A comparative structural analysis of the flagellin monomers of Caulobacter crescentus indicates that these proteins are encoded by two genes

Isolation of a Caulobacter gene cluster specifying flagellum production by using nonmotile Tn5 insertion mutants

Caulobacter crescentus assembles a single polar flagellum from protein components synthesized at a specific time in the cell cycle. Of the 26 genes required for flagellum production, at least 4 of them-flaY, E, F, and G-map together in a single cluster. We have isolated DNA from this region of the chromosome by using a nonmotile mutant with a Tn5 insertion into flaE. C. crescentus DNA carrying the Tn5-flaE region and adjacent sequences was cloned into pBR325 and selected by transposon-encoded kanamycin resistance. The resulting plasmid was used as a probe to isolate the flaE region from a wild-type gene bank and to determine the chromosomal location of several deletion and insertion mutations within the flaY/E/F/G cluster. At least three promotors and three major transcripts were shown to originate from the cloned gene cluster. The role of these genes in flagellar biogenesis was examined by immunoprecipitation of mutant cell extracts with antiflagellin antibody. Deletions extending rightward into this gene cluster eliminated one of the two flagellin proteins normally synthesized by C. crescentus. Mutations mapping to the left permitted synthesis of both normal flagellins but at significantly decreased levels. These results suggest that the leftward end of this cluster contains a region that may function in a regulatory capacity whereas the rightward end may contain sequences overlapping a flagellin structural gene.

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.

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.

Rapid Immunocapture of Pseudomonas putida Cells from Lake Water by Using Bacterial Flagella

Monoclonal antibodies to Pseudomonas putida Paw340 cells were produced. In an enzyme-linked immunosorbent assay (ELISA) against whole bacterial cells, a hybridoma cell line termed MLV1 produced a monoclonal antibody that reacted with P. putida Paw340 but showed no cross-reaction with 100 medical isolates and 150 aquatic isolates. By ELISA, immunogold electron microscopy, and Western blot (immunoblot) analysis, MLV1 antibody was found to react with purified bacterial flagella. The surfaces of magnetic polystyrene beads were coated with MLV1 antibody. By mixing MLV1 antibody-coated beads with lake water samples containing the target P. putida host, bead-cell complexes which could be recovered by attraction towards a magnet were formed. Prevention of nonspecific attachment of cells to the beads required the incorporation of detergents in the isolation protocol. These detergents affected colony-forming ability; however, the cells remained intact for direct detection. When reisolated by standard cultural methods, approximately 20% of the initial target population was recovered. Since the beads and bead-cell complexes were recovered in a magnetic field, target bacteria were separated from other lake water organisms and from particulate material which was not attracted towards the magnet and were thereby enriched. This method may now provide a useful system for recovering recombinant bacteria selectively from environmental samples.

Cloning and expression of Pseudomonas aeruginosa flagellin in Escherichia coli

The flagellin gene was isolated from a Pseudomonas aeruginosa PAO1 genomic bank by conjugation into a PA103 Fla- strain. Flagellin DNA was transferred from motile recipient PA103 Fla+ cells by transformation into Escherichia coli. We show that transformed E. coli expresses flagellin protein. Export of flagellin to the E. coli cell surface was suggested by positive colony blots of unlysed cells and by isolation of flagellin protein from E. coli supernatants.

Cloning of the flagellin gene from Bacillus subtilis and complementation studies of an in vitro-derived deletion mutation

The flagellin promoter and structural gene from Bacillus subtilis I168 was cloned and sequenced. The amino-terminal protein sequence deduced from the coding sequence of the cloned gene was identical to that of the amino terminus of purified flagellin, indicating that the export of this protein is not directed by a posttranslationally processed N-terminal signal peptide. A sequence that was homologous to that of a consensus sigma 28 RNA polymerase recognition site lay upstream of the proposed translational start site. Amplification of this promoter region on a multicopy plasmid resulted in the formation of long, filamentous cells that accumulated flagellin intracellularly. The chromosomal locus containing the wild-type flagellin allele was replaced with a defective allele of the gene (delta hag-633) that contained a 633-base-pair deletion. Transport analysis of various flagellin gene mutations expressed in the hag deletion strain suggest that the extreme C-terminal portion of flagellin is functionally involved in export of the protein.

Laser excitation of fluorescent-labeled polypeptides in polyacrylamide gels

A laser beam at 488 nm, converted into a fan of light by a surface-coated mirror oscillated in response to a triangular wave, was inserted into the base of a polyacrylamide gel. The laser light was trapped by internal reflection and gave uniform illumination throughout the entire gel slab. Photography with color film detected 50 fmol of fluorescein covalently coupled to ovalbumin, gave 80-fold greater sensitivity than transillumination in detection of fluorescein-labeled polypeptides, and was about 25-fold more sensitive than protein staining with silver. Laser illumination visualized end-labeled beta-galactosidase, afforded quality control of such preparations, and demonstrated that the end-labeled derivative contained about 25-fold less fluorescein than uniformly labeled beta-galactosidase. The latter result was confirmed by dot-blot analysis using a polyclonal antibody specific for fluorescein. The application of end-labeling to the location of features of protein primary structure is discussed.

Cloning, nucleotide sequence, and taxonomic implications of the flagellin gene of Roseburia cecicola

The gene coding for the flagellin protein of Roseburia cecicola, an oxygen-intolerant, gram-negative, anaerobic bacterium indigenous to the murine cecum, has been cloned and sequenced. NH2-terminal amino acid sequence data from the flagellin protein were used as a basis for the synthesis of two mixed-sequence deoxyoligonucleotides. The oligonucleotides were used to identify and clone the flagellin structural gene. DNA sequence analysis of M13mp8 and mp9 subclones revealed a protein with a length of 293 amino acids and a molecular weight of 31,370. Comparisons with the sequences of flagellins of other species revealed conserved regions and suggested that although R. cecicola has structural characteristics of a gram-negative bacterium, it may be most closely related to the gram-positive bacteria.

Control of synthesis and positioning of a Caulobacter crescentus flagellar protein

The Caulobacter crescentus flagellum is assembled during a defined time period in the cell cycle. Two genes encoding the major components of the flagellar filament, the 25K and the 27.5K flagellins, are expressed coincident with flagellar assembly. A third gene, flgJ, is also temporally regulated. The synthesis of the product of flgJ, the 29K flagellin, occurs prior to the synthesis of the other flagellin proteins. We demonstrate here that the time of initiation of flgJ expression is independent of chromosomal location but is dependent upon cis-acting sequences present upstream of the flgJ structural gene. Evidence that there is transcriptional control of flgJ expression includes the following: (1) The initial appearance of flgJ message was coincident with the onset of 29K flagellin protein synthesis, and (2) expression of an NPT II reporter gene driven by the flgJ promoter was temporally correct. Post-transcriptional regulation might contribute to the control of expression, because the flgJ mRNA persisted for a longer period of time than did the synthesis of the 29K protein. The 29K flagellin was found only in the progeny swarmer cell after cell division. In a mutant strain that failed to assemble a flagellum, the 29K flagellin still segregated to the presumptive swarmer cell, demonstrating that positioning of the protein is independent of filament assembly. Analysis of a chimeric flgJ-NPT II transcriptional fusion showed that the flgJ regulatory sequences do not control the segregation of the 29K flagellin to the swarmer cell progeny, suggesting that correct segregation depends on the protein product.

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.

Promoter mapping and cell cycle regulation of flagellin gene transcription in Caulobacter crescentus

Caulobacter crescentus contains a 25- and a 27-kDa flagellin, which are assembled into the flagellar filament, and a 29-kDa flagellin, which is related in sequence but is of unknown function. We have used DNA sequence analysis and nuclease S1 assays to map the in vivo transcription start sites of the three flagellin genes and to study their regulation. These experiments lead to several conclusions. First, copies of the 29-, 25-, and 27-kDa flagellin genes are organized in a tandem array in the flaEY gene cluster of C. crescentus. Second, flagellin genes are under transcriptional control and each gene is expressed with a characteristic periodicity in the cell cycle. Third, flagellin gene promoters contain conserved nucleotide sequence elements at -13, -24, and -100 that are homologous to the fla genes in the hook gene cluster. The -13 and -24 sequences conform to a fla gene promoter consensus sequence (C/TTGGCC/GC-N5-TTGC) that is similar in sequence to the -12, -24 consensus sequence of the Klebsiella pneumonia nif gene promoters. Fourth, the sequence element at approximately -100 in the 25- and the 27-kDa flagellin genes is homologous to a 19-base-pair sequence [designated previously as II-1; see Chen, L.-S., Mullin, D. M. & Newton, A. (1986) Proc. Natl. Acad. Sci. USA 83, 2860-2864]at -101 in the promoter of transcription unit II of the hook gene cluster; the two flagellin genes, like the fla genes examined in the hook gene cluster that contain the -100 element, are under positive control by transcription unit III of the hook gene cluster. This result supports a model in which the timing of fla gene transcription in the C. crescentus cell cycle is determined in part by a cascade of trans-acting regulatory gene products.

Escherichia coli hemolysin is released extracellularly without cleavage of a signal peptide

A 110-kilodalton polypeptide isolated from cell-free culture supernatants of hemolytic Escherichia coli was shown to be associated with hemolytic activity. The relative amount of the extracellular 110-kilodalton species detected directly reflects the extracellular hemolysin activity associated with Escherichia coli strains harboring different hemolysin recombinant plasmids. The predicted molecular mass of the hemolysin structural gene (hlyA) based on DNA sequence analysis was 109,858 daltons. Amino-terminal amino acid sequence analysis of the 110-kilodalton polypeptide provided direct evidence that it was encoded by hlyA. Based on this information, it was also demonstrated that the HlyA polypeptide was released extracellularly without signal peptidase-like cleavage. An examination of hemolysin-specific polypeptides detected by use of recombinant plasmids in a minicell-producing strain of Escherichia coli was performed. These studies demonstrated how hemolysin-associated 110- and 58-kilodalton polypeptides detected in the minicell background could be misinterpreted as a precursor-product relationship.

Bacterial chemotaxis: biochemistry of behavior in a single cell

Bacterial chemotaxis is a primitive behavioral system that shows great promise for being amenable to a description of its molecular mechanism. In Gram-negatives like Escherichia coli, addition of amino acid attractant begins a series of events, starting with binding to certain intrinsic membrane proteins, the MCPs, and ending with a period of smooth swimming. Immediately, methyl-esterification of these MCPs begins and continues during this period. By contrast in the Gram-positive Bacillus subtilis, demethylation of MCPs occurs during the same period. At least two other mechanisms for mediating chemotaxis toward the attractants oxygen and phosphotransferase sugars exist in E. coli, and in these, changes in methylation of MCPs plays no role. Moreover, chemotaxis away from many repellents by B. subtilis appears to involve different mechanisms. Many of the repellents include drugs and toxicants, many of them man-made, so that chemoreceptors could not have specifically evolved; yet the bacteria are often exquisitely sensitive to them. Indeed, the B. subtilis membrane seems to act like a generalized antenna for noxious membrane-active substances.

Morphology, function and isolation of halobacterial flagella

Halobacterium halobium has right-handed helical flagella. During the logarithmic phase of growth, cells are predominantly monopolar, whereas in the stationary phase they are mostly bipolarly flagellated. The flagellar bundle consists of several filaments. Halobacteria swim forward by clockwise and backwards by counterclockwise rotation of their flagella. The flagellar bundle does not fly apart when the sense of rotation changes. In addition to the flagella attached to the cells, large amounts of loose flagella, which aggregate into thick super-flagella, can be observed at all phases of growth. During stationary phase, the production of these super-flagella, which are generally 10 to 20 times longer than the cell body, is significantly higher. Dissociation and association by high temperature and differential centrifugation allow the isolation of pure flagella. Three different protein bands, of 23,500, 26,500 and 31,500 apparent molecular weights, are seen on sodium dodecyl sulphate/polyacrylamide gels. Antibodies against halobacterial flagella were produced in chicken; these antibodies interact with the flagella even in 4 M-NaCl. Rotation of tethered cells demonstrates that Halobacteria move due to the rotation of the flagella.

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.

Methylation involved in chemotaxis is regulated during Caulobacter differentiation

Caulobacter crescentus carries a flagellum and is motile only during a limited time in its cell cycle. We have asked if the biochemical machinery that mediates chemotaxis exists coincident with the cell's structural ability to respond to a chemotactic signal. We first demonstrated that one function of the chemotaxis machinery, the ability to methylate the carboxyl side chains of a specific set of membrane proteins (methyl-accepting chemotaxis proteins, MCPs), is present in C. crescentus. This conclusion is based on the observations that (i) methionine auxotrophs starved of methionine can swim only in the forward direction (comparable to smooth swimming in the enteric bacteria), (ii) a specific set of membrane proteins was found to be methylated in vivo and the incorporated [3H]methyl groups were alkali sensitive, (iii) this same set of membrane proteins incorporated methyl groups from S-adenosylmethionine in vitro, and (iv) out of a total of eight generally nonchemotactic mutants, two were found to swim only in a forward direction and one of these lacked methyltransferase activity. Analysis of in vivo and in vitro methylation in synchronized cultures showed that the methylation reaction is lost when the flagellated swarmer cell differentiates into a stalked cell. In vivo methylation reappeared coincident with the biogenesis of the flagellum just prior to cell division. In vitro reconstitution experiments with heterologous cell fractions from different cell types showed that swarmer cells contain methyltransferase and their membranes can be methylated. However, newly differentiated stalked cells lack methyltransferase activity and membranes from these cells cannot accept methyl groups. These results demonstrate that MCP methylation is confined to that portion of the cell cycle when flagella are present.

Synthesis and assembly of flagellar components by Caulobacter crescentus motility mutants

Cultures of wild-type Caulobacter crescentus and strains with fla mutations representing 24 genes were pulse-labeled with 14C-amino acids and analyzed by immunoprecipitation to study the synthesis of flagellar components. Most fla mutants synthesize flagellin proteins at a reduced rate, suggesting the existence of some mechanism to prevent the accumulation of unpolymerized flagellin subunits. Two strains contain deletions that appear to remove a region necessary for this regulation. The hook protein does not seem to be subject to this type of regulation and, in addition, appears to be synthesized as a faster-sedimenting precursor. Mutations in a number of genes result in the appearance of degradation products of either the flagellin or the hook proteins. Mutations in flaA, -X, -Y, or -Z result in the production of filaments (stubs) that contain altered ratios of the flagellin proteins. In some flaA mutants, other flagellin-related proteins were assembled into the stub structures in addition to the flagellins normally present. Taken together, these analyses have begun to provide insight into the roles of individual fla genes in flagellum biogenesis in C. crescentus.

Cloning of developmentally regulated flagellin genes from Caulobacter crescentus via immunoprecipitation of polyribosomes

Immunoprecipitation of Caulobacter crescentus polyribosomes with antiflagellin antibody provided RNA for the synthesis of cDNA probes that were used to identify three specific EcoRI restriction fragments (6.8, 10, and 22 kilobases) in genomic digests of Caulobacter DNA. The RNA was present only in polyribosomes isolated from a time interval in the Caulobacter cell cycle that was coincident with flagellin polypeptide synthesis. The structural gene for Mr 27,500 flagellin polypeptide was assigned to a region of the 10-kilobase EcoRI restriction fragment by DNA sequence analysis. Analysis of mutants defective in motility further established a correlation between the Mr 27,500 flagellin gene and the flaE gene locus [Johnson, R. C. & Ely, B. (1979) J. Bacteriol. 137, 627-634]. The other EcoRI fragments that hybridize with the immunoprecipitated polyribosome-derived cDNA probe are also temporally regulated and have features that suggest they encode other polypeptides associated with the flagellum. Modifications were required to adapt the procedure of immunoprecipitation of polyribosomes for use with Caulobacter and should be applicable to the production of specific structural gene probes from other prokaryotic systems.