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Flagellar motility and chemotaxis are essential virulence traits required for the ability of Helicobacter pylori to colonize the gastric mucosa. The flagellar regulatory network and the complex chemotaxis system of H. pylori are fundamentally different from other bacteria, despite many similarities. In H. pylori expression of the flagella is controlled by a complex regulatory cascade involving the two-component system FlgR-HP244, the sigma factors 54 and 28 and the anti-sigma 28 factor FlgM. Thus far, the input signal for histidine kinase HP244, which activates the transcriptional regulator FlgR, which triggers sigma factor 54-dependent transcription of the flagellar class 2 genes, is not known. Based on a yeast two-hybrid screen a highly significant protein-protein interaction between the H. pylori protein HP137 and both the histidine kinase HP244 and the flagellar hook protein HP908 (FlgE´) has been reported recently (Rain et al., 2001). So far, no function could be assigned to HP137. Interestingly, the interaction between HP137 and histidine kinase HP244 was observed in the characteristic block N sequence motif of the C-terminal ATP-binding kinase domain. In this work a potential role of HP137 in a feedback regulatory mechanism controlling the activity of histidine kinase HP244 in the flagellar regulation of H. pylori was investigated. Although the substitution of the gene encoding HP137 by a kanamycin cassette resulted in non-motile bacteria, the failure to restore motility by the reintroduction of hp137 in cis into the mutant strain, and the observation that HP137 has no significant effect on the activity of histidine kinase HP244 in vitro indicated that HP137 is not directly involved in flagellar regulation. Therefore, it was demonstrated that HP137 does not participate in the regulation of flagellar gene expression, neither in H. pylori nor in the closely related bacterium C. jejuni. Chemotactic signal transduction in H. pylori differs from the enterobacterial paradigm in several respects. In addition to a CheY response regulator protein (CheY1) H. pylori contains a CheY-like receiver domain (CheY2) which is C-terminally fused to the histidine kinase CheA. Furthermore, the genome of H. pylori encodes three CheV proteins consisting of an N-terminal CheW-like domain and a C-terminal receiver domain, while there are no orthologues of the chemotaxis genes cheB, cheR, and cheZ. To obtain insight into the mechanism controlling the chemotactic response of H. pylori the phosphotransfer reactions between the purified two-component signalling modules were investigated in vitro. Using in vitro phosphorylation assays it was shown that both H. pylori histidine kinases CheAY2 and CheA´ lacking the CheY-like domain (CheY2) act as ATP-dependent autokinases. Similar to other CheA proteins CheA´ shows a kinetic of phosphorylation represented by an exponential time course, while the kinetics of phosphorylation of CheAY2 is characterized by a short exponential time course followed by the hydrolysis of CheAY2~P. Therefore, it was demonstrated that the presence of the CheY2-like receiver domain influences the stability of the phosphorylated P1 domain of the CheA part of the bifunctional protein. Furthermore, it was proven that both CheY1 and CheY2 are phosphorylated by CheAY2 and CheA´~P and that the three CheV proteins mediate the dephosphorylation of CheA´~P, although with a clearly reduced efficiency as compared to CheY1 and CheY2. Moreover, CheA´ is capable of donating its phospho group to the CheY1 protein from C. jejuni and to CheY protein from E. coli. Retrophosphorylation experiments indicated that CheY1~P is able to transfer the phosphate group back to the HK CheAY2 and the receiver domain present in the bifunctional CheAY2 protein acts as a phosphate sink fine tuning the activity of the freely diffusible CheY1 protein, which is thought to interact with the flagellar motor. Hence, in this work evidence of a complex phosphorelay in the chemotaxis system was obtained which has similarities to other systems with multiple CheY proteins. The role of the CheV proteins remain unclear at the moment, but they might be engaged in a further fine regulation of the phosphate flow in this complex chemotaxis system and the independent function of the two domains CheA´ and CheY2 is not sufficient for normal chemotactic signalling in vivo.
The Gram-negative, spiral-shaped, microaerophilic bacterium Helicobacter pylori is the causative agent of various disorders of the upper gastrointestinal tract, such as chronic superficial gastritis, chronic active gastritis, peptic ulceration and adenocarcinoma. Although many of the bacterial factors associated with disease development have been analysed in some detail in the recent years, very few studies have focused so far on the mechanisms that regulate expression of these factors at the molecular level. In an attempt to obtain an overview of the basic mechanisms of virulence gene expression in H. pylori, three important virulence factors of this pathogen, representative of different pathogenic mechanisms and different phases of the infectious process, are investigated in detail in the present thesis regarding their transcriptional regulation. As an essential factor for the early phase of infection, including the colonisation of the gastric mucosa, the flagella are analysed; the chaperones including the putative adhesion factors GroEL and DnaK are investigated as representatives of the phase of adherence to the gastric epithelium and persistence in the mucus layer; and finally the cytotoxin associated antigen CagA is analysed as representative of the cag pathogenicity island, which is supposed to account for the phenomena of chronic inflammation and tissue damage observed in the later phases of infection. RNA analyses and in vitro transcription demonstrate that a single promoter regulates expression of cagA, while two promoters are responsible for expression of the upstream divergently transcribed cagB gene. All three promoters are shown to be recognised by RNA polymerase containing the vegetative sigma factor sigma 80. Promoter deletion analyses establish that full activation of the cagA promoter requires sequences up to -70 and binding of the C-terminal portion of the alpha subunit of RNA polymerase to an UP-like element located between -40 and -60, while full activation of the major cagB promoter requires sequences upstream of -96 which overlap with the cagA promoter. These data suggest that the promoters of the pathogenicity island represent a class of minimum promoters, that ensure a basic level of transcription, while full activation requires regulatory elements or structural DNA binding proteins that provide a suitable DNA context. Regarding flagellar biosynthesis, a master transcriptional factor is identified that regulates expression of a series of flagellar basal body and hook genes in concert with the alternative sigma factor sigma 54. Evidence is provided that this regulator, designated FlgR (for flagellar regulatory protein), is necessary for motility and transcription of five promoters for seven basal body and hook genes. In addition, FlgR is shown to act as a repressor of transcription of the sigma 28-regulated promoter of the flaA gene, while changes in DNA topology are shown to affect transcription of the sigma 54-regulated flaB promoter. These data indicate that the regulatory network that governs flagellar gene expression in H. pylori shows similarities to the systems of both Salmonella spp. and Caulobacter crescentus. In contrast to the flagellar genes which are regulated by three different sigma factors, the three operons encoding the major chaperones of H. pylori are shown to be transcribed by RNA polymerase containing the vegetative sigma factor sigma 80. Expression of these operons is shown to be regulated negatively by the transcriptional repressor HspR, a homologue of a repressor protein of Streptomyces spp., known to be involved in negative regulation of heat shock genes. In vitro studies with purified recombinant HspR establish that the protein represses transcription by binding to large DNA regions centered around the transcription initiation site in the case of one promoter, and around -85 and -120 in the case of the the other two promoters. In contrast to the situation in Streptomyces, where transcription of HspR-regulated genes is induced in response to heat shock, transcription of the HspR-dependent genes in H. pylori is not inducible with thermal stimuli. Transcription of two of the three chaperone encoding operons is induced by osmotic shock, while transcription of the third operon, although HspR-dependent, is not affected by salt treatment. Taken together, the analyses carried out indicate that H. pylori has reduced its repertoire of specific regulatory proteins to a basic level that may ensure coordinate regulation of those factors that are necessary during the initial phase of infection including the passage through the gastric lumen and the colonisation of the gastric mucosa. The importance of DNA topology and/or context for transcription of many virulence gene promoters may on the other hand indicate, that a sophisticated global regulatory network is present in H. pylori, which influences transcription of specific subsets of virulence genes in response to changes in the microenvironment.