Positional information during Caulobacter cell differentiation

Sponge digestive system diversity and evolution: filter feeding to carnivory

Sponges are an ancient basal life form, so understanding their evolution is key to understanding all metazoan evolution. Sponges have very unusual feeding mechanisms, with an intricate network of progressively optimized filtration units: from the simple choanocyte lining of a central cavity, or spongocoel, to more complex chambers and canals. Furthermore, in a single evolutionary event, a group of sponges transitioned to carnivory. This major evolutionary transition involved replacing the filter-feeding apparatus with mobile phagocytic cells that migrate collectively towards the trapped prey. Here, we focus on the diversity and evolution of sponge nutrition systems and the amazing adaptation to carnivory.

Degradation of a Caulobacter soluble cytoplasmic chemoreceptor is ClpX dependent

In order to determine whether ClpXP-mediated proteolysis is a common mechanism used to regulate the chemotaxis machinery during the cell cycle of Caulobacter crescentus, we have characterized a soluble cytoplasmic chemoreceptor, McpB. The mcpB gene lies adjacent to the major chemotaxis operon, which encodes 12 chemotaxis proteins, including the membrane chemoreceptor McpA. Like McpA, McpB possesses a C-terminal CheBR docking motif and three potential methylation sites, which we suggest are methylated. The McpB protein is degraded via a ClpX-dependent pathway during the swarmer-to-stalked cell transition, and a motif, which is 3 amino acids N-terminal to the McpB CheBR docking site, is required for proteolysis. Analysis of the degradation signal in McpB and McpA reveals a common motif present in the other four chemoreceptors that possess CheBR docking sites. A green fluorescent protein (GFP) fusion bearing 58 amino acids from the C terminus of McpA, which contains this motif, is degraded, suggesting that the C-terminal sequence is sufficient to confer ClpXP protease susceptibility.

Conserved response regulator CtrA and IHF binding sites in the alpha-proteobacteria Caulobacter crescentus and Rickettsia prowazekii chromosomal replication origins

CzcR is the Rickettsia prowazekii homolog of the Caulobacter crescentus global response regulator CtrA. CzcR expression partially compensates for developmental defects in ctrA mutant C. crescentus cells, and CzcR binds to all five CtrA binding sites in the C. crescentus replication origin. Conversely, CtrA binds to five similar sites in the putative R. prowazekii replication origin (oriRp). Also, Escherichia coli IHF protein binds over a central CtrA binding site in oriRp. Therefore, CtrA and IHF regulatory proteins have similar binding patterns in both replication origins, and we propose that CzcR is a global cell cycle regulator in R. prowazekii.

Temporal regulation of genes encoding the flagellar proximal rod in Caulobacter crescentus

The gram-negative bacterium Caulobacter crescentus has a life cycle that includes two distinct and separable developmental stages, a motile swarmer phase and a sessile stalked phase. The cell cycle-controlled biogenesis of the single polar flagellum of the swarmer cell is the best-studied aspect of this developmental program. The flagellar regulon is arranged into a rigid trans-acting hierarchy of gene expression in which successful expression of early genes is required for the expression of genes that are later in the hierarchy and in which the order of gene expression mirrors the order of assembly of gene products into the completed flagellum. The flgBC-fliE genes were identified as a result of the C. crescentus genome sequencing project and encode the homologues of two flagellar proximal rod proteins, FlgB and FlgC, and one conserved protein, FliE, that is of unknown function. Footprint assays on a DNA fragment containing the operon promoter as well as in vivo mutant suppressor analysis of promoter mutations indicate that this operon is controlled by the cell cycle response regulator CtrA, which with sigma(70) is responsible for regulating transcription of other early flagellar genes in C. crescentus. Promoter analysis, timing of expression, and epistasis experiments place these genes outside of the flagellar regulatory hierarchy; they are expressed in class II mutants, and flgB deletions do not prevent class III gene expression. This operon is also unusual in that it is expressed from a promoter that is divergent from the class II operon containing fliP, which encodes a member of the flagellum-specific protein export apparatus.

Differentiation of chitinase-active and non-chitinase-active subpopulations of a marine bacterium during chitin degradation

The ability of marine bacteria to adhere to detrital particulate organic matter and rapidly switch on metabolic genes in an effort to reproduce is an important response for bacterial survival in the pelagic marine environment. The goal of this investigation was to evaluate the relationship between chitinolytic gene expression and extracellular chitinase activity in individual cells of the marine bacterium Pseudoalteromonas sp. strain S91 attached to solid chitin. A green fluorescent protein reporter gene under the control of the chiA promoter was used to evaluate chiA gene expression, and a precipitating enzyme-linked fluorescent probe, ELF-97-N-acetyl-beta-D-glucosaminide, was used to evaluate extracellular chitinase activity among cells in the bacterial population. Evaluation of chiA expression and ELF-97 crystal location at the single-cell level revealed two physiologically distinct subpopulations of S91 on the chitin surface: one that was chitinase active and remained associated with the surface and another that was non-chitinase active and released daughter cells into the bulk aqueous phase. It is hypothesized that the surface-associated, non-chitinase-active population is utilizing chitin degradation products that were released by the adjacent chitinase-active population for cell replication and dissemination into the bulk aqueous phase.

The cyanobacterial circadian system: a clock apart

Several new molecular components of the circadian clocks of animals, fungi, and bacteria have been unveiled in the past two years. Enough parts are now identified to indicate that there is more than one way to build a biological clock, although there are parallels in the cycling molecular events among disparate groups of organisms.

A developmentally regulated chromosomal origin of replication uses essential transcription elements

Only one of the two chromosomes in the asymmetric Caulobacter predivisional cell initiates replication in the progeny cells. Transcription from a strong promoter within the origin occurs uniquely from the replication-competent chromosome at the stalked pole of the predivisional cell. This regulated promoter has an unusual sequence organization, and transcription from this promoter is essential for regulated (cell type-specific) replication. Our analysis defines a new class of bacterial origins and suggests a coupling between transcription and replication that is consistent with the phylogenetic relationship of Caulobacter to the ancestral mitochondrion.

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.

Asymmetric expression of the gyrase B gene from the replication-competent chromosome in the Caulobacter crescentus predivisional cell

The bacterium Caulobacter crescentus undergoes an asymmetric cell division resulting in the formation of two different daughter cells, a motile swarmer cell and a nonmotile stalked cell. These two cell types differ in their program of gene expression, their ability to replicate DNA, and the physical properties of their nucleoids. We show here that two genes, gyrB (encoding the gyrase B subunit) and orf-1, are specifically transcribed from the chromosome in the portion of the predivisional cell destined for the progeny stalked cell. This is in contrast to a subset of flagellar genes which are transcribed from the chromosome in the incipient swarmer portion of the predivisional cell. gyrB and orf-1 are within a newly identified cluster of genes involved in DNA replication and recombination, including dnaN and recF. The transcription of gyrB and orf1 occurs from the replication-competent chromosome in stalked and predivisional cells and is silenced in swarmer cells. We hypothesize that selective silencing of groups of genes in the chromosomes at the swarmer and stalked poles of the predivisional cell results in the different developmental programs and the difference in replicative ability of the two progeny cells.

Polarized cells, polar actions

The recognition of polar bacterial organization is just emerging. The examples of polar localization given here are from a variety of bacterial species and concern a disparate array of cellular functions. A number of well-characterized instances of polar localization of bacterial proteins, including the chemoreceptor complex in both C. crescentus and E. coli, the maltose-binding protein in E. coli, the B. japonicum surface attachment proteins, and the actin tail of L. monocytogenes within a mammalian cell, involve proteins or protein complexes that facilitate bacterial interaction with the environment, either the extracellular milieux or that within a plant or mammalian host. The significance of this observation remains unclear. Polarity in bacteria poses many problems, including the necessity for a mechanism for asymmetrically distributing proteins as well as a mechanism by which polar localization is maintained. Large structures, such as a flagellum, are anchored at the pole by means of the basal body that traverses the peptidoglycan wall. But for proteins and small complexes, whether in the periplasm or the membrane, one must invoke a mechanism that prevents the diffusion of these proteins away from the cell pole. Perhaps the periplasmic proteins are retained at the pole by the presence of the periseptal annulus (35). The constraining features for membrane components are not known. For large aggregates, such as the clusters of MCP, CheA, and CheW complexes, perhaps the size of the aggregate alone prevents displacement. In most cases of cellular asymmetry, bacteria are able to discriminate between the new pole and the old pole and to utilize this information for localization specificity. The maturation of new pole to old pole appears to be a common theme as well. Given numerous examples reported thus far, we propose that bacterial polarity displays specific rules and is a more general phenomenon than has been previously recognized.

Spatial and temporal phosphorylation of a transcriptional activator regulates pole-specific gene expression in Caulobacter

Polar localization of proteins in the Caulobacter predivisional cell results in the formation of two distinct progeny cells, a motile swarmer cell and a sessile stalked cell. The transcription of several flagellar promoters is localized to the swarmer pole of the predivisional cell. We present evidence that the product of the flbD gene is the transcriptional activator of these promoters. We show that FlbD is distributed in all cell types and in both poles of the predivisional cell. We also demonstrate that FlbD can be phosphorylated, and that a FlbD kinase activity is under cell cycle control. Cells expressing a FlbD mutant that should activate transcription in the absence of phosphorylation, exhibited an alteration in the temporal pattern of flagellin transcription. Furthermore, predivisional cells expressing the mutant FlbD failed to polarly localize flagellin synthesis. We propose that the phosphorylation of FlbD is restricted to the swarmer compartment of the predivisional cell, and serves as the control point for regulating the spatial transcription of flagellar promoters.

Polarized distribution of Listeria monocytogenes surface protein ActA at the site of directional actin assembly

The facultative intracellular pathogen Listeria monocytogenes can infect host tissues by using directional actin assembly to propel itself from one cell into another. The movement is generated by continuous actin assembly from one end of the bacterium into a tail, which is left behind in the cytoplasm. Bacterial actin assembly requires expression of the bacterial gene actA. We have used immunocytochemistry to show that the actA gene product, ActA, is distributed asymmetrically on the bacterial surface: it is not expressed at one pole and is increasingly concentrated towards the other. This polarized distribution of ActA was linked to bacterial division: ActA protein was not, or only faintly, expressed at the pole that had been formed during the previous division. On intracellular bacteria ActA was expressed at the site of actin assembly, suggesting that ActA may be involved in actin filament nucleation off the bacterial surface. We predict that the asymmetrical distribution of this protein is required for the ability of intracellular Listeria to move in the direction of the non-ActA expressing pole.

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.

A developmentally regulated Caulobacter flagellar promoter is activated by 3' enhancer and IHF binding elements

The transcription of a group of flagellar genes is temporally and spatially regulated during the Caulobacter crescentus cell cycle. These genes all share the same 5' cis-regulatory elements: a sigma 54 promoter, a binding site for integration host factor (IHF), and an enhancer sequence, known as the ftr element. We have partially purified the ftr-binding proteins, and we show that they require the same enhancer sequences for binding as are required for transcriptional activation. We have also partially purified the Caulobacter homolog of IHF and demonstrate that it can facilitate in vitro integrase-mediated lambda recombination. Using site-directed mutagenesis, we provide the first demonstration that natural enhancer sequences and IHF binding elements that reside 3' to the sigma 54 promoter of a bacterial gene, flaNQ, are required for transcription of the operon, in vivo. The IHF protein and the ftr-binding protein is primarily restricted to the predivisional cell, the cell type in which these promoters are transcribed. flaNQ promoter expression is localized to the swarmer pole of the predivisional cell, as are other flagellar promoters that possess these regulatory sequences 5' to the start site. The requirement for an IHF binding site and an ftr-enhancer element in spatially transcribed flagellar promoters indicates that a common mechanism may be responsible for both temporal and polar transcription.

Early Caulobacter crescentus genes fliL and fliM are required for flagellar gene expression and normal cell division

The biogenesis of the Caulobacter crescentus polar flagellum requires the expression of more than 48 genes, which are organized in a regulatory hierarchy. The flbO locus is near the top of the hierarchy, and consequently strains with mutations in this locus are nonmotile and lack the flagellar basal body complex. In addition to the motility phenotype, mutations in this locus also cause abnormal cell division. Complementing clones restore both motility and normal cell division. Sequence analysis of a complementing subclone revealed that this locus encodes at least two proteins that are homologs of the Salmonella typhimurium and Escherichia coli flagellar proteins FliL and FliM. FliM is thought to be a switch protein and to interface with the flagellum motor. The C. crescentus fliL and fliM genes form an operon that is expressed early in the cell cycle. Tn5 insertions in the fliM gene prevent the transcription of class II and class III flagellar genes, which are lower in the regulatory hierarchy. The start site of the fliLM operon lies 166 bp from the divergently transcribed flaCBD operon that encodes several basal body genes. Sequence comparison of the fliL transcription start site with those of other class I genes, flaS and flaO, revealed a highly conserved 29-bp sequence in a potential promoter region that differs from sigma 70, sigma 54, sigma 32, and sigma 28 promoter sequences, suggesting that at least three class I genes share a unique 5' regulatory region.

Polar localization of a bacterial chemoreceptor

The bacterial chemotaxis signal transducer MCP is an integral membrane receptor protein. The chemoreceptor is localized at the flagellum-bearing pole of Caulobacter crescentus swarmer cells. Amino-terminal sequences of the MCP target the protein to the membrane while the carboxy-terminal portion of the protein is responsible for polar localization. The C. crescentus and Escherichia coli MCPs have highly conserved carboxy-terminal domains, and when an E. coli MCP is expressed in C. crescentus, it is targeted to the swarmer cell progeny. These results suggest that subcellular localization of a prokaryotic protein involves interaction of specific regions of the protein with unique cell sites that contain either localized binding proteins or a specific secretory apparatus.