacter crescentus

The bacterial flagellum is a complex structure composed of a transmembrane basal body, a hook, and a filament. In Caulobacter crescentus the biosynthesis and assembly of this structure is under temporal and spatial control. To help to define the order of assembly of the flagellar components and to identify the genes involved in the early steps of basal body construction, mutants defective in basal body formation have been analyzed. Mutants in the flaD flaB flaC gene cluster were found to be unable to assemble a complete basal body. The flaD BC motC region was cloned and the genes were localized by subcloning and complementation analysis. A series of Tn5 insertion mutations in the flaD BC region were mapped. Complementation analysis of the Tn5 insertion mutants indicated the existence of at least four transcriptional units in the region and identified the presence of two new genes designated flbN and flbO. Mutants in flbN, flaB, flaC and flbO were unable to assemble any basal body structure and are likely to be involved in the early steps of basal body formation. The flaD mutant, however, was found to contain a partially assembled basal body consisting of the rod and three hook-distal rings. All of the mutants in this cluster exhibited pleiotropic effects on the expression of other flagellar and chemotaxis functions, including the level of synthesis of flagellins, the hook protein and hook protein precursor, and the level of chemotaxis methylation.

Separation of temporal control and trans-acting modulation of flagellin and chemotaxis genes in Caulobacter

The genes involved in the biogenesis of the flagellum and the chemotaxis machinery are temporally regulated during the Caulobacter crescentus cell cycle. Using plasmid complementation, we have mapped the extent of the flaY and flaE genes. These genes function in trans to regulate the expression of the flagellin genes and the chemotaxis genes. We have found that the trans regulation that modulates the amount of the flagellins and the chemotaxis proteins can be separated from the temporal control of fla and che gene expression. This conclusion is based on two observations: the low level of synthesis of flagellins and chemotaxis proteins in flaY and flaE mutant strains occurred at the correct time in the cell cycle, and complementation with plasmids containing intact flaY and flaE genes resulted in the synthesis of normal levels of flagellins and chemotaxis gene products with the maintenance of temporal cell cycle control.

Transcriptional regulation of a periodically controlled flagellar gene operon in Caulobacter crescentus

Temporal regulation of flagellar gene expression in Caulobacter crescentus has been examined by a detailed analysis of the flbG-flaJ-flbH-flaK hook operon. The approximate location of the promoter for this 4.4 X 10(3) base-pair transcriptional unit was determined by deletion mapping, and the flaK gene was shown by nucleotide sequencing to code for the hook protein. flaK messenger RNA was quantified by S1 nuclease mapping with an internal restriction fragment of the gene as the 5'-labeled DNA probe. The results of these assays provide the first direct evidence that periodic expression of a flagellar gene in the C. crescentus cell cycle is regulated at the transcriptional level. The effect of altering the time of gene duplication in the cell cycle was examined by subcloning the complete hook operon on a plasmid that replicates throughout the S phase. The normal periodicity of flaK transcription and translation was maintained in this merodiploid strain, which suggests that replication alone is not sufficient to initiate flagellar gene expression. We also show that the three adjacent transcriptional units III, IV and V are required in trans for transcription of the book operon, and we discuss the possible role of these genes in the hierarchical regulation of the flagellar gene expression.

Isolation and genetic analysis of Caulobacter mutants defective in cell shape and membrane lipid synthesis

In this paper we report the isolation, characterization and genetic analysis of several C. crescentus mutants altered in membrane lipid synthesis. One of these, a fatty acid bradytroph, AE6002, was shown to be due to a mutation in the fatA gene. In addition to the presence of the fatA506 mutation, this strain was found to contain two other mutations, one of which caused the production of a water-soluble brown-orange pigment (pigA) and another which caused formation of helical cells (hclA). Expression of the latter two phenotypes required complex media and both were repressed by glucose. However, the lesions were mapped to loci that are separated by a substantial distance. The hclA and the fatA genes mapped close together, possibly implying that comutation had occurred in AE6002. Data are presented that allow the unambiguous identification of a second Fat gene (fatB) in C. crescentus. The map position of another mutation in membrane lipid biogenesis, the glycerol-3-PO4 auxotroph gpsA505, was also determined. During this study the flaZ gene was fine-mapped and the positions of proC and rif changed from the previously reported location.

Physical mapping and complementation analysis of transposon Tn5 mutations in Caulobacter crescentus: organization of transcriptional units in the hook gene cluster

Using the cloned DNA from the hook protein gene region of Caulobacter crescentus ( Ohta et al., Proc. Natl. Acad. Sci. U.S.A. 79:4863-4867, 1982), we have identified and physically mapped 19 Tn5-induced and 2 spontaneous insertion mutations to this region of the chromosome. These nonmotile mutants define a major cluster of fla genes that covers approximately 17 kilobases on the chromosome (hook gene cluster). Complementation analysis of the mutants using DNA fragments from the region subcloned in the broad host range plasmid pRK290 has shown that these fla genes are organized into at least five transcriptional units (I to V). Transcriptional unit II contains at least one gene in addition to the hook protein gene, which makes this the first operon described in C. crescentus. Expression of the hook protein gene and the genetically unlinked flagellin A and B genes by this set of mutants also furnishes additional insights into the hierarchial regulation of flagellar genes. We have found that the spontaneous insertion mutant ( SC511 ) of the hook protein gene ( flaK ) makes no flagellin A or B and that genes downstream from the hook protein gene are required in trans for expression of the hook protein operon and the flagellin A and B genes. Recombination and complementation results thus place flaK , flaJ , flaN , and flaO (R. C. Johnson and B. Ely , J. Bacteriol . 137:627-634, 1979) in the hook gene cluster, identify at least three new genes ( flbD , flbG , and flbF ), and suggest that this cluster may contain several additional, as yet unidentified, fla genes.

Evidence that subcellular flagellin pools in Caulobacter crescentus are precursors in flagellum assembly

To study the assembly of the Caulobacter crescentus flagellar filament, we have devised a fractionation protocol that separates the cellular flagellin into three compartments: soluble, membrane, and assembled. Radioactive labeling in pulse-chase and pulse-labeling experiments has demonstrated for the first time that both soluble and membrane-associated flagellin pools are precursors in the assembly of the flagellar filament. The results of these experiments also indicate that flagellar filament assembly occurs via the translocation of newly synthesized flagellins from the soluble pool to the membrane pool to the assembled flagellar filaments. It is not possible to conclude whether the soluble flagellin fraction is synthesized cytoplasmically or as a loosely associated membrane intermediate which is released during lysis. It is clear, however, that the soluble and membrane flagellins are in physically and functionally distinct pools. The implications of these findings for the study of protein secretion from cells and the invariant targeting of flagellar proteins to the stalk-distal pole of the dividing cell during flagellum morphogenesis are discussed.

Analysis of the pleiotropic regulation of flagellar and chemotaxis gene expression in Caulobacter crescentus by using plasmid complementation

The biosynthesis of the single polar flagellum and the proteins that comprise the chemotaxis methylation machinery are both temporally and spacially regulated during the Caulobacter crescentus cell-division cycle. The genes involved in these processes are widely separated on the chromosome. The region of the chromosome defined by flaE mutations contains at least one flagellin structural gene and appears to regulate flagellin synthesis and flagellar assembly. The protein product of the adjacent flaY gene was found to be required to regulate the expression of several flagellin proteins and the assembly of a functional flagellum. We demonstrate here that each of these genes is also required for the expression of chemotaxis methylation genes known to map elsewhere on the chromosome. In order to study the regulation of these genes, plasmids were constructed that contain either an intact flaYE region or deletions in the region of flaY. These plasmids were mated into a wild-type strain and into strains containing various Tn5 insertion and deletion mutations and a temperature-sensitive mutation in the flaYE region. The presence of a plasmid containing the flaYE region allowed the mutant strains to swim and to exhibit chemotaxis, to synthesize increased amounts of the flagellins, to methylate their "methyl-accepting chemotaxis proteins" (MCPs), and to regain wild-type levels of methyltransferase activity. Chromosomal deletions that extend beyond the cloned region were not complemented by this plasmid. Plasmids containing small deletions in the flaY region failed to restore to any flaY or flaE mutants the ability to swim or to assemble a flagellar filament. When mated into a wild-type strain, plasmids bearing deletions in the flaY region were found to be recessive. The pleiotropic regulation of flagellin synthesis, assembly, and chemotaxis methylation functions exhibited by both the flaY and flaE genes suggest that their gene products function in a regulatory hierarchy that controls both flagellar and chemotaxis gene expression.