Regulated degradation of chromosome replication proteins DnaA and CtrA in Caulobacter crescentus

DnaA protein binds bacterial replication origins and it initiates chromosome replication. The Caulobacter crescentus DnaA also initiates chromosome replication and the C. crescentus response regulator CtrA represses chromosome replication. CtrA proteolysis by ClpXP helps restrict chromosome replication to the dividing cell type. We report that C. crescentus DnaA protein is also selectively targeted for proteolysis but DnaA proteolysis uses a different mechanism. DnaA protein is unstable during both growth and stationary phases. During growth phase, DnaA proteolysis ensures that primarily newly made DnaA protein is present at the start of each replication period. Upon entry into stationary phase, DnaA protein is completely removed while CtrA protein is retained. Cell cycle arrest by sudden carbon or nitrogen starvation is sufficient to increase DnaA proteolysis, and relieving starvation rapidly stabilizes DnaA protein. This starvation-induced proteolysis completely removes DnaA protein even while DnaA synthesis continues. Apparently, C. crescentus relies on proteolysis to adjust DnaA in response to such rapid nutritional changes. Depleting the C. crescentus ClpP protease significantly stabilizes DnaA. However, a dominant-negative clpX allele that blocks CtrA degradation, even when combined with a clpA null allele, did not decrease DnaA degradation. We suggest that either a novel chaperone presents DnaA to ClpP or that ClpX is used with exceptional efficiency so that when ClpX activity is limiting for CtrA degradation it is not limiting for DnaA degradation. This unexpected and finely tuned proteolysis system may be an important adaptation for a developmental bacterium that is often challenged by nutrient-poor environments.     

Regulation of the replication initiator DnaA in Caulobacter crescentus

The decision to initiate DNA replication is a critical step in the cell cycle of all organisms. In nearly all bacteria, replication initiation requires the activity of the conserved replication initiation protein DnaA. Due to its central role in cell cycle progression, DnaA activity must be precisely regulated. This review summarizes the current state of DnaA regulation in the asymmetrically dividing α-proteobacterium Caulobacter crescentus, an important model for bacterial cell cycle studies. Mechanisms will be discussed that regulate DnaA activity and abundance under optimal conditions and in coordination with the asymmetric Caulobacter cell cycle. Furthermore, we highlight recent findings of how regulated DnaA synthesis and degradation collaborate to adjust DnaA abundance under stress conditions. The mechanisms described provide important examples of how DNA replication is regulated in an α-proteobacterium and thus represent an important starting point for the study of DNA replication in many other bacteria. This article is part of a Special Issue entitled: Dynamic gene expression, edited by Prof. Patrick Viollier.     

S-layer anchoring and localization of an S-layer-associated protease in Caulobacter crescentus

The S-layer of the gram-negative bacterium Caulobacter crescentus is composed of a single protein, RsaA, that is secreted and assembled into a hexagonal crystalline array that covers the organism. Despite the widespread occurrence of comparable bacterial S-layers, little is known about S-layer attachment to cell surfaces, especially for gram-negative organisms. Having preliminary indications that the N terminus of RsaA anchors the monomer to the cell surface, we developed an assay to distinguish direct surface attachment from subunit-subunit interactions where small RsaA fragments are incubated with S-layer-negative cells to assess the ability of the fragments to reattach. In doing so, we found that the RsaA anchoring region lies in the first approximately 225 amino acids and that this RsaA anchoring region requires a smooth lipopolysaccharide species found in the outer membrane. By making mutations at six semirandom sites, we learned that relatively minor perturbations within the first approximately 225 amino acids of RsaA caused loss of anchoring. In other studies, we confirmed that only this N-terminal region has a direct role in S-layer anchoring. As a by-product of the anchoring studies, we discovered that Sap, the C. crescentus S-layer-associated protease, recognized a cleavage site in the truncated RsaA fragments that is not detected by Sap in full-length RsaA. This, in turn, led to the discovery that Sap was an extracellular membrane-bound protease, rather than intracellular, as previously proposed. Moreover, Sap was secreted to the cell surface primarily by the S-layer type I secretion apparatus.     

Fatty acid degradation in Caulobacter crescentus.

Fatty acid degradation was investigated in Caulobacter crescentus, a bacterium that exhibits membrane-mediated differentiation events. Two strains of C. crescentus were shown to utilize oleic acid as sole carbon source. Five enzymes of the fatty acid beta-oxidation pathway, acyl-coenzyme A (CoA) synthase, crotonase, thiolase, beta-hydroxyacyl-CoA dehydrogenase, and acyl-CoA dehydrogenase, were identified. The activities of these enzymes were significantly higher in C. crescentus than the fully induced levels observed in Escherichia coli. Growth in glucose or glucose plus oleic acid decreased fatty acid uptake and lowered the specific activity of the enzymes involved in beta-oxidation by 2- to 3-fold, in contrast to the 50-fold glucose repression found in E. coli. The mild glucose repression of the acyl-CoA synthase was reversed by exogenous dibutyryl cyclic AMP. Acyl-CoA synthase activity was shown to be the same in oleic acid-grown cells and in cells grown in the presence of succinate, a carbon source not affected by catabolite repression. Thus, fatty acid degradation by the beta-oxidation pathway is constitutive in C. crescentus and is only mildly affected by growth in the presence of glucose. Tn5 insertion mutants unable to form colonies when oleic acid was the sole carbon source were isolated. However, these mutants efficiently transported fatty acids and had beta-oxidation enzyme levels comparable with that of the wild type. Our inability to obtain fatty acid degradation mutants after a wide search, coupled with the high constitutive levels of the beta-oxidation enzymes, suggest that fatty acid turnover, as has proven to be the case fatty acid biosynthesis, might play an essential role in membrane biogenesis and cell cycle events in C. crescentus.     

SpoT regulates DnaA stability and initiation of DNA replication in carbon-starved Caulobacter crescentus

Cell cycle progression and polar differentiation are temporally coordinated in Caulobacter crescentus. This oligotrophic bacterium divides asymmetrically to produce a motile swarmer cell that represses DNA replication and a sessile stalked cell that replicates its DNA. The initiation of DNA replication coincides with the proteolysis of the CtrA replication inhibitor and the accumulation of DnaA, the replication initiator, upon differentiation of the swarmer cell into a stalked cell. We analyzed the adaptive response of C. crescentus swarmer cells to carbon starvation and found that there was a block in both the swarmer-to-stalked cell polar differentiation program and the initiation of DNA replication. SpoT is a bifunctional synthase/hydrolase that controls the steady-state level of the stress-signaling nucleotide (p)ppGpp, and carbon starvation caused a SpoT-dependent increase in (p)ppGpp concentration. Carbon starvation activates DnaA proteolysis (B. Gorbatyuk and G. T. Marczynski, Mol. Microbiol. 55:1233-1245, 2005). We observed that SpoT is required for this phenomenon in swarmer cells, and in the absence of SpoT, carbon-starved swarmer cells inappropriately initiated DNA replication. Since SpoT controls (p)ppGpp abundance, we propose that this nucleotide relays carbon starvation signals to the cellular factors responsible for activating DnaA proteolysis, thereby inhibiting the initiation of DNA replication. SpoT, however, was not required for the carbon starvation block of the swarmer-to-stalked cell polar differentiation program. Thus, swarmer cells utilize at least two independent signaling pathways to relay carbon starvation signals: a SpoT-dependent pathway mediating the inhibition of DNA replication initiation, and a SpoT-independent pathway(s) that blocks morphological differentiation.     

The Caulobacter crescentus chromosome replication origin evolved two classes of weak DnaA binding sites

The Caulobacter crescentus replication initiator DnaA and essential response regulator CtrA compete to control chromosome replication. The C. crescentus replication origin (Cori) contains five strong CtrA binding sites but only two apparent DnaA boxes, termed G-boxes (with a conserved second position G, TGATCCACA). Since clusters of DnaA boxes typify bacterial replication origins, this discrepancy suggested that C. crescentus DnaA recognizes different DNA sequences or compensates with novel DNA-binding proteins. We searched for novel DNA sites by scanning mutagenesis of the most conserved Cori DNA. Autonomous replication assays showed that G-boxes and novel W-boxes (TCCCCA) are essential for replication. Further analyses showed that C. crescentus DnaA binds G-boxes with moderate and W-boxes with very weak affinities significantly below DnaA's capacity for high-affinity Escherichia coli-boxes (TTATCCACA). Cori has five conserved W-boxes. Increasing W-box affinities increases or decreases autonomous replication depending on their strategic positions between the G-boxes. In vitro, CtrA binding displaces DnaA from proximal G-boxes and from distal W-boxes implying CtrA-DnaA competition and DnaA-DnaA cooperation between G-boxes and W-boxes. Similarly, during cell cycle progression, CtrA proteolysis coincides with DnaA binding to Cori. We also observe highly conserved W-boxes in other replication origins lacking E. coli-boxes. Therefore, strategically weak DnaA binding can be a general means of replication control.     

Phospholipid biosynthesis is required for stalk elongation in Caulobacter crescentus.

Membrane phospholipid synthesis was inhibited in Caulobacter crescentus by growth of a glycerol auxotroph in the absence of glycerol or by treatment with the antibiotic cerulenin. It was observed that the final step in the swarmer cell-to-stalked cell transition, stalk elongation, was inhibited under these conditions. Since an early effect of inhibiting phospholipid synthesis in C. crescentus is the termination of deoxyribonucleic acid (DNA) replication (I. Contreras, R. Bender, A. Weissborn, K. Amemiya J. D. Mansour, S. Henry, and L. Shapiro, J. Mol. Biol. 138:401-410, 1980), we questioned whether the inhibition of stalk formation was due directly to the inhibition phospholipid synthesis or secondarily to the inhibition of DNA synthesis. Under conditions which inhibited DNA synthesis but permitted phospholipid synthesis, i.e., growth of a temperature-sensitive DNA elongation mutant at the restrictive temperature or treatment with hydroxy-urea, stalk elongation occurred normally. Therefore phospholipid synthesis is required for stalk elongation in C. crescentus.     

RNA-controlled regulation in Caulobacter crescentus

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Screen for localized proteins in Caulobacter crescentus

Precise localization of individual proteins is required for processes such as motility, chemotaxis, cell-cycle progression, and cell division in bacteria, but the number of proteins that are localized in bacterial species is not known. A screen based on transposon mutagenesis and fluorescence activated cell sorting was devised to identify large numbers of localized proteins, and employed in Caulobacter crescentus. From a sample of the clones isolated in the screen, eleven proteins with no previously characterized localization in C. crescentus were identified, including six hypothetical proteins. The localized hypothetical proteins included one protein that was localized in a helix-like structure, and two proteins for which the localization changed as a function of the cell cycle, suggesting that complex three-dimensional patterns and cell cycle-dependent localization are likely to be common in bacteria. Other mutants produced localized fusion proteins even though the transposon has inserted near the 5' end of a gene, demonstrating that short peptides can contain sufficient information to localize bacterial proteins. The screen described here could be used in most bacterial species.     

Transposon mutagenesis in Caulobacter crescentus

Transposons Tn5 (Km) and Tn7 (Tp and Sm) were transferred to Caulobacter crescentus via P-type antibiotic resistance factors. Transposition was demonstrated by the isolation of chromosomal insertions of each transposon. With C. crescentus strains harboring RP4 aphA::Tn7, the introduction of a wild-type RP4 resulted in the loss of the resident plasmid. Simultaneous selection for Kmr and Smr yielded colonies with chromosomal insertions of Tn7. Examination of over 10,000 chromosomal insertions of Tn7 indicated no auxotrophic or motility mutants. Thus, Tn7 appears to have a high specificity of insertion in C. crescentus. The Mu-containing plasmid pJB4JI transferred Tn5 to C. crescentus, but the plasmid was not maintained. Control experiments showed that recovery of Mu-containing plasmids occurred at very low frequencies in C. crescentus and that the plasmids which were recovered had undergone extensive deletion of plasmid DNA. Presumably, some part of the Mu genome was not tolerated by C. crescentus. The instability of the Mu-containing plasmids makes them excellent vectors for the introduction of transposons, and we have used pJB4JI to isolated chromosomal insertions of Tn5. When several thousand of these insertion mutants were examined, we found auxotrophic and motility mutants at frequencies of 1 and 2%, respectively. These results indicate that Tn5 had a low specificity of insertion in C. crescentus and therefore would be a useful mutagen for obtaining a variety of mutant phenotypes.     

TmRNA is required for correct timing of DNA replication in Caulobacter crescentus

SsrA, or tmRNA, is a small RNA that interacts with selected translating ribosomes to target the nascent polypeptides for degradation. Here we report that SsrA activity is required for normal timing of the G(1)-to-S transition in Caulobacter crescentus. A deletion of the ssrA gene, or of the gene encoding SmpB, a protein required for SsrA activity, results in a specific delay in the cell cycle during the G(1)-to-S transition. The ssrA deletion phenotype is not due to accumulation of stalled ribosomes, because the deletion is not complemented by a mutated version of SsrA that releases ribosomes but does not target proteins for degradation. Degradation of the CtrA response regulator normally coincides with initiation of DNA replication, but in strains lacking SsrA activity there is a 40-min delay between the degradation of CtrA and replication initiation. This uncoupling of initiation of replication from CtrA degradation indicates that there is an SsrA-dependent pathway required for correct timing of DNA replication.     

Galactose catabolism in Caulobacter crescentus.

Caulobacter crescentus wild-type strain CB13 is unable to utilize galactose as the sole carbon source unless derivatives of cyclic AMP are present. Spontaneous mutants have been isolated which are able to grow on galactose in the absence of exogenous cyclic nucleotides. These mutants and the wild-type strain were used to determine the pathway of galactose catabolism in this organism. It is shown here that C. crescentus catabolizes galactose by the Entner-Duodoroff pathway. Galactose is initially converted to galactonate by galactose dehydrogenase and then 2-keto-3-deoxy-6-phosphogalactonate aldolase catalyzes the hydrolysis of 2-keto-3-deoxy-6-phosphogalactonic acid to yield triose phosphate and pyruvate. Two enzymes of galactose catabolism, galactose dehydrogenase and 2-keto-3-deoxy-6-phosphogalactonate aldolase, were shown to be inducible and independently regulated. Furthermore, galactose uptake was observed to be regulated independently of the galactose catabolic enzymes.     

Chromosome segregation in an asymmetrically dividing bacterium,Caulobacter crescentus

The mode of chromosome segregation in an asymmetrically dividing bacterium, Caulobacter crescentus, was studied by examining the fate of labeled DNA strands. Swarmer cells (one type of Caulobacter daughter cell), in which single strands of DNA had been labeled with [³H]thymidine during the previous round of chromosome replication, were grown synchronously in a non-radioactive medium for two generations. The distribution of radioactivity among the cells was visualized by autoradiography under a phase-contrast microscope. The labeled DNA strands in each cell were found to consist of two conserved units. From this, we propose a model in which the swarmer cell has two identical chromosomes, which are segregated into the progeny swarmer cell and the progeny stalked cell after chromosome replication.