Caulobacter flagellar organelle: synthesis, compartmentation, and assembly

Flagellar Structures from the Bacterium Caulobacter crescentus and Implications for Phage CbK Predation of Multiflagellin Bacteria

Caulobacter crescentus is a Gram-negative alphaproteobacterium that commonly lives in oligotrophic fresh- and saltwater environments. C. crescentus is a host to many bacteriophages, including ϕCbK and ϕCbK-like bacteriophages, which require interaction with the bacterial flagellum and pilus complexes during adsorption. It is commonly thought that the six paralogs of the flagellin gene present in C. crescentus are important for bacteriophage evasion. Here, we show that deletion of specific flagellins in C. crescentus can indeed attenuate ϕCbK adsorption efficiency, although no single deletion completely ablates ϕCbK adsorption. Thus, the bacteriophage ϕCbK likely recognizes a common motif among the six known flagellins in C. crescentus with various degrees of efficiency. Interestingly, we observe that most deletion strains still generate flagellar filaments, with the exception of a strain that contains only the most divergent flagellin, FljJ, or a strain that contains only FljN and FljO. To visualize the surface residues that are likely recognized by ϕCbK, we determined two high-resolution structures of the FljK filament, with and without an amino acid substitution that induces straightening of the filament. We observe posttranslational modifications on conserved surface threonine residues of FljK that are likely O-linked glycans. The possibility of interplay between these modifications and ϕCbK adsorption is discussed. We also determined the structure of a filament composed of a heterogeneous mixture of FljK and FljL, the final resolution of which was limited to approximately 4.6 Å. Altogether, this work builds a platform for future investigations of how phage ϕCbK infects C. crescentus at the molecular level.IMPORTANCE Bacterial flagellar filaments serve as an initial attachment point for many bacteriophages to bacteria. Some bacteria harbor numerous flagellin genes and are therefore able to generate flagellar filaments with complex compositions, which is thought to be important for evasion from bacteriophages. This study characterizes the importance of the six flagellin genes in C. crescentus for infection by bacteriophage ϕCbK. We find that filaments containing the FljK flagellin are the preferred substrate for bacteriophage ϕCbK. We also present a high-resolution structure of a flagellar filament containing only the FljK flagellin, which provides a platform for future studies on determining how bacteriophage ϕCbK attaches to flagellar filaments at the molecular level.

Role of Caulobacter Cell Surface Structures in Colonization of the Air-Liquid Interface

In aquatic environments, Caulobacter spp. can be found at the boundary between liquid and air known as the neuston. I report an approach to study temporal features of Caulobacter crescentus colonization and pellicle biofilm development at the air-liquid interface and have defined the role of cell surface structures in this process. At this interface, C. crescentus initially forms a monolayer of cells bearing a surface adhesin known as the holdfast. When excised from the liquid surface, this monolayer strongly adheres to glass. The monolayer subsequently develops into a three-dimensional structure that is highly enriched in clusters of stalked cells known as rosettes. As this pellicle film matures, it becomes more cohesive and less adherent to a glass surface. A mutant strain lacking a flagellum does not efficiently reach the surface, and strains lacking type IV pili exhibit defects in organization of the three-dimensional pellicle. Strains unable to synthesize the holdfast fail to accumulate at the boundary between air and liquid and do not form a pellicle. Phase-contrast images support a model whereby the holdfast functions to trap C. crescentus cells at the air-liquid boundary. Unlike the holdfast, neither the flagellum nor type IV pili are required for C. crescentus to partition to the air-liquid interface. While it is well established that the holdfast enables adherence to solid surfaces, this study provides evidence that the holdfast has physicochemical properties that allow partitioning of nonmotile mother cells to the air-liquid interface and facilitate colonization of this microenvironment.IMPORTANCE In aquatic environments, the boundary at the air interface is often highly enriched with nutrients and oxygen. Colonization of this niche likely confers a significant fitness advantage in many cases. This study provides evidence that the cell surface adhesin known as a holdfast enables Caulobacter crescentus to partition to and colonize the air-liquid interface. Additional surface structures, including the flagellum and type IV pili, are important determinants of colonization and biofilm formation at this boundary. Considering that holdfast-like adhesins are broadly conserved in Caulobacter spp. and other members of the diverse class Alphaproteobacteria, these surface structures may function broadly to facilitate colonization of air-liquid boundaries in a range of ecological contexts, including freshwater, marine, and soil ecosystems.

Characterization of long-chain fatty acid uptake in Caulobacter crescentus

Studies evaluating the uptake of long-chain fatty acids in Caulobacter crescentus are consistent with a protein-mediated process. Using oleic acid (C18:1) as a substrate, fatty acid uptake was linear for up to 15 min. This process was saturable giving apparent V(max) and K(m) values of 374 pmol oleate transported/min/mg total protein and 61 μM oleate, respectively, consistent with the notion that one or more proteins are likely involved. The rates of fatty acid uptake in C. crescentus were comparable to those defined in Escherichia coli. Uncoupling the electron transport chain inhibited oleic acid uptake, indicating that like the long-chain fatty acid uptake systems defined in other gram-negative bacteria, this process is energy-dependent in C. crescentus. Long-chain acyl CoA synthetase activities were also evaluated to address whether vectorial acylation represented a likely mechanism driving fatty acid uptake in C. crescentus. These gram-negative bacteria have considerable long-chain acyl CoA synthetase activity (940 pmol oleoyl CoA formed/min/mg total protein), consistent with the notion that the formation of acyl CoA is coincident with uptake. These results suggest that long-chain fatty acid uptake in C. crescentus proceeds through a mechanism that is likely to involve one or more proteins.

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.

A sigma 54 transcriptional activator also functions as a pole-specific repressor in Caulobacter

The differential localization of proteins in the Caulobacter predivisional cell leads to the formation of two distinct progeny cells: a motile swarmer cell and a sessile stalked cell. Pole-specific transcription in the predivisional cell is one mechanism responsible for protein localization. Here we show that the sigma 54 transcriptional activator FlbD, which activates swarmer pole-specific transcription of a subset of late flagellar genes, is also capable of functioning as a pole-specific repressor of the early flagellar fliF operon. DNase I footprinting and methylation interference assays indicate that FlbD binds to regions of the fliF promoter at regions that would be likely to interfere with the binding of RNA polymerase. A mutation that abolishes FlbD binding results in up to a fourfold increase in fliF promoter expression. This mutation alters both the spatial and temporal pattern of fliF expression resulting in the inappropriate expression of the fliF operon in the swarmer pole of the predivisional cell. These results demonstrate that FlbD represses early flagellar gene expression in the swarmer pole of the Caulobacter predivisional cell. This is the first instance in which a protein specifically involved in pole-specific repression has been identified in Caulobacter. The restriction of FlbD activity to the swarmer pole accomplishes two regulatory missions by simultaneously activating late flagellar gene expression and repressing early flagellar genes.

Regulation of cell surface polarity from bacteria to mammals

The generation of unique domains on the cell, cell surface polarity, is critical for differentiation into the diversity of cell structures and functions found in a wide variety of organisms and cells, including the bacterium Caulobacter crescentus, the budding yeast Saccharomyces cerevisiae, and mammalian polarized epithelial cells. Comparison of the mechanisms for establishing polarity in these cells indicates that restricted membrane protein distributions are generated by selective protein targeting to, and selective protein retention at, the cell surface. Initiation of these mechanisms involves reorientation of components of the cytoskeleton and protein transport pathways toward restricted sites at the cell surface and formation of a targeting patch at those sites for selective recruitment and retention of proteins.

The cell cycle-regulated flagellar gene flbF of Caulobacter crescentus is homologous to a virulence locus (lcrD) of Yersinia pestis

We have characterized flbF, a key locus located at the top of the flagellar gene hierarchy of Caulobacter crescentus. This gene is required for transcription from sigma 54 promoters of fla genes expressed late in the cell cycle. We have determined the nucleotide sequence of the gene, mapped the 5' end of the flbF RNA, and examined the pattern of expression in the cell cycle. Our results show that flbF is expressed earlier in the cell cycle than other fla genes, that it is expressed at a low level throughout the stalked cell cycle, and that its 5' regulatory region contains sequences that can be aligned with the sigma 28 promoter consensus reported for enteric bacteria. flbF contains an open reading frame of 700 residues with an amino-terminal half rich in hydrophobic residues that could correspond to six to eight transmembrane domains. The translated flbF sequence is very similar to LcrD (low calcium response) encoded by virulence plasmids of pathogenic Yersinia spp. (G. Plano, S. Barve, and S. Straley, J. Bacteriol. 173:7293-7303, 1991). LcrD and FlbF can be aligned over the entire length of the proteins with the greatest degree of sequence identity (45%) in the hydrophobic amino-terminal region. The high degree of sequence homology of proteins derived from widely differing organisms, including Caulobacter and Yersinia species, suggests that FlbF and LcrD may be representatives of a larger family of regulatory proteins with a common sensor mechanism for modifying responses to appropriate stimuli.

Isolation and characterization of ilvA, ilvBN, and ilvD mutants of Caulobacter crescentus

Caulobacter crescentus strains requiring isoleucine and valine (ilv) for growth were shown by transduction and pulsed-field gel electrophoresis to contain mutations at one of two unlinked loci, ilvB and ilvD. Other C. crescentus strains containing mutations at a third locus, ilvA, required either isoleucine or methionine for growth. Biochemical assays for threonine deaminase, acetohydroxyacid synthase, and dihydroxyacid dehydratase demonstrated that the ilvA locus encodes threonine deaminase, the ilvB locus encodes acetohydroxyacid synthase, and the ilvD locus encodes dihydroxyacid dehydratase. C. crescentus strains resistant to the herbicide sulfometuron methyl, which is known to inhibit the action of certain acetohydroxyacid synthases in a variety of bacteria and plants, were shown to contain mutations at the ilvB locus, further suggesting that an acetohydroxyacid synthase gene resides at this locus. Two recombinant plasmids isolated in our laboratory, pPLG389 and pJCT200, were capable of complementing strains containing the ilvB and ilvD mutations, respectively. The DNA in these plasmids hybridized to the corresponding genes of Escherichia coli and Serratia marcescens, confirming the presence of ilvB-like and ilvD-like DNA sequences at the ilvB and ilvD loci, respectively. However, no hybridization was observed between any of the other enteric ilv genes and C. crescentus DNA. These results suggest that C. crescentus contains an isoleucine-valine biosynthetic pathway which is similar to the corresponding pathway in enteric bacteria but that only the ilvB and ilvD genes contain sequences which are highly conserved at the DNA level.

Timing of flagellar gene expression in the Caulobacter cell cycle is determined by a transcriptional cascade of positive regulatory genes

The Caulobacter crescentus flagellar (fla) genes are organized in a regulatory hierarchy in which genes at each level are required for expression of those at the next lower level. To determine the role of this hierarchy in the timing of fla gene expression, we have examined the organization and cell cycle regulation of genes located in the hook gene cluster. As shown here, this cluster is organized into four multicistronic transcription units flaN, flbG, flaO, and flbF that contain fla genes plus a fifth transcription unit II.1 of unknown function. Transcription unit II.1 is regulated independently of the fla gene hierarchy, and it is expressed with a unique pattern of periodicity very late in the cell cycle. The flaN, flbG, and flaO operons are all transcribed periodically, and flaO, which is near the top of the hierarchy and required in trans for the activation of flaN and flbG operons, is expressed earlier in the cell cycle than the other two transcription units. We have shown that delaying flaO transcription by fusing it to the II.1 promoter also delayed the subsequent expression of the flbG operon and the 27- and 25-kDa flagellin genes that are at the bottom of the regulatory hierarchy. Thus, the sequence and timing of fla gene expression in the cell cycle are determined in large measure by the positions of these genes in the regulatory hierarchy. These results also suggest that periodic transcription is a general feature of fla gene expression in C. crescentus.

Plasmid and chromosomal DNA replication and partitioning during the Caulobacter crescentus cell cycle

Cell division in Caulobacter crescentus yields a swarmer and a stalked cell. Only the stalked cell progeny is able to replicate its chromosome, and the swarmer cell progeny must differentiate into a stalked cell before it too can replicate its chromosome. In an effort to understand the mechanisms that limit chromosomal replication to the stalked cell, plasmid DNA synthesis was analyzed during the developmental cell cycle of C. crescentus, and the partitioning of both the plasmids and the chromosomes to the progeny cells was examined. Unlike the chromosome, plasmids from the incompatibility groups Q and P replicated in all C. crescentus cell types. However, all plasmids tested showed a ten- to 20-fold higher replication rate in the stalked cells than the swarmer cells. We observed that all plasmids replicated during the C. crescentus cell cycle with comparable kinetics of DNA synthesis, even though we tested plasmids that encode very different known (and putative) replication proteins. We determined the plasmid copy number in both progeny cell types, and determined that plasmids partitioned equally to the stalked and swarmer cells. We also reexamined chromosome partitioning in a recombination-deficient strain of C. crescentus, and confirmed an earlier report that chromosomes partition to the progeny stalked and swarmer cells in a random manner that does not discriminate between old and new DNA strands.

Attachment of the adhesive holdfast organelle to the cellular stalk of Caulobacter crescentus

Caulobacters attach to surfaces in the environment via their holdfasts, attachment organelles located at the base of the flagellum in swarmer cells and later at the end of the cellular stalk in the stalked cells which develop from the swarmer cells. There seems to be little specificity with respect to the types of surfaces to which holdfasts adhere. A notable exception is that the holdfast of one cell does not adhere to the cell surface of another caulobacter, except by joining holdfasts, typically forming "rosettes" of stalked cells. Thus, the localized adhesion of the holdfasts to the cells is in some way a specialized attachment. We investigated this holdfast-cell attachment by developing an adhesion screening assay and analyzing several mutants of Caulobacter crescentus CB2A selected to be defective in adhesion. One class of mutants made a normal holdfast by all available criteria, yet the attachment to the cell was very weak, such that the holdfast was readily shed. Another class of mutants made no holdfast at all, but when mixed with a wild-type strain, a mutant of this class participated in rosette formation. The mutant could also attach to the discarded holdfast produced by a shedding mutant. In addition, when rosettes composed of holdfast-defective and wild-type cells were examined, an increase in the number of holdfast-defective cells was correlated with a decrease in the ability of the holdfast material at the center of the rosette to bind colloidal gold particles. Gold particles are one type of surface to which holdfasts adhere well, suggesting that the stalk end and the colloidal gold particles occupy the same sites on the holdfast substance. Taken together, the data support the interpretation that there is a specialized attachment site for the holdfast at the base of the flagellum which later becomes the end of the stalk, but not a specialized region of the holdfast for attachment to this site. Also, attachment to the cell is accomplished by bond formations that occur not only at the time of holdfast production. Thus, we propose that the attachment of the holdfast to the cell is a true adhesion process and that the stalk tip and base of the flagellum must have compositions distinctly different from that of the remainder of the caulobacter cell surface.

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.

Ntr-like promoters and upstream regulatory sequence ftr are required for transcription of a developmentally regulated Caulobacter crescentus flagellar gene

The flbG (hook operon or transcription unit II) and flaN (transcription unit I) operons of Caulobacter crescentus have a -12, -24 nucleotide sequence motif that is very similar to those of the Nif and Ntr promoters of enteric bacteria and Rhizobium spp. and a conserved ftr (flagellar gene transcription regulation) sequence, previously designated II-1 (D. A. Mullin, S. A. Minnich, L.-S. Chen, and A. Newton, J. Mol. Biol. 195:939-943, 1987) at approximately -100. We have used site-directed mutagenesis to examine the role of these sequences in the transcriptional regulation of these periodically expressed flagellar genes. Mutations in the flbG promoter that removed the conserved GC at -12, -13, the GG at -24, -25, or an AC base pair at -18, -19 in the nonconserved sequence between the -12, -24 elements completely eliminated detectable transcription. Mutations at other positions resulted in either a slight decrease (position 26), no change (position 15), or an elevated level (position -16 or -19) of the flbG transcript. By contrast, most of these flbG promoter mutations resulted in greatly elevated levels of transcription from the opposing flaN operon. Similar experiments were used to confirm the location of the flaN promoter to a -12, -24 Nif and Ntr sequence motif. Deletion of all or part of the ftr element or point mutations in the sequence drastically reduced the level of flbG transcript and resulted in increased levels of the flaN transcript. Thus, the conserved sequences at -12 and -24 in flbG and flaN are required for transcription of these genes in vivo, and the ftr element is required for transcription of flbG. This analysis also suggested that the ftr sequence and sequences in the flbG promoter are required for the negative autoregulation of the flbG and flaN operons. We speculate that the flbG and flaN promoters and the ftr element interact in some way to mediate the negative control of these divergent transcription units.

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 and temporal expression of a flagellar basal body gene in Caulobacter crescentus

Caulobacter crescentus assembles a single polar flagellum at a defined time in the cell cycle. The protein components of the flagellar hook and filament are synthesized just prior to their assembly. We demonstrated that the expression of a gene, flaD, that is involved in the formation of the flagellar basal body is under temporal control and is transcribed relatively early in the cell cycle, before the hook and flagellin genes are transcribed. Thus, the order of flagellar gene transcription reflects the order of assembly of the protein components. A mutation in the flaD gene results in the assembly of a partial basal body which is missing the outermost P and L rings as well as the external hook and filament (K.M. Hahnenberger and L. Shapiro, J. Mol. Biol. 194:91-103, 1987). The flaD gene was cloned and characterized by nucleotide sequencing and S1 nuclease protection assays. In contrast to the protein components of the hook and filament, the protein encoded by the flaD gene contains a hydrophobic leader peptide. The predicted amino acid sequence of the leader peptide of flaD is very similar to the leader peptide of the flagellar basal body P ring of Salmonella typhimurium (M. Homma, Y. Komeda, T. Iino, and R.M. Macnab, J. Bacteriol. 169:1493-1498, 1987).

Role of the 25-, 27-, and 29-kilodalton flagellins in Caulobacter crescentus cell motility: method for construction of deletion and Tn5 insertion mutants by gene replacement

Caulobacter crescentus incorporates two distinct, but related proteins into the polar flagellar filament: a 27-kilodalton (kDa) flagellin is assembled proximal to the hook and a 25-kDa flagellin forms the distal end of the filament. These two proteins and a third, related flagellin protein of 29 kDa are encoded by three tandem genes (alpha-flagellin cluster) in the flaEY gene cluster (S.A. Minnich and A. Newton, Proc. Natl. Acad. Sci. USA 84: 1142-1146, 1987). Since point mutations in flagellin genes had not been isolated their requirement for flagellum function and fla gene expression was not known. To address these questions, we developed a gene replacement protocol that uses cloned flagellin genes mutagenized by either Tn5 transposons in vivo or the replacement of specific DNA fragments in vitro by the antibiotic resistance omega cassette. Analysis of gene replacement mutants constructed by this procedure led to several conclusions. (i) Mutations in any of the three flagellin genes do not cause complete loss of motility. (ii) Tn5 insertions in the 27-kDa flagellin gene and a deletion mutant of this gene do not synthesize the 27-kDa flagellin, but they do synthesize wild-type levels of the 25-kDa flagellin, which implies that the 27-kDa flagellin is not required for expression and assembly of the 25-kDa flagellin; these mutants show slightly impaired motility on swarm plates. (iii) Mutant PC7810, which is deleted for the three flagellin genes in the flaEY cluster, does not synthesize the 27- or 29-kDa flagellin, and it is significantly more impaired for motility on swarm plates than mutants with defects in only the 27-kDa flagellin gene. The synthesis of essentially normal levels of 25-kDa flagellin by strain PC7810 confirms that additional copies of the 25-kDa flagellin map outside the flaEY cluster (beta-flagellin cluster) and that these flagellin genes are active. Thus, while the 29- and 27-kDa flagellins are not absolutely essential for motility in C. crescentus, their assembly into the flagellar structure is necessary for normal flagellar function.

Regulation of tryptophan biosynthesis in Caulobacter crescentus

We present an analysis of the expression of the trpE gene and the trpFBA operon in the dimorphic bacterium Caulobacter crescentus. The catalytic activity of component I of anthranilate synthase, the product of the trpE gene, was efficiently inhibited by tryptophan, the end product of the pathway, which suggests that tryptophan biosynthesis is likely controlled at the pathway level in C. crescentus. However, trpFBA mRNA levels and trpE enzyme levels did not vary significantly in wild-type C. crescentus in response to the presence of tryptophan in the growth medium or to growth in minimal versus rich medium. This lack of regulation of the trpE, trpF, trpB, and trpA genes is consistent with the idea that oligotrophic bacteria, such as C. crescentus, do not utilize regulatory mechanisms that greatly alter the biosynthetic capabilities in exponentially growing cells. In contrast, mRNA levels from the 5'-untranslated region and the upstream gene (usg) coding region increased dramatically in C. crescentus trpD or hisB auxotrophs starved for tryptophan or histidine, respectively. Surprisingly, concomitant increases in mRNA levels were not detected from the trpF, trpB, or trpA coding regions downstream in the operon. Thus, severe starvation of C. crescentus for amino acids appears to elicit a strong, general transcriptional response that is not observed in bacteria growing exponentially in medium lacking amino acids.

Localizing the subunit pool for the temporally regulated polar pili of Caulobacter crescentus

The pili of the stalked bacterium Caulobacter crescentus are assembled at a specific time in the life cycle at one pole of the cell and are composed of the monomer protein, pilin. A previous study demonstrated that the onset of pilin synthesis occurs well before pili appear on the surface, suggesting that pilin accumulates within the cell. In the present study, an electron microscope immunocytochemistry assay was used to determine the subcellular location of this unassembled pilin and its fate during pilus assembly and cell division. Populations of synchronously growing cells were embedded in epoxy resin at selected times during the cell cycle. Ultrathin sections were treated with pilin-specific antibody, followed by protein A coupled to colloidal gold. It was determined that the cellular location for unassembled pilin was the cell cytoplasm. All cell membranes and regions of nuclear material were poorly labeled. Quantitation demonstrated that label density increased during the period of pilin synthesis and declined during the period of pilus assembly and maintenance. The pilin pool was not unequally segregated at division; e.g., to the daughter cell that is elaborating pili. Mutants which have simultaneously lost the ability to produce flagella, pili, and other polar organelles, possibly due to alterations in the specialized region of polar organelle assembly, were also examined by the immunocytochemistry technique. There was no significant difference in the pilin pool size relative to the wild type, indicating that pilin synthesis continues in the absence of a functioning assembly site. This pattern of synthesis and assembly for the pilus is significantly different from that of the polar flagellum which is produced at the same time and location on the cell surface. These findings are discussed in relation to the hypothesized organization center at the cell pole which may have a major role in directing the assembly of all the polar structures.

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.

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.

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.

Heat shock protein synthesis during development in Caulobacter crescentus

Caulobacter crescentus cells respond to a sudden increase in temperature by transiently inducing the synthesis of several polypeptides. Two of the proteins induced, Hsp62 and Hsp70, were shown to be analogous to the heat shock proteins of Escherichia coli, GroEL and DnaK, respectively, by immunological cross-reactivity with antibodies raised against the E. coli proteins. Two-dimensional gel electrophoretic resolution of extracts of cells labeled with [35S]methionine during heat shock led to the identification of 20 distinct Hsps in C. crescentus which are coordinately expressed, in response to heat, at the various stages of the cell division cycle. Thus, a developmental control does not seem to be superimposed on the transient activation of the heat shock genes. Nonetheless, under normal temperature conditions, four Hsps (Hsp70, Hsp62, Hsp24b, and Hsp23a) were shown to be synthesized, and their synthesis was cell cycle regulated.

Identification, nucleotide sequence, and control of developmentally regulated promoters in the hook operon region of Caulobacter crescentus

The major flagellar proteins, including the flagellins and the hook protein, are synthesized periodically in the Caulobacter crescentus cell cycle at the time of flagellum assembly. Although fla genes are regulated at the transcriptional level [Ohta, N., Chen, L.-S., Swanson, E. & Newton, A. (1985) J. Mol. Biol. 186, 107-115], the 5' regulatory regions of C. crescentus genes have not been identified. We describe here the results of nuclease S1 protection assays that map the 5' ends of mRNAs synthesized in vivo from transcription units II (hook operon) and II.1 of the hook gene cluster and locate the corresponding promoter regions PII and PII.1. The two promoters are regulated with different periodicities in the cell cycle and have different genetic requirements for expression. The failure to detect transcripts from either PI or PII in Escherichia coli suggests that developmentally regulated promoters of C. crescentus have different recognition sequences from those of E. coli. There is little nucleotide sequence homology between PII and PII.1. There are, however, three regions of homology between PII and the nucleotide sequence 5' to the 29-kDa-flagellin-related gene, and two of these are in regions of dyad symmetry. We discuss the possibility that DNA-protein interactions at homologous nucleotide sequences like those identified in PII are part of a regulatory gene cascade that participates in timing fla gene expression in the C. crescentus cell cycle.

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.

Waveform analysis and structure of flagella and basal complexes from Bdellovibrio bacteriovorus 109J

The structure of sheathed flagella from Bdellovibrio bacteriovorus was investigated. The first three periods of these flagella were characterized by progressively smaller wavelengths and amplitudes in periods more distal to the cell. The damped appearance was due to a single nonrandom transition between two helical structures within each filament. The intersection of the two helices, one of which was a threefold-reduced miniature of the other, occurred at a fixed distance along the filament and resulted in a shift in the flagellar axis. Flagella increased in length as the cells aged and assumed a constant miniature waveform at their distal ends. The core filament was the principal determinant of flagellar morphology. It was composed of 28,000- and 29,500-dalton polypeptides. The 28,000-dalton subunits were located in the cell-proximal segment of the filament, and the 29,500-dalton subunits were located in the more distal region. The heteromorphous appearance of bdellovibrio flagella arose from the sequential assembly of these subunits. The basal complex associated with core filaments was examined because of its potential involvement in sheath formation. Bdellovibrio basal organelles were generally similar to those of other gram-negative species, but appeared to lack a disk analogous to the outer membrane-associated L ring which is a normal component of gram-negative basal complexes.

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.

Isolation of flagellated membrane vesicles from Caulobacter crescentus cells: evidence for functional differentiation of polar membrane domains

An immunoaffinity chromatography procedure is described for the separation of membrane vesicles from Caulobacter crescentus cells into flagellated (polar) vesicles and nonflagellated (nonpolar) vesicles. Analysis by two-dimensional gel electrophoresis shows that a number of proteins are associated primarily with either the polar or the nonpolar fraction, and this result suggests that the envelope of these cells is organized into at least two relatively stable domains. Radioimmunoassay also shows that the membrane pool of flagellin, which is known to behave as a precursor in the assembly of the flagellar filament, may be localized exclusively in the polar membrane domain. Thus, the results provide biochemical evidence for the structural and functional differentiation of the C. crescentus cell envelope. These findings are consistent with a model we proposed previously to explain the targeting of surface structures to the new cell pole of C. crescentus. The immunoadsorption approach described here should be useful in the further investigation of this problem, as well as in the fractionation of membrane domains with characteristic surface antigens in other systems.

Genetic analysis and characterization of a Caulobacter crescentus mutant defective in membrane biogenesis

A mutant of Caulobacter crescentus has been isolated which has an auxotrophic requirement for unsaturated fatty acids or biotin for growth on medium containing glucose as the carbon source. This mutant exhibits a pleiotropic phenotype which includes (i) the auxotrophic requirement, (ii) cell death in cultures attempting to grow on glucose in the absence of fatty acids or biotin, and (iii) a major change in the outer membrane protein composition before cell death. This genetic lesion did not appear to affect directly a fatty acid biosynthetic reaction because fatty acid and phospholipid syntheses were found to continue in the absence of supplement. Oleic acid repressed fatty acid biosynthesis and induced fatty acid degradation in the wild-type parent, AE5000 . The mutant strain, AE6000 , was altered in both of these regulatory functions. The AE6000 mutant also showed specific inhibition of the synthesis of outer membrane and flagellar proteins. Total phospholipid, DNA, RNA, and protein syntheses were unaffected. The multiple phenotypes of the AE6000 mutant were found to cosegregate and to map between hclA and lacA on the C. crescentus chromosome. The defect in this mutant appears to be associated with a regulatory function in membrane biogenesis and provides evidence for a direct coordination of membrane protein synthesis and lipid metabolism in C. crescentus.

Caulobacter crescentus fatty acid-dependent cell cycle mutant

A fatty acid auxotroph of Caulobacter crescentus, AE6001, which displays a strict requirement for unsaturated fatty acids to grow on glucose as the carbon source has been isolated. Starvation of AE6001 for unsaturated fatty acids resulted in a block in the cell cycle. Starved cultures accumulated at the predivisional cell stage after a round of DNA replication had been completed and after a flagellum had been assembled at the pole of the cell. Cell division and cell growth failed to occur probably because the mutant was unable to synthesize a membrane. An analysis of double mutants containing the fatB503 allele and other mutations in membrane biogenesis demonstrated that the cell cycle of AE6001 blocked at a homeostatic state. The addition of oleic acid to starved cultures permitted cell division and the initiation of a new round of DNA replication. The coincident block in both the initiation of DNA replication and membrane assembly, exhibited by starved cultures of this mutant, suggests that the fatB503 gene product may be involved in the coordination of these events.

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.

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.

Caulobacter flagellin mRNA segregates asymmetrically at cell division

Molecular processes which promote the spatial localization of subcellular components are fundamental to cell development and differentiation. At various stages in development unequal segregation of molecular information must occur to result in the differentiated characteristics which distinguish cell progeny. Biological attributes of the dimorphic bacterium, Caulobacter crescentus, provide an experimental system permitting examination of the generation of asymmetry at the molecular level. When a Caulobacter cell divides, two different daughter cells are produced--a motile swarmer cell with a polar flagellum and a non-motile cell with a static appendage referred to as a stalk. The two cell types are distinct with respect to surface morphology, developmental potential, protein composition and biosynthetic capabilities. One of the more conspicuous manifestations of asymmetric expression of macromolecules in this system, the flagellum, has been studied extensively. We have cloned the flagellin genes of Caulobacter and report here the use of these sequences as probes to demonstrate that (1) the level of flagellin mRNA is regulated during the cell cycle in a pattern coincident with flagellum polypeptide synthesis and (2) flagellin mRNA synthesized before cell division is segregated with progeny swarmer cells. This provides molecular evidence of specific partitioning of an mRNA at the time of cell division.

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.

Cell surface patterning and morphogenesis: biogenesis of a periodic surface array during Caulobacter development

Shape changes, extended processes, and other surface elaborations are associated with cellular differentiation, and the cell membranes involved with these developmental changes often are reshaped without a major alteration in biochemical composition. Caulobacter crescentus produces a hexagonally-packed periodic surface layer that covers the entire cell and further, mimics some of the membrane-mediated changes of higher organisms by forming a membranous stalk during its distinctive life cycle. Growth of the surface layer was examined during the cell cycle by treating synchronously growing cells with surface layer antibody, continuing growth, and then labeling for electron microscopy with a protein A-colloidal gold conjugate. Three regions of distinctive surface array biogenesis were resolved. The periodic surface layer on the main cell body was enlarged by insertion of new material at numerous uniformly distributed points. In contrast, the surface layer on the stalk appeared as entirely new synthesis. In examining growth of the stalk in subsequent generations, we noted that growth of stalk surface persisted at the stalk-cell body junction. The region of cell division also showed a pattern of entirely new surface layer production at late stages in division, similar to the stalk. The immunocytological method also facilitated a careful examination of stalk initiation and growth. Although initiation was under precise temporal and spatial regulation, the rate of stalk elongation was variable from cell to cell and apparently no longer under cell cycle control. The similarity of surface layer biogenesis on the stalk and the site of cell division may be a significant reflection of other events occurring at the cell pole. A model suggested by this and other studies that can account for the temporal pattern of polar morphogenesis is discussed, as is the potential relationship between the geometrically ordered surface array and the formation or maintenance of the stalk.

Genetic mapping with Tn5-derived auxotrophs of Caulobacter crescentus

Chromosomal insertions of Tn5 in Caulobacter crescentus displayed complete stability upon transduction and proved useful in strain building on complex media. RP4-primes constructed in vitro containing C. crescentus genomic sequences in the HindIII site of the kanamycin resistance gene failed to show enhanced or directed chromosome mobilization abilities. One of these kanamycin-sensitive RP4 derivatives, pVS1, was used as a mobilization vector in conjugation experiments on complex media where chromosomal Tn5 transfer to the recipient was selected. pVS1-mediated transfer of Tn5-induced auxotrophic mutations occurred at frequencies of 10(-6) to 10(-8) per donor cell. During conjugation with Tn5-encoded kanamycin resistance as the selected marker, Tn5 remained in its donor-associated locus in 85 to 100% of the transconjugants. A collection of eight temperature-sensitive donor strains bearing Tn5 insertion mutations from various regions of the C. crescentus genetic map were used to provide a rapid means for the determination of the map location of a new mutation. Use of the techniques described in this paper allowed an expansion of the C. crescentus genetic map to include the relative locations of 32 genes.

Isolation and expression of cloned hook protein gene from Caulobacter crescentus

Previous genetic analysis of Caulobacter crescentus showed that the periodic synthesis of hook protein, flagellin A, and flagellin B, the major flagellar subunits, is coupled in some way to chromosome replication. To examine the regulation of flagellar gene expression at the molecular level, we isolated the gene that codes for the 72,000-dalton hook protein. A specific 125I-labeled anti-hook protein IgG was used to screen a hybrid lambdaL47.1 bank of 4,500 clones and to compare peptide maps of the cloned gene product with purified hook protein. Restriction analysis of DNA from the positive lambda clones and plasmid subclones showed that the structural gene for the hook protein is contained on a 2.3-kilobase (kb) BamHI fragment. The direction of transcription was established by demonstrating the inducibility of hook protein gene in strains with the 2.3-kb fragment fused to the Escherichia coli lipoprotein gene-lactose gene promoter-operator region of pIN-II. Preliminary genomic analysis showed that the hook gene occupies a single location on the C. crescentus chromosome. These results suggest that the periodic expression of the hook protein gene in the cell cycle does not involve a major or persistent rearrangement of the 2.3-kb coding sequence during the cell cycle.

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

The flagellum of Caulobacter crescentus is composed of two flagellin polypeptide monomers which are distinguished by molecular weight and are closely related by biochemical and immunological criteria (C. Lagenaur and N. Agabian, J. Bacteriol. 132:731-733, 1977). The synthesis and assembly of these two flagellin proteins are developmentally regulated, and the periodicity of expression for each is distinct (C. Lagenaur and N. Agabian, J. Bacteriol. 135:1062-1069, 1978; M. A. Osley, M. Sheffery, and A. Newton, Cell 12:393-400, 1977). To understand the genetic and functional relationship between the 25,000- and 27,500-molecular-weight flagellins of C. crescentus CB15, a detailed comparative analysis of their protein structure was made, using a number of techniques, including one- and two-dimensional peptide mapping, a novel procedure of peptide alignment, and amino terminal amino acid sequence analysis. The tryptic peptides generated by each of the flagellins were compared by two-dimensional thin-layer chromatography. This peptide map analysis indicated that approximately 36% of the peptides generated from these two proteins had similar migration properties. Together with biochemical and immunological criteria, the two-dimensional peptide map suggested some structural relatedness between the monomers. However, a comparison of peptide fragments generated during partial protease digestion of each protein by a method of one-dimensional mapping indicated that the two proteins are structurally unique. A peptide alignment technique was developed to directly compare the primary structure of these proteins. In the peptide alignment procedure the amino terminus of each protein is radioactively labeled. After partial enzymatic digestion, the peptides are fractionated by polyacrylamide gel electrophoresis: those labeled at the amino terminus are then resolved by subsequent autoradiography. Each digest contains a family of amino-terminal-labeled fragments, the sizes of which reflect the sequential alignment of cleavage sites in the protein. A comparison of the alignment of specific cleavage sites of the two flagellins by this technique further established that each flagellin is structurally unique, particularly in the carboxyl terminal region. Finally, comparison of the amino terminal amino acid sequences indicated that the amino terminal region of both flagellins is highly conserved, but that the two polypeptides are clearly not identical. These findings strongly indicate that the two flagellins are encoded by distinct genetic loci and are not the product of novel processing of a single larger precursor.

Regulation of polypeptide synthesis during Caulobacter development: two-dimensional gel analysis

The gram-negative bacterium Caulobacter crescentus progresses through three distinct morphological transitions, including both motile and nonmotile cell types, during its cell cycle. Assessment of the extent of regulation of polypeptide synthesis during these transitions was carried out with two-dimensional gel electrophoresis of whole-cell extracts. Synchronous cells were pulse-labeled with 14C-amino acids for 10-min intervals throughout the entire 2-h cell cycle. The radioactively labeled polypeptides were analyzed by two-dimensional polyacrylamide gel electrophoresis. Autoradiograms resulting from fluorography of the second dimension provided the detection of approximately 1,000 unique spots. The 600 predominant polypeptide spots, representing approximately 40% of the coding capacity of Caulobacter deoxyribonucleic acid, were analyzed for major changes in their synthetic rates. Quantitation by densitometric scanning of individual polypeptide spots represented on the sequential fluorograms demonstrated significant changes in the temporal synthesis of 6% of the polypeptides. Extracts from asynchronous cells were fractionated to obtain total-membrane and deoxyribonucleic acid-binding polypeptide fractions. Subsequent electrophoresis of these cellular fractions revealed approximately 100 membrane polypeptides and 25 deoxyribonucleic acid-binding polypeptides. Eight of the regulated polypeptides were identified as membrane or deoxyribonucleic acid-binding proteins. The regulated polypeptides can be grouped into three main categories based on their interval of synthesis. The three categories are in direct correlation with the three distinct cell cycle stages. This analysis has also revealed a unique transition period in the cell cycle in which a significant proportion of gene expression is regulated.

The caulobacters: ubiquitous unusual bacteria

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