Isolation, identification, and transcriptional specificity of the heat shock sigma factor sigma32 from Caulobacter crescentus

Expression of Two RpoH Sigma Factors in Sinorhizobium meliloti upon Heat Shock

The plant symbiotic α-proteobacterium Sinorhizobium meliloti has two RpoH-type sigma factors, RpoH1 and RpoH2. The former induces the synthesis of heat shock proteins and optimizes interactions with the host. Using a Western blot analysis, we examined time course changes in the intracellular contents of these factors upon a temperature upshift. The RpoH1 level was relatively high and constant, suggesting that its regulatory role in the heat shock response is attained through the activation of the pre-existing RpoH1 protein. In contrast, the RpoH2 level was initially undetectable, and gradually increased. These differential patterns reflect the functional diversification of these factors.

Identification of a U/Zn/Cu responsive global regulatory two-component system in Caulobacter crescentus

Despite the well-known toxicity of uranium (U) to bacteria, little is known about how cells sense and respond to U. The recent finding of a U-specific stress response in Caulobacter crescentus has provided a foundation for studying the mechanisms of U- perception in bacteria. To gain insight into this process, we used a forward genetic screen to identify the regulatory components governing expression of the urcA promoter (P_urcA ) that is strongly induced by U. This approach unearthed a previously uncharacterized two-component system, named UzcRS, which is responsible for U-dependent activation of P_urcA . UzcRS is also highly responsive to zinc and copper, revealing a broader specificity than previously thought. Using ChIP-seq, we found that UzcR binds extensively throughout the genome in a metal-dependent manner and recognizes a noncanonical DNA-binding site. Coupling the genome-wide occupancy data with RNA-seq analysis revealed that UzcR is a global regulator of transcription, predominately activating genes encoding proteins that are localized to the cell envelope; these include metallopeptidases, multidrug-resistant efflux (MDR) pumps, TonB-dependent receptors and many proteins of unknown function. Collectively, our data suggest that UzcRS couples the perception of U, Zn and Cu with a novel extracytoplasmic stress response.

Overlapping alternative sigma factor regulons in the response to singlet oxygen in Rhodobacter sphaeroides

Organisms performing photosynthesis in the presence of oxygen have to cope with the formation of highly reactive singlet oxygen ((1)O(2)) and need to mount an adaptive response to photooxidative stress. Here we show that the alternative sigma factors RpoH(I) and RpoH(II) are both involved in the (1)O(2) response and in the heat stress response in Rhodobacter sphaeroides. We propose RpoH(II) to be the major player in the (1)O(2) response, whereas RpoH(I) is more important for the heat stress response. Mapping of the 5' ends of RpoH(II)- and also RpoH(I)/RpoH(II)-dependent transcripts revealed clear differences in the -10 regions of the putative promoter sequences. By using bioinformatic tools, we extended the RpoH(II) regulon, which includes genes induced by (1)O(2) exposure. These genes encode proteins which are, e.g., involved in methionine sulfoxide reduction and in maintaining the quinone pool. Furthermore, we identified small RNAs which depend on RpoH(I) and RpoH(II) and are likely to contribute to the defense against photooxidative stress and heat stress.

Complex regulatory pathways coordinate cell-cycle progression and development in Caulobacter crescentus

Caulobacter crescentus has become the predominant bacterial model system to study the regulation of cell-cycle progression. Stage-specific processes such as chromosome replication and segregation, and cell division are coordinated with the development of four polar structures: the flagellum, pili, stalk, and holdfast. The production, activation, localization, and proteolysis of specific regulatory proteins at precise times during the cell cycle culminate in the ability of the cell to produce two physiologically distinct daughter cells. We examine the recent advances that have enhanced our understanding of the mechanisms of temporal and spatial regulation that occur during cell-cycle progression.

Heat-shock sigma factor RpoH from Geobacter sulfurreducens

Recent studies with Myxococcus xanthus have suggested that homologues of the Escherichia coli heat-shock sigma factor, RpoH, may not be involved in the heat-shock response in this delta-proteobacterium. The genome of another delta-proteobacterium, Geobacter sulfurreducens, which is considered to be a representative of the Fe(III)-reducing Geobacteraceae that predominate in a diversity of subsurface environments, contains an rpoH homologue. Characterization of the G. sulfurreducens rpoH homologue revealed that it was induced by a temperature shift from 30 degrees C to 42 degrees C and that an rpoH-deficient mutant was unable to grow at 42 degrees C. The predicted heat-shock genes, hrcA, grpE, dnaK, groES and htpG, were heat-shock inducible in an rpoH-dependent manner, and comparison of promoter regions of these genes identified the consensus sequences for the -10 and -35 promoter elements. In addition, DNA elements identical to the CIRCE consensus sequence were found in promoters of rpoH, hrcA and groES, suggesting that these genes are regulated by a homologue of the repressor HrcA, which is known to bind the CIRCE element. These results suggest that the G. sulfurreducens RpoH homologue is the heat-shock sigma factor and that heat-shock response in G. sulfurreducens is regulated positively by RpoH as well as negatively by the HrcA/CIRCE system.

GroES/GroEL and DnaK/DnaJ have distinct roles in stress responses and during cell cycle progression in Caulobacter crescentus

Misfolding and aggregation of protein molecules are major threats to all living organisms. Therefore, cells have evolved quality control systems for proteins consisting of molecular chaperones and proteases, which prevent protein aggregation by either refolding or degrading misfolded proteins. DnaK/DnaJ and GroES/GroEL are the best-characterized molecular chaperone systems in bacteria. In Caulobacter crescentus these chaperone machines are the products of essential genes, which are both induced by heat shock and cell cycle regulated. In this work, we characterized the viabilities of conditional dnaKJ and groESL mutants under different types of environmental stress, as well as under normal physiological conditions. We observed that C. crescentus cells with GroES/EL depleted are quite resistant to heat shock, ethanol, and freezing but are sensitive to oxidative, saline, and osmotic stresses. In contrast, cells with DnaK/J depleted are not affected by the presence of high concentrations of hydrogen peroxide, NaCl, and sucrose but have a lower survival rate after heat shock, exposure to ethanol, and freezing and are unable to acquire thermotolerance. Cells lacking these chaperones also have morphological defects under normal growth conditions. The absence of GroE proteins results in long, pinched filamentous cells with several Z-rings, whereas cells lacking DnaK/J are only somewhat more elongated than normal predivisional cells, and most of them do not have Z-rings. These findings indicate that there is cell division arrest, which occurs at different stages depending on the chaperone machine affected. Thus, the two chaperone systems have distinct roles in stress responses and during cell cycle progression in C. crescentus.

A caulobacter crescentus extracytoplasmic function sigma factor mediating the response to oxidative stress in stationary phase

Alternative sigma factors of the extracytoplasmic function (ECF) subfamily are important regulators of stress responses in bacteria and have been implicated in the control of homeostasis of the extracytoplasmic compartment of the cell. This work describes the characterization of sigF, encoding 1 of the 13 members of this subfamily identified in Caulobacter crescentus. A sigF-null strain was obtained and shown to be severely impaired in resistance to oxidative stress, caused by hydrogen peroxide treatment, exclusively during the stationary phase. Although sigF mRNA levels decrease in stationary-phase cells, the amount of sigma(F) protein is greatly increased at this stage, indicating a posttranscriptional control. Data obtained indicate that the FtsH protease is either directly or indirectly involved in the control of sigma(F) levels, as cells lacking this enzyme present larger amounts of the sigma factor. Increased stability of sigma(F) protein in stationary-phase cells of the parental strain and in exponential-phase cells of the ftsH-null strain is also demonstrated. Transcriptome analysis of the sigF-null strain led to the identification of eight genes regulated by sigma(F) during the stationary phase, including sodA and msrA, which are known to be involved in oxidative stress response.

Cells lacking ClpB display a prolonged shutoff phase of the heat shock response in Caulobacter crescentus

The heat shock response in Caulobacter crescentus was previously shown to be positively regulated by the alternative sigma factor of RNA polymerase (RNAP) sigma(32), and negatively modulated by DnaK during the induction phase of the heat shock response but not during the recovery phase. In the present work we have investigated the involvement of the chaperone ClpB in the control of the heat shock response in C. crescentus. Data obtained indicated a role of ClpB in downregulation of heat shock protein (HSP) synthesis, as cells lacking this chaperone showed a prolonged shutoff phase of the heat shock response. In Escherichia coli, it has been proposed that the DnaK chaperone system switches transcription back to constitutively expressed genes through simultaneous reactivation of heat-aggregated sigma(70), as well as sequestration of sigma(32) away from RNAP. In C. crescentus, results obtained with a clpB null mutant indicate that ClpB could be involved in the reactivation of the major sigma factor sigma(73). In support of this hypothesis, we showed that transcription directed from sigma(73)-dependent promoters is not switched back in the clpB null mutant during the recovery phase. Furthermore, we observed that resolubilization of heat-aggregated sigma(73) is dependent on the presence of ClpB. Our findings also indicated that the absence of ClpB made cells more sensitive to heat shock and ethanol but not to other stresses, and unable to acquire thermotolerance.

Functional and structural analysis of HrcA repressor protein from Caulobacter crescentus

A large number of bacteria regulate chaperone gene expression during heat shock by the HrcA-CIRCE system, in which the DNA element called CIRCE serves as binding site for the repressor protein HrcA under nonstress conditions. In Caulobacter crescentus, the groESL operon presents a dual type of control. Heat shock induction is controlled by a sigma32-dependent promoter and the HrcA-CIRCE system plays a role in regulation of groESL expression under physiological temperatures. To study the activity of HrcA in vitro, we purified a histidine-tagged version of the protein, and specific binding to the CIRCE element was obtained by gel shift assays. The amount of retarded DNA increased significantly in the presence of GroES/GroEL, suggesting that the GroE chaperonin machine modulates HrcA activity. Further evidence of this modulation was obtained using lacZ transcription fusions with the groESL regulatory region in C. crescentus cells, producing different amounts of GroES/GroEL. In addition, we identified the putative DNA-binding domain of HrcA through extensive protein sequence comparison and constructed various HrcA mutant proteins containing single amino acid substitutions in or near this region. In vitro and in vivo experiments with these mutated proteins indicated several amino acids important for repressor activity.

Downregulation of the heat shock response is independent of DnaK and sigma32 levels in Caulobacter crescentus

Expression of heat shock genes in Gram-negative proteobacteria is positively modulated by the transcriptional regulator RpoH, the sigma(32) subunit of RNA polymerase (RNAP). In this study we investigated the chaperones DnaK/DnaJ and GroES/GroEL as possible modulators of the heat response in Caulobacter crescentus. We have shown that cells overexpressing DnaK show poor induction of heat shock protein (HSP) synthesis, even though sigma(32) levels present a normal transient increase upon heat stress. On the other hand, depletion of DnaK led to higher levels of sigma(32) and increased transcription of HSP genes, at normal growth temperature. In contrast, changes in the amount of GroES/EL had little effect on sigma(32) levels and HSP gene transcription. Despite the strong effect of DnaK levels on the induction phase of the heat shock response, downregulation of HSP synthesis was not affected by changes in the amount this chaperone. Thus, we propose that competition between sigma(32) and sigma(73), the major sigma factor, for the core RNAP could be the most important factor controlling the shut-off of HSP synthesis during recovery phase. In agreement with this hypothesis, we have shown that expression of sigma(73) gene is heat shock inducible.

New genes involved in chromate resistance in Ralstonia metallidurans strain CH34

Chromate resistance in Ralstonia metallidurans CH34 is based on chromate efflux catalyzed by ChrA efflux pumps. The bacterium harbors two chromate resistance determinants, the previously known chr(1) on plasmid pMOL28 (genes chrI, chrB(1), chrA(1), chrC, chrE, chrF(1)) and chr(2) on the chromosome (genes chrB(2), chrA(2), chrF(2)). Deletion of the genes chrI, chrC, chrA(2), chrB(2) and chrF(2) influenced chromate resistance and transcription from a chrBp(1) ::lacZ fusion. Deletion of the plasmid-encoded gene chrB(1) did not change chromate resistance or chrBp(1) regulation. Northern hybridization and primer-extension experiments were used to study transcription of the plasmid-encoded chr(1) determinant. Transcription of chrB(1), chrA(1) and chrC was induced by chromate. The presence of sulfate influenced transcription positively. The chrBp(1), chrAp(1) and chrCppromoters showed some similarity to heat-shock promoters. Transcription of the gene rpoH encoding a putative heat-shock sigma factor was also induced by chromate, but rpoH was not essential for chromate resistance. The ChrC protein was purified as a homotetramer and exerted superoxide dismutase activity. Thus, possible regulators for chromate resistance (ChrI, ChrB(1), ChrB(2), ChrF(1), and ChrF(2)) and an additional detoxification system (ChrC) were newly identified as parts of chromate resistance in R. metallidurans.

The FtsH protease is involved in development, stress response and heat shock control in Caulobacter crescentus

The ftsH gene of Caulobacter crescentus has been isolated and identified as a component of the general stress response of this organism. In C. crescentus, ftsH expression is transiently induced after temperature upshift and in stationary phase. Consistent with this, mutants deprived of the FtsH protease are viable at normal growth conditions, but are highly sensitive to elevated temperature, increased salt concentration or the presence of antibiotics. Overexpression of ftsH resulted in an increased salt but not thermotolerance, emphasizing the importance of the FtsH protease in stress response. Mutants lacking FtsH were unable to undergo morphological and physiological adaptation in stationary phase and, upon starvation, experienced a more pronounced loss of viability than cells containing FtsH. In addition, cells lacking FtsH had an increased cellular concentration of the heat shock sigma factor sigma32, indicating that, as in Escherichia coli, the FtsH protease is involved in the control of the C. crescentus heat shock response. In agreement with this, transcription of the heat-induced sigma32-dependent gene dnaK was derepressed at normal temperature when FtsH was absent. In contrast, the groEL gene, which is controlled in response to heat stress by both sigma32 and a HcrA/CIRCE mechanism, was not derepressed in an ftsH mutant. Finally, FtsH is involved in C. crescentus development and cell cycle control. ftsH mutants were unable to synthesize stalks efficiently and had a severe cell division phenotype. In the absence of FtsH, swarmer cells differentiated into stalked cells faster than when FtsH was present, even though the entire cell cycle was longer under these conditions. Thus, directly or indirectly, the FtsH protease is involved in the inherent biological clock mechanism, which controls the timing of cell differentiation in C. crescentus.

DnaK chaperone-mediated control of activity of a sigma(32) homolog (RpoH) plays a major role in the heat shock response of Agrobacterium tumefaciens

RpoH (Escherichia coli sigma(32) and its homologs) is the central regulator of the heat shock response in gram-negative proteobacteria. Here we studied salient regulatory features of RpoH in Agrobacterium tumefaciens by examining its synthesis, stability, and activity while increasing the temperature from 25 to 37 degrees C. Heat induction of RpoH synthesis occurred at the level of transcription from an RpoH-dependent promoter, coordinately with that of DnaK, and followed by an increase in the RpoH level. Essentially normal induction of heat shock proteins was observed even with a strain that was unable to increase the RpoH level upon heat shock. Moreover, heat-induced accumulation of dnaK mRNA occurred without protein synthesis, showing that preexisting RpoH was sufficient for induction of the heat shock response. These results suggested that controlling the activity, rather than the amount, of RpoH plays a major role in regulation of the heat shock response. In addition, increasing or decreasing the DnaK-DnaJ chaperones specifically reduced or enhanced the RpoH activity, respectively. On the other hand, the RpoH protein was normally stable and remained stable during the induction phase but was destabilized transiently during the adaptation phase. We propose that the DnaK-mediated control of RpoH activity plays a primary role in the induction of heat shock response in A. tumefaciens, in contrast to what has been found in E. coli.

Complete genome sequence of Caulobacter crescentus

The complete genome sequence of Caulobacter crescentus was determined to be 4,016,942 base pairs in a single circular chromosome encoding 3,767 genes. This organism, which grows in a dilute aquatic environment, coordinates the cell division cycle and multiple cell differentiation events. With the annotated genome sequence, a full description of the genetic network that controls bacterial differentiation, cell growth, and cell cycle progression is within reach. Two-component signal transduction proteins are known to play a significant role in cell cycle progression. Genome analysis revealed that the C. crescentus genome encodes a significantly higher number of these signaling proteins (105) than any bacterial genome sequenced thus far. Another regulatory mechanism involved in cell cycle progression is DNA methylation. The occurrence of the recognition sequence for an essential DNA methylating enzyme that is required for cell cycle regulation is severely limited and shows a bias to intergenic regions. The genome contains multiple clusters of genes encoding proteins essential for survival in a nutrient poor habitat. Included are those involved in chemotaxis, outer membrane channel function, degradation of aromatic ring compounds, and the breakdown of plant-derived carbon sources, in addition to many extracytoplasmic function sigma factors, providing the organism with the ability to respond to a wide range of environmental fluctuations. C. crescentus is, to our knowledge, the first free-living alpha-class proteobacterium to be sequenced and will serve as a foundation for exploring the biology of this group of bacteria, which includes the obligate endosymbiont and human pathogen Rickettsia prowazekii, the plant pathogen Agrobacterium tumefaciens, and the bovine and human pathogen Brucella abortus.

Conserved regulatory elements of the promoter sequence of the gene rpoH of enteric bacteria

The rpoH regulatory region of different members of the enteric bacteria family was sequenced or downloaded from GenBank and compared. In addition, the transcriptional start sites of rpoH of Yersinia frederiksenii and Proteus mirabilis, two distant members of this family, were determined. Sequences similar to the sigma(70) promoters P1, P4 and P5, to the sigma(E) promoter P3 and to boxes DnaA1, DnaA2, cAMP receptor protein (CRP) boxes CRP1, CRP2 and box CytR present in Escherichia coli K12, were identified in sequences of closely related bacteria such as: E.coli, Shigella flexneri, Salmonella enterica serovar Typhimurium, Citrobacter freundii, Enterobacter cloacae and Klebsiella pneumoniae. In more distant bacteria, Y.frederiksenii and P.mirabilis, the rpoH regulatory region has a distal P1-like sigma(70) promoter and two proximal promoters: a heat-induced sigma(E)-like promoter and a sigma(70) promoter. Sequences similar to the regulatory boxes were not identified in these bacteria. This study suggests that the general pattern of transcription of the rpoH gene in enteric bacteria includes a distal sigma(70) promoter, >200 nt upstream of the initiation codon, and two proximal promoters: a heat-induced sigma(E)-like promoter and a sigma(70) promoter. A second proximal sigma(70) promoter under catabolite-regulation is probably present only in bacteria closely related to E.coli.

Identification and transcriptional control of the genes encoding the Caulobacter crescentus ClpXP protease

The region of the Caulobacter crescentus chromosome harboring the genes for the ClpXP protease was isolated and characterized. Comparison of the deduced amino acid sequences of the C. crescentus ClpP and ClpX proteins with those of their homologues from several gram-positive and gram-negative bacteria revealed stronger conservation for the ATPase regulatory subunit (ClpX) than for the peptidase subunit (ClpP). The C. crescentus clpX gene was shown by complementation analysis to be functional in Escherichia coli. However, clpX from E. coli was not able to substitute for the essential nature of the clpX gene in C. crescentus. The clpP and clpX genes are separated on the C. crescentus chromosome by an open reading frame pointing in the opposite direction from the clp genes, and transcription of clpP and clpX was found to be uncoupled. clpP is transcribed as a monocistronic unit with a promoter (PP1) located immediately upstream of the 5' end of the gene and a terminator structure following its 3' end. PP1 is under heat shock control and is induced upon entry of the cells into the stationary phase. At least three promoters for clpX (PX1, PX2, and PX3) were mapped in the clpP-clpX intergenic region. In contrast to PP1, the clpX promoters were found to be downregulated after heat shock but were also subject to growth phase control. In addition, the clpP and clpX promoters showed different activity patterns during the cell cycle. Together, these results demonstrate that the genes coding for the peptidase and the regulatory subunits of the ClpXP protease are under independent transcriptional control in C. crescentus. Determination of the numbers of ClpP and ClpX molecules per cell suggested that ClpX is the limiting component compared with ClpP.

Regulation of heat-shock response in bacteria

Stress response in bacteria is essential for effective adaptation to changes in the environment, as well as to the changes in the physiological state of the bacterial culture itself. This response is mediated by global regulatory mechanisms affecting several pathways. It now appears that these regulatory mechanisms operate by transcriptional control, translational control, and proteolysis. One example to be discussed extensively is the heat-shock response. In Escherichia coli, where it has been studied initially and most extensively, the expression of the heat-shock operon is transcriptionally controlled by the employment of the heat-shock transcription factor sigma 32, that recognizes specific heat-shock promoters. Later studies indicated that in most bacteria the control of the major heat-shock genes is much more complicated, and involves additional--or alternative--control channels. These regulatory elements will be reviewed looking at the groE and dnaK operons. These operons, coding for the bacterial equivalent of Hsp10+60 and Hsp70, respectively, contain in many bacteria a conserved regulatory inverted repeat (IR = CIRCE), and are transcribed either by the vegetative sigma factor--sigma 70--or by a sigma 32-like factor. The IR functions at the DNA level as a repressor binding site and also controls the half life of the transcript. In addition, in Agrobacterium tumefaciens there also exists a system for mRNA processing that involves a temperature-controlled cleavage of the groE transcript.

Promoter selectivity of the Bradyrhizobium japonicum RpoH transcription factors in vivo and in vitro

Expression of the dnaKJ and groESL1 heat shock operons of Bradyrhizobium japonicum depends on a sigma32-like transcription factor. Three such factors (RpoH1, RpoH2, and RpoH3) have previously been identified in this organism. We report here that they direct transcription from some but not all sigma32-type promoters when the respective rpoH genes are expressed in Escherichia coli. All three RpoH factors were purified as soluble C-terminally histidine-tagged proteins, although the bulk of overproduced RpoH3 was insoluble. The purified proteins were recognized by an anti-E. coli sigma32 serum. While RpoH1 and RpoH2 productively interacted with E. coli core RNA polymerase and produced E. coli groE transcript in vitro, RpoH3 was unable to do so. B. japonicum core RNA polymerase was prepared and reconstituted with the RpoH proteins. Again, RpoH1 and RpoH2 were active, and they initiated transcription at the B. japonicum groESL1 and dnaKJ promoters. In all cases, the in vitro start site was shown to be identical to the start site determined in vivo. Promoter competition experiments revealed that the B. japonicum dnaKJ and groESL1 promoters were suboptimal for transcription by RpoH1- or RpoH2-containing RNA polymerase from B. japonicum. In a mixture of different templates, the E. coli groESL promoter was preferred over any other promoter. Differences were observed in the specificities of both sigma factors toward B. japonicum rpoH-dependent promoters. We conclude that the primary function of RpoH2 is to supply the cell with DnaKJ under normal growth conditions whereas RpoH1 is responsible mainly for increasing the level of GroESL1 after a heat shock.

Regulatory conservation and divergence of sigma32 homologs from gram-negative bacteria: Serratia marcescens, Proteus mirabilis, Pseudomonas aeruginosa, and Agrobacterium tumefaciens

The heat shock response in Escherichia coli is mediated primarily by the rpoH gene, encoding sigma32, which is specifically required for transcription of heat shock genes. A number of sigma32 homologs have recently been cloned from gram-negative bacteria that belong to the gamma or alpha subdivisions of the proteobacteria. We report here some of the regulatory features of several such homologs (RpoH) expressed in E. coli as well as in respective cognate bacteria. When expressed in an E. coli delta rpoH strain lacking its own sigma32, these homologs activated the transcription of heat shock genes (groE and dnaK) from the start sites normally used in E. coli. The level of RpoH in Serratia marcescens and Pseudomonas aeruginosa cells was very low at 30 degrees C but was elevated markedly upon a shift to 42 degrees C, as found previously with E. coli. The increased RpoH levels upon heat shock resulted from both increased synthesis and stabilization of the normally unstable RpoH protein. In contrast, the RpoH level in Proteus mirabilis was relatively high at 30 degrees C and increased less markedly upon heat shock, mostly by increased synthesis; this sigma32 homolog was already stable at 30 degrees C, and little further stabilization occurred upon the shift to 42 degrees C. The increased synthesis of RpoH homologs in all these gamma proteobacteria was observed even in the presence of rifampin, suggesting that the induction occurred at the level of translation. Thus, the basic regulatory strategy of the heat shock response by enhancing the RpoH level is well conserved in the gamma proteobacteria, but some divergence in the actual mechanisms used occurred during evolution.

The CIRCE element and its putative repressor control cell cycle expression of the Caulobacter crescentus groESL operon

The groESL operon is under complex regulation in Caulobacter crescentus. In addition to strong induction after exposure to heat shock, under physiological growth conditions, its expression is subject to cell cycle control. Transcription and translation of the groE genes occur primarily in predivisional cells, with very low levels of expression in stalked cells. The regulatory region of groESL contains both a sigma32-like promoter and a CIRCE element. Overexpression of C. crescentus sigma32 gives rise to higher levels of GroEL and increased levels of the groESL transcript coming from the sigma32-like promoter. Site-directed mutagenesis in CIRCE has indicated a negative role for this cis-acting element in the expression of groESL only at normal growth temperatures, with a minor effect on heat shock induction. Furthermore, groESL-lacZ transcription fusions carrying mutations in CIRCE are no longer cell cycle regulated. Analysis of an hrcA null strain, carrying a disruption in the gene encoding the putative repressor that binds to the CIRCE element, shows constitutive synthesis of GroEL throughout the Caulobacter cell cycle. These results indicate a negative role for the hrcA gene product and the CIRCE element in the temporal control of the groESL operon.

Isolation and characterization of the Xanthomonas campestris rpoH gene coding for a 32-kDa heat shock sigma factor

Degenerate oligonucleotide primers corresponding to the conserved regions of bacterial heat shock sigma factor RpoH (sigma 32) were used to amplify a 190-bp fragment by PCR on the X. campestris pv. campestris strain 11 chromosome. Using this fragment as a probe, plasmid pXC57 carrying a 4.7-kb insert was isolated from a genomic library of Xc11. Sequence analysis of a stretch of 2,053 bp from the pXC57 insert revealed an ORF encoding a polypeptide of 291 aa (32,854 dal) which displays 59.6% and 57.3% identity to the rpoH gene products of E. coli and P. aeruginosa, respectively. The Xc11 rpoH gene was able to complement the RpoH deficient E. coli strain A7448. Both amino acid and mRNA sequences deduced from the Xc11 rpoH gene show structural features characteristics of the corresponding sequences from those of the gamma subgroup proteobacteria. The RpoH levels in Xc11 were demonstrated to increase transiently in response to heat shock treatment by immunoblot analysis using the polyclonal antibody raised against the purified Xc11 RpoH.

An essential, multicomponent signal transduction pathway required for cell cycle regulation in Caulobacter

Cell differentiation and division in Caulobacter crescentus are regulated by a signal transduction pathway mediated by the histidine kinase DivJ and the essential response regulator DivK. Here we report genetic and biochemical evidence that the DivJ and DivK proteins function to control the activity of CtrA, a response regulator required for multiple cell cycle events, including flagellum biosynthesis, DNA replication, and cell division. Temperature-sensitive sokA (suppressor of divK) alleles were isolated as extragenic suppressors of a cold-sensitive divK mutation and mapped to the C terminus of the CtrA protein. The sokA alleles also suppress the lethal phenotype of a divK gene disruption and the cold-sensitive cell division phenotype of divJ mutants. The relationship between these signal transduction components and their target was further defined by demonstrating that the purified DivJ kinase phosphorylates CtrA, as well as DivK. Our studies also showed that phospho-CtrA activates transcription in vitro from the class II flagellar genes and that their promoters are recognized by the principal C. crescentus sigma factor sigma73. We propose that an essential signal transduction pathway mediated by DivJ, DivK, and CtrA coordinates cell cycle and developmental events in C. crescentus by regulating the level of CtrA phosphorylation and transcription from sigma73-dependent class II gene promoters. Our results suggest that an unidentified phosphotransfer protein or kinase (X) is responsible for phosphoryl group transfer to CtrA in the proposed DivJ --> DivK --> X --> CtrA phosphorelay pathway.

Metabolic roles of a Rhodobacter sphaeroides member of the sigma32 family

We report the role of a gene (rpoH) from the facultative phototroph Rhodobacter sphaeroides that encodes a protein (sigma37) similar to Escherichia coli sigma32 and other members of the heat shock family of eubacterial sigma factors. R. sphaeroides sigma37 controls genes that function during environmental stress, since an R. sphaeroides deltaRpoH mutant is approximately 30-fold more sensitive to the toxic oxyanion tellurite than wild-type cells. However, the deltaRpoH mutant lacks several phenotypes characteristic of E. coli cells lacking sigma32. For example, an R. sphaeroides deltaRpoH mutant is not generally defective in phage morphogenesis, since it plates the lytic virus RS1, as well as its wild-type parent. In characterizing the response of R. sphaeroides to heat, we found that its growth temperature profile is different when cells generate energy by aerobic respiration, anaerobic respiration, or photosynthesis. However, growth of the deltaRpoH mutant is comparable to that of a wild-type strain under each of these conditions. The deltaRpoH mutant mounted a heat shock response when aerobically grown cells were shifted from 30 to 42 degrees C, but it exhibited altered induction kinetics of approximately 120-, 85-, 75-, and 65-kDa proteins. There was also reduced accumulation of several presumed heat shock transcripts (rpoD P(HS), groESL1, etc.) when aerobically grown deltaRpoH cells were placed at 42 degrees C. Under aerobic conditions, it appears that another sigma factor enables the deltaRpoH mutant to mount a heat shock response, since either RNA polymerase preparations from an deltaRpoH mutant, reconstituted Esigma37, or a holoenzyme containing a 38-kDa protein (sigma38) each transcribed E. coli Esigma32-dependent promoters. The lower growth temperature profile of photosynthetic cells is correlated with a difference in heat-inducible gene expression, since neither wild-type cells or the deltaRpoH mutant mount a typical heat shock response after such cultures were shifted from 30 to 37 degrees C.

Purification, characterization, and reconstitution of DNA-dependent RNA polymerases from Caulobacter crescentus

Cell differentiation in the Caulobacter crescentus cell cycle requires differential gene expression that is regulated primarily at the transcriptional level. Until now, however, a defined in vitro transcription system for the biochemical study of developmentally regulated transcription factors had not been available in this bacterium. We report here the purification of C. crescentus RNA polymerase holoenzymes and resolution of the core RNA polymerase from holoenzymes by chromatography on single-stranded DNA cellulose. The three RNA polymerase holoenzymes Esigma54, Esigma32, and Esigma73 were reconstituted exclusively from purified C. crescentus core and sigma factors. Reconstituted Esigma54 initiated transcription from the sigma54-dependent fljK promoter of C. crescentus in the presence of the transcription activator FlbD, and active Esigma32 specifically initiated transcription from the sigma32-dependent promoter of the C. crescentus heat-shock gene dnaK. For reconstitution of the Esigma73 holoenzyme, we overexpressed the C. crescentus rpoD gene in Escherichia coli and purified the full-length sigma73 protein. The reconstituted Esigma73 recognized the sigma70-dependent promoters of the E. coli lacUV5 and neo genes, as well as the sigma73-dependent housekeeping promoters of the C. crescentus pleC and rsaA genes. The ability of the C. crescentus Esigma73 RNA polymerase to recognize E. coli sigma70-dependent promoters is consistent with relaxed promoter specificity of this holoenzyme previously observed in vivo.

The GroE chaperonin machine is a major modulator of the CIRCE heat shock regulon of Bacillus subtilis

Class I heat-inducible genes in Bacillus subtilis consist of the heptacistronic dnaK and the bicistronic groE operon and form the CIRCE regulon. Both operons are negatively regulated at the level of transcription by the HrcA repressor interacting with its operator, the CIRCE element. Here, we demonstrate that the DnaK chaperone machine is not involved in the regulation of HrcA and that the GroE chaperonin exerts a negative effect in the post-transcriptional control of HrcA. When expression of the groE operon was turned off, the dnaK operon was significantly activated and large amounts of apparently inactive HrcA repressor were produced. Overproduction of GroEL, on the other hand, resulted in decreased expression of the dnaK operon. Introduction of the hrcA gene and its operator into Escherichia coli was sufficient to elicit a transient heat shock response, indicating that no additional Bacillus-specific gene(s) was needed. As in B. subtilis, the groEL gene of E. coli negatively influenced the activity of HrcA. HrcA could be overproduced in E. coli, but formed inclusion bodies which could be dissolved in 8 M urea. Upon removal of urea, HrcA had a strong tendency to aggregate, but aggregation could be suppressed significantly by the addition of GroEL. Purified HrcA repressor was able specifically to retard a DNA fragment containing the CIRCE element, and the amount of retarded DNA was increased significantly in the presence of GroEL. These results suggest that the GroE chaperonin machine modulates the activity of the HrcA repressor and therefore point to a novel function of GroE as a modulator of the heat shock response.

Cloning, nucleotide sequence, and regulatory analysis of the Nitrosomonas europaea dnaK gene

The dnaK gene of an ammonia-oxidizing bacterium, Nitrosomonas europaea, was cloned and sequenced. It was found that the dnaK gene product was highly homologous to previously analyzed dnaK gene products from other organisms at the amino acid level. Two partial open reading frames located upstream and downstream of the dnaK gene were also found and identified as grpE and dnaJ genes, respectively, by the predicted amino acid homology of their gene products to other bacterial GrpE and DnaJ proteins. Transcription of the dnaK gene was strongly induced by a heat shock from 30 to 37 degrees C. An analysis of the expression of the dnaK gene fused to the lacZ translational reporter gene also showed eightfold increase in beta-galactosidase activity after the heat shock induction. Heat-inducible transcription start sites of the dnaK gene, revealed by primer extension analysis, were located 16 and 17 nucleotides upstream from the translational start codon of the dnaK gene, and the predicted promoter sequence showed a homology to the consensus sequence of sigma 32-dependent heat shock promoters of gram-negative bacteria. The upstream region of the dnaK gene did not contain the inverted repeat structure that was involved in the regulation of the heat shock gene of several gram-negative and gram-positive bacteria. Therefore, we conclude that the heat shock regulatory mechanism of the N. europaea dnaK gene may be similar to the sigma 32-dependent mechanism observed in other gram-negative bacteria.

The Caulobacter heat shock sigma factor gene rpoH is positively autoregulated from a sigma32-dependent promoter

Sigma factor sigma32, encoded by rpoH, is required for the recognition of heat shock genes during normal growth conditions and in response to heat shock and other stresses. Unlike the well-studied Escherichia coli rpoH gene, which is transcribed from four promoters recognized by either a sigma70 (sigmaD)- or sigma24 (sigmaE)-containing RNA polymerase, the Caulobacter crescentus rpoH gene is transcribed from two promoters, P1 and P2. In this study, we have examined the structure and expression of these promoters and shown that the rpoH P2 promoter is sigma32 dependent. We present evidence here that P2 is specifically recognized and transcribed by the reconstituted C. crescentus Esigma32 RNA polymerase holoenzyme. We show that site-directed mutations within either the -10 or the -35 regions of P2 have substantial effects on the levels of transcription by the Esigma32 polymerase predicted from the sigma32 promoter consensus sequence. The mutations have similar effects in vivo as assayed with rpoH-lacZ transcription fusions. Analysis of the rpoH P1 promoter provided evidence that it is sigma70 dependent. S1 nuclease protection assays of rpoH P1- and P2-specific expression after heat shock at 42 or 50 degrees C and during synchronous cell division cycles under normal growth conditions showed that the two promoters are differentially regulated. Mutations within the rpoH P2 promoter consensus sequences abolished the response to heat shock induction in C. crescentus. We conclude from these results that, unlike rpoH genes studied previously in other bacteria, the major transcriptional response of the C. crescentus rpoH gene to heat shock depends on positive autoregulation of the sigma32-dependent promoter.

The Bradyrhizobium japonicum rpoH1 gene encoding a sigma 32-like protein is part of a unique heat shock gene cluster together with groESL1 and three small heat shock genes

The heat shock response of Bradyrhizobium japonicum is controlled by a complex network involving two known regulatory systems. While some heat shock genes are controlled by a highly conserved inverted-repeat structure (CIRCE), others depend on a sigma 32-type heat shock sigma factor. Using Western blot (immunoblot) analysis, we confirmed the presence of a sigma 32-like protein in B. japonicum and defined its induction pattern after heat shock. A B. japonicum rpoH-like gene (rpoH1) was cloned by complementation of an Escherichia coli strain lacking sigma 32. A knockout mutation in rpoH1 did not abolish sigma 32 production in B. japonicum, and the rpoH1 mutant showed the wild-type growth phenotype, suggesting the presence of multiple rpoH homologs in this bacterium. Further characterization of the rpoH1 gene region revealed that the rpoH1 gene is located in a heat shock gene cluster together with the previously characterized groESL1 operon and three genes encoding small heat shock proteins in the following arrangement: groES1, groEL1, hspA, rpoH1, hspB, and hspC. Three heat-inducible promoters are responsible for transcription of the six genes as three bicistronic operons. A sigma 32-dependent promoter has previously been described upstream of the groESL1 operon. Although the hspA-rpoH1 and hspBC operons were clearly heat inducible, they were preceded by sigma 70-like promoters. Interestingly, a stretch of about 100 bp between the transcription start site and the start codon of the first gene in each of these two operons was nearly identical, making it a candidate for a regulatory element potentially allowing heat shock induction of sigma 70-dependent promoters.