Heat shock activation of the groESL operon of Agrobacterium tumefaciens and the regulatory roles of the inverted repeat

Segal, G. M.; Ron, Eliora Z.

doi:10.1128/jb.178.12.3634-3640.1996

Cited by 42 publications

(47 citation statements)

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“…The dnaKJ operon, clpB, and several other heat shock genes are under control of RpoH (19,24,38). The groESL operon was found to be under dual control of RpoH and the HrcA repressor (24,39). Analysis of the heat shock proteome by two-dimensional protein gel electrophoresis confirmed these results but also raised additional questions, since 32 of 56 heat shock proteins were induced independently of RpoH and HrcA (34).…”

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confidence: 57%

Replicon-Specific Regulation of Small Heat Shock Genes in Agrobacterium tumefaciens

et al. 2004

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Four genes coding for small heat shock proteins (sHsps) were identified in the genome sequence of Agrobacterium tumefaciens, one on the circular chromosome (hspC), one on the linear chromosome (hspL), and two on the pAT plasmid (hspAT1 and hspAT2). Induction of sHsps at elevated temperatures was revealed by immunoblot analyses. Primer extension experiments and translational lacZ fusions demonstrated that expression of the pAT-derived genes and hspL is controlled by temperature in a regulon-specific manner. While the sHsp gene on the linear chromosome turned out to be regulated by RpoH ( 32 ), both copies on pAT were under the control of highly conserved ROSE (named for repression of heat shock gene expression) sequences in their 5 untranslated region. Secondary structure predictions of the corresponding mRNA strongly suggest that it represses translation at low temperatures by masking the Shine-Dalgarno sequence. The hspC gene was barely expressed (if at all) and not temperature responsive.The virulence of pathogenic microorganisms is strongly affected by temperature (11,16,41). Whereas a temperature of 37°C induces expression of virulence genes in mammalian pathogens, much lower temperatures are typically favorable for the infection process of plant pathogens. Many virulence genes in Agrobacterium tumefaciens, Pseudomonas syringae, and different Erwinia species are induced at temperatures between 18 and 28°C and repressed at higher temperatures (41). Various reasons account for the reduced infectivity of A. tumefaciens at temperatures above 28°C. (i) The signal transduction pathway mediated by the VirAG two-component regulatory system is functional only below this temperature (15). (ii) Assembly of T-pilus components required for DNA transfer to plant cells is compromised (3,4,8,9,17). (iii) Degradation of a subset of virulence proteins might occur at elevated temperatures (4).A puzzling observation was recently made during studies on the temperature stability of the A. tumefaciens type IV secretion system, which translocates DNA and protein into plant cells. Concomitant with the accumulation of plant secondary metabolite-induced virulence proteins at low temperatures, small heat shock proteins (sHsps) were induced (see Discussion of reference 4). Synthesis of sHsps was also observed during symbiosis of Sinorhizobium meliloti with the legume

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confidence: 57%

Replicon-Specific Regulation of Small Heat Shock Genes in Agrobacterium tumefaciens

et al. 2004

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“…If CIRCE is part of the mRNA and localized close to the ribosome binding site of the following gene, it decreases the stability of mRNA by impairing ribosome binding and consequently deprotecting the 5Ј end of mRNA against 5Ј-binding RNases (20,32,46). This destabilizing mechanism is not realized in the case of the H. pylori dnaK operon.…”

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confidence: 94%

Transcriptional Analysis of Major Heat Shock Genes of Helicobacter pylori

Homuth¹,

Domm

Kleiner

et al. 2000

J Bacteriol

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The transcriptional organization and heat inducibility of the major heat shock genes hrcA, dnaK, dnaJ, groEL, and htpG were analyzed on the transcriptional level in Helicobacter pylori strain 69A. The strongly heat-induced dnaK operon was found to be tricistronic, consisting of the genes hrcA, grpE, and dnaK. The dnaJ gene specified one monocistronic mRNA which was also heat inducible. The genes groES and groEL were transcribed as one strongly heat-inducible bicistronic mRNA which exhibited exactly the same induction kinetic as the dnaK operon. Surprisingly, transcription of the monocistronic htpG gene was switched off after heat shock. The data presented are discussed with regard to the different mechanisms regulating expression of heat shock genes in H. pyloriHelicobacter pylori is a gram-negative, spiral-shaped pathogenic bacterium that specifically colonizes the gastric epithelium of primates and is the causative agent of chronic, active type B gastritis in humans (3). The following genetic determinants contribute to the successful colonization of the gastric mucosa: a urease neutralizing the bacterial microenvironment by producing ammonia from the urea present in mucosal sections (9, 10, 14); motility in the gastric mucus and adhesion to the mucosal cell membrane, enabling H. pylori to avoid the extremely low pH of the gastric lumen (11,24,35); and the low-pH-induced synthesis of H. pylori gene products inhibiting acid secretion by mucosal cells (26). As has been demonstrated for all other bacterial species examined so far, H. pylori elicits a heat shock response. Thermoregulation plays an important role in virulence gene expression in pathogenic bacteria including Escherichia coli, Salmonella spp., Shigella spp., and Yersinia spp. Given the importance of the heat shock response in the pathogenesis of other enteric pathogens, this stress response may also play an important role in pathogenesis of H. pylorimediated gastritis.The major heat shock proteins GroES/GroEL and DnaK have been identified in H. pylori. The amount of GroEL increases after heat shock and acid shock (22,45). It has been proposed that GroEL may participate in protection and activity regulation of urease (12,36). An increase in the amount of DnaK after acid shock has also been observed (22). Furthermore, DnaK was reported to be involved in the modulation of glycolipid binding specificity of H. pylori at low pH (21).The aim of this study was to analyze expression of the major H. pylori heat shock genes at the transcriptional level under unstressed conditions and after heat shock. The availability of the published complete H. pylori genome sequence (38) made it possible to generate highly sensitive RNA probes allowing the detection of mRNA specified by the classical heat shock genes hrcA, dnaK, dnaJ, groEL, and htpG.Recently, Spohn and Scarlato demonstrated the negative regulation of the promoters preceding the dnaK and groE operons by the HspR/HAIR (HspR-associated inverted repeat) repressor/operator system in H. pylori G27 (34). Surprising...

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“…A second class of heat shock proteins is regulated by B (7)(8)(9), and the others are HrcA and B independent (7,9). In Agrobacterium tumefaciens and other ␣-proteobacteria, two heat shock control elements were identified, the RpoH homologue and the CIRCE-HrcA regulatory system (16,24,29,30,32). In contrast to the gram-positive bacteria the CIRCE-HrcA system is found only in the groESL operon and heat shock transcription of the major chaperone genes is controlled by RpoH (16,18,(27)(28)(29)(30)(31)(32).…”

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Heat Shock Proteome of Agrobacterium tumefaciens : Evidence for New Control Systems

et al. 2002

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The regulation of Agrobacterium tumefaciens heat shock genes involves a transcriptional activator (RpoH) and repressor elements (HrcA-CIRCE). Using proteome analysis and mutants in these control elements, we show that the heat shock induction of 32 (out of 56) heat shock proteins is independent of RpoH and HrcA. These results indicate the existence of additional regulatory factors in the A. tumefaciens heat shock response.The heat shock response is characterized by the induction of several proteins, some of which are highly conserved. In Escherichia coli the heat shock regulon is controlled by alternative sigma factors, mainly 32 (encoded by rpoH), which regulates transcription of all major cytoplasmic heat shock proteins (6, 35) and has been identified in more than 20 species of gramnegative eubacteria (1,11,12,16,17,19,20,26). The heat shock proteins of the gram-positive Bacillus subtilis are divided into at least three regulatory classes (7). The chaperones encoded by the orf39-grpE-dnaK-dnaJ operon and by the groESL operon are transcribed by the vegetative sigma factor even during heat shock (4) and regulated by the HrcA repressor, which binds to CIRCE (controlling inverted repeat of chaperone expression) (9, 13-15, 37). A second class of heat shock proteins is regulated by B (7-9), and the others are HrcA and B independent (7, 9). In Agrobacterium tumefaciens and other ␣-proteobacteria, two heat shock control elements were identified, the RpoH homologue and the CIRCE-HrcA regulatory system (16,24,29,30,32). In contrast to the gram-positive bacteria the CIRCE-HrcA system is found only in the groESL operon and heat shock transcription of the major chaperone genes is controlled by RpoH (16,18,[27][28][29][30][31][32]. To further study the complex heat shock response in A. tumefaciens, we used two-dimensional (2-D) gel electrophoresis. We found 56 heat shock proteins, 5 of which are newly identified heat shock proteins. The heat shock proteins can be divided into at least three regulatory groups. The first group is RpoH dependent (24 proteins); among these, GroEL and GroES may be considered as a separate group since they are also repressed by HrcA in non-heat shock conditions. The expression of genes of the third group (32 proteins) is regulated independently of the known control elements ( 32 and HrcA) and indicates the existence of additional regulatory factors or controls.Effects of RpoH on the heat shock response. Proteome analysis of A. tumefaciens indicated the heat shock induction of 56 proteins (25). It should be noted that several groups of proteins were not studied in our experiments, i.e., membrane proteins and proteins with very high or very low pI values. We examined the involvement of RpoH in a wild-type strain and an ⌬rpoH mutant (16) ( Table 1). Using 2-D gel analysis (3, 25), we found that, in all strains, the majority of the non-heat shock proteins were strongly down-regulated during heat shock ( Fig. 1 and 2), as represented by the periplasmic binding protein (Fig. 3a). Out of the 56 protein...

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Heat shock activation of the groESL operon of Agrobacterium tumefaciens and the regulatory roles of the inverted repeat

Cited by 42 publications

References 50 publications

Replicon-Specific Regulation of Small Heat Shock Genes in Agrobacterium tumefaciens

Replicon-Specific Regulation of Small Heat Shock Genes in Agrobacterium tumefaciens

Transcriptional Analysis of Major Heat Shock Genes of Helicobacter pylori

Heat Shock Proteome of Agrobacterium tumefaciens : Evidence for New Control Systems

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