Structural and mechanistic insights into Helicobacter pylori NikR activation.

NikR is a transcriptional metalloregulator central in the mandatory response to acidity of Helicobacter pylori that controls the expression of numerous genes by binding to specific promoter regions. NikR/DNA interactions were proposed to rely on protein activation by Ni(II) binding to high-affinity (HA) and possibly secondary external (X) sites. We describe a biochemical characterization of HpNikR mutants that shows that the HA sites are essential but not sufficient for DNA binding, while the secondary external (X) sites and residues from the HpNikR dimer-dimer interface are important for DNA binding. We show that a second metal is necessary for HpNikR/DNA binding, but only to some promoters. Small-angle X-ray scattering shows that HpNikR adopts a defined conformation in solution, resembling the cis-conformation and suggests that nickel does not trigger large conformational changes in HpNikR. The crystal structures of selected mutants identify the effects of each mutation on HpNikR structure. This study unravels key structural features from which we derive a model for HpNikR activation where: (i) HA sites and an hydrogen bond network are required for DNA binding and (ii) metallation of a unique secondary external site (X) modulates HpNikR DNA binding to low-affinity promoters by disruption of a salt bridge.

The Helicobacter pylori UreI protein: role in adaptation to acidity and identification of residues essential for its activity and for acid activation.

Helicobacter pylori is a human gastric pathogen that survives the strong acidity of the stomach by virtue of its urease activity. This activity produces ammonia, which neutralizes the bacterial microenvironment. UreI, an inner membrane protein, is essential for resistance to low pH and for the gastric colonization of mice by H. pylori. In the heterologous Xenopus oocytes expression system, UreI behaves like an H+-gated urea channel, and His-123 was found to be important for low pH activation. We investigated the role of UreI directly in H. pylori and showed that, in the presence of urea, strains expressing wild-type UreI displayed very rapid stimulation of extracellular ammonia production upon exposure to pH

[UreI: a Helicobacter pylori protein essential for resistance to acidity and for the early steps of murine gastric mucosa infection]. / UreI: une protéine de Helicobacter pylori essentielle à la résistance à l'acidité et aux étapes précoces de l'infection de la muqueuse gastrique murine.

UNLABELLED: Helicobacter pylori (H. pylori) is a Gram negative microaerophilic bacteria whose only known niche is the human gastric mucosa. The presence of H. pylori is associated with various pathologies ranging from peptic ulcer disease to gastric carcinoma. H. pylori virulence is dependent on its exceptional ability to resist to the stomach acidity by hydrolyzing urea into ammonia. Survival of H. pylori to acidity in the presence of urea relies on the activity of a membrane protein, UreI. AIMS: We decided to better characterize the role of UreI (i) in vitro in ammonia production through the action of urease, and (ii) in vivo in the colonization of the gastric mucosa. METHODS: Ammonia production by a wild type strain of H. pylori or by a UreI-deficient strain was measured as a function of extracellular pH. In addition, the kinetics of elimination of a UreI-deficient mutant in vivo were realized in the mouse model for colonization. RESULTS: UreI was associated with an increase of ammonia production in acidic conditions in vitro and was necessary for the initial steps of the mouse stomach colonization. CONCLUSION: UreI thus behaves as a sensor of extracellular pH. This protein activates urease at acidic pH; thereby, it probably allows H. pylori to resist to acidity in vivo during the first steps of infection.

Identification of the Helicobacter pylori anti-sigma28 factor.

Flagellar motility is essential for colonization of the human gastric mucosa by Helicobacter pylori. The flagellar filament is composed of two subunits, FlaA and FlaB. Transcription of the genes encoding these proteins is controlled by the sigma28 and sigma54 factors of RNA polymerase respectively. The expression of flagellar genes is regulated, but no sigma28-specific effector was identified. It was also unclear whether H. pylori possessed a checkpoint for flagellar synthesis, and no gene encoding an anti-sigma28 factor, FlgM, could be identified by sequence similarity searches. To investigate the sigma28-dependent regulation, a new approach based on genomic data was used. Two-hybrid screening with the H. pylori proteins identified a protein of unknown function (HP1122) interacting with the sigma28 factor and defined the C-terminal part of HP1122 (residues 48-76) as the interaction domain. HP1122 interacts with region 4 of sigma28 and prevents its association with the beta-region of H. pylori RNA polymerase. Thus, HP1122 presented the characteristics of an anti-sigma28 factor. This was confirmed in H. pylori by RNA dot-blot hybridization and electron microscopy. The level of sigma28-dependent flaA transcription was higher in a HP1122-deficient strain and was decreased by the overproduction of HP1122. The overproduction of HP1122 also resulted in H. pylori cells with highly truncated flagella. These results demonstrate that HP1122 is the H. pylori anti-sigma28 factor, FlgM, a major regulator of flagellum assembly. Potential anti-sigma28 factors were identified in Campylobacter jejuni, Pseudomonas aeruginosa and Thermotoga maritima by sequence homology with the C-terminal region of HP1122.

The AmiE aliphatic amidase and AmiF formamidase of Helicobacter pylori: natural evolution of two enzyme paralogues.

Aliphatic amidases (EC 3.5.1.4) are enzymes catalysing the hydrolysis of short-chain amides to produce ammonia and the corresponding organic acid. Such an amidase, AmiE, has been detected previously in Helicobacter pylori. Analysis of the complete H. pylori genome sequence revealed the existence of a duplicated amidase gene that we named amiF. The corresponding AmiF protein is 34% identical to its AmiE paralogue. Because gene duplication is widely considered to be a fundamental process in the acquisition of novel enzymatic functions, we decided to study and compare the functions of the paralogous amidases of H. pylori. AmiE and AmiF proteins were overproduced in Escherichia coli and purified by a two-step chromatographic procedure. The two H. pylori amidases could be distinguished by different biochemical characteristics such as optimum pH or temperature. AmiE hydrolysed propionamide, acetamide and acrylamide and had no activity with formamide. AmiF presented an unexpected substrate specificity: it only hydrolysed formamide. AmiF is thus the first formamidase (EC 3.5.1.49) related to aliphatic amidases to be described. Cys-165 in AmiE and Cys-166 in AmiF were identified as residues essential for catalysis of the corresponding enzymes. H. pylori strains carrying single and double mutations of amiE and amiF were constructed. The substrate specificities of these enzymes were confirmed in H. pylori. Production of AmiE and AmiF proteins is dependent on the activity of other enzymes involved in the nitrogen metabolism of H. pylori (urease and arginase respectively). Our results strongly suggest that (i) the H. pylori paralogous amidases have evolved to achieve enzymatic specialization after ancestral gene duplication; and (ii) the production of these enzymes is regulated to maintain intracellular nitrogen balance in H. pylori.

The protein-protein interaction map of Helicobacter pylori.

With the availability of complete DNA sequences for many prokaryotic and eukaryotic genomes, and soon for the human genome itself, it is important to develop reliable proteome-wide approaches for a better understanding of protein function. As elementary constituents of cellular protein complexes and pathways, protein-protein interactions are key determinants of protein function. Here we have built a large-scale protein-protein interaction map of the human gastric pathogen Helicobacter pylori. We have used a high-throughput strategy of the yeast two-hybrid assay to screen 261 H. pylori proteins against a highly complex library of genome-encoded polypeptides. Over 1,200 interactions were identified between H. pylori proteins, connecting 46.6% of the proteome. The determination of a reliability score for every single protein-protein interaction and the identification of the actual interacting domains permitted the assignment of unannotated proteins to biological pathways.

[Bacteriology and pathogenicity of Helicobacter pylori]. / Bactériologie et pathogénicité d'Helicobacter pylori.

Helicobacter pylori is the prototype of bacteria belonging to a new genus, the Helicobacter genus. It is a gram-negative, highly motile and microaerophilic bacterium, with a spiral shape, that colonizes the human gastric mucosa and causes several gastroduodenal diseases. Pathogenicity of H. pylori relies upon its capacity to adapt to a hostile environment and to escape the host response. Resistance to acidity, motility, adhesion, molecular mimicry, resistance to phagocytosis, synthesis of a cytotoxin, induction of an inflammatory response are the major strategies developed by H. pylori to colonize persistently and damage gastric tissue.

The Helicobacter pylori UreI protein is not involved in urease activity but is essential for bacterial survival in vivo.

We produced defined isogenic Helicobacter pylori ureI mutants to investigate the function of UreI, the product of one of the genes of the urease cluster. The insertion of a cat cassette had a strong polar effect on the expression of the downstream urease genes, resulting in very weak urease activity. Urease activity, measured in vitro, was normal in a strain in which ureI was almost completely deleted and replaced with a nonpolar cassette. In contrast to previous reports, we thus found that the product of ureI was not necessary for the synthesis of active urease. Experiments with the mouse-adapted H. pylori SS1 strain carrying the nonpolar ureI deletion showed that UreI is essential for H. pylori survival in vivo and/or colonization of the mouse stomach. The replacement of ureI with the nonpolar cassette strongly reduced H. pylori survival in acidic conditions (1-h incubation in phosphate-buffered saline solution at pH 2.2) in the presence of 10 mM urea. UreI is predicted to be an integral membrane protein and may therefore be involved in a transport process essential for H. pylori survival in vivo.

Identification and characterization of an aliphatic amidase in Helicobacter pylori.

We report, for the first time, the presence in Helicobacter pylori of an aliphatic amidase that, like urease, contributes to ammonia production. Aliphatic amidases are cytoplasmic acylamide amidohydrolases (EC 3.5.1.4) hydrolysing short-chain aliphatic amides to produce ammonia and the corresponding organic acid. The finding of an aliphatic amidase in H. pylori was unexpected as this enzyme has only previously been described in bacteria of environmental (soil or water) origin. The H. pylori amidase gene amiE (1017 bp) was sequenced, and the deduced amino acid sequence of AmiE (37746Da) is very similar (75% identity) to the other two sequenced aliphatic amidases, one from Pseudomonas aeruginosa and one from Rhodococcus sp. R312. Amidase activity was measured as the release of ammonia by sonicated crude extracts from H. pylori strains and from recombinant Escherichia coli strains overproducing the H. pylori amidase. The substrate specificity was analysed with crude extracts from H. pylori cells grown in vitro; the best substrates were propionamide, acrylamide and acetamide. Polymerase chain reaction (PCR) amplification of an internal amiE sequence was obtained with each of 45 different H. pylori clinical isolates, suggesting that amidase is common to all H. pylori strains. A H. pylori mutant (N6-836) carrying an interrupted amiE gene was constructed by allelic exchange. No amidase activity could be detected in N6-836. In a N6-urease negative mutant, amidase activity was two- to threefold higher than in the parental strain N6. Crude extracts of strain N6 slowly hydrolysed formamide. This activity was affected in neither the amidase negative strain (N6-836) nor a double mutant strain deficient in both amidase and urease activities, suggesting the presence of an independent discrete formamidase in H. pylori. The existence of an aliphatic amidase, a correlation between the urease and amidase activities and the possible presence of a formamidase indicates that H. pylori has a large range of possibilities for intracellular ammonia production.

The Helicobacter pylori ureC gene codes for a phosphoglucosamine mutase.

The function of UreC, the product of a 1,335-bp-long open reading frame upstream from the urease structural genes (ureAB) of Helicobacter pylori, was investigated. We present data showing that the ureC gene product is a phosphoglucosamine mutase. D. Mengin-Lecreulx and J. van Heijenoort (J. Biol. Chem. 271:32-39, 1996) observed that UreC is similar (43% identity) to the GlmM protein of Escherichia coli. Those authors showed that GlmM is a phosphoglucosamine mutase catalyzing interconversion of glucosamine-6-phosphate into glucosamine-1-phosphate, which is subsequently transformed into UDP-N-acetylglucosamine. The latter product is one of the main cytoplasmic precursors of cell wall peptidoglycan and outer membrane lipopolysaccharides. The present paper reports that, like its E. coli homolog glmM, the H. pylori ureC gene is essential for cell growth. It was known that growth of a lethal conditional glmM mutant of E. coli at a nonpermissive temperature can be restored in the presence of the ureC gene. We showed that complete complementation of the glmM mutant can be obtained with a plasmid overproducing UreC. The peptidoglycan content and the specific phosphoglucosamine mutase activity of such a complemented strain were measured; these results demonstrated that the ureC gene product functions as a phosphoglucosamine mutase. Homologs of the UreC and GlmM proteins were identified in Haemophilus influenzae, Mycobacterium leprae, Clostridium perfringens, Synechocystis sp. strain PCC6803, and Methanococcus jannaschii. Significant conservation of the amino acid sequence of these proteins in such diverse organisms suggests a very ancient common ancestor for the genes and defines a consensus motif for the phosphoglucosamine mutase active site. We propose renaming the H. pylori ureC gene the glmM gene.

RegF, an SspA homologue, regulates the expression of the Neisseria gonorrhoeae pilE gene.

The Neisseria gonorrhoeae pilE gene codes for a type IV pilin, the major subunit of pili which constitute an essential virulence factor during gonococcal infection. Expression of pilE seems to be highly regulated, which may allow piliation to adapt to growth conditions. From an N. gonorrhoeae genomic library, we selected plasmid pNG200 encoding a protein (RegF) which caused a 5-fold increase in the expression of pilE::cat fusion in Escherichia coli. This regulation was mediated via the complex pilE promoter region, comprising potential sigma 70- and sigma 54-dependent promoters, and could not be observed in the absence of an active sigma 54 factor. The RegF protein (23,149 Da) showed 42% identity with the E. coli "stringent starvation protein", SspA. This protein was shown to interact with the RNA polymerase holoenzyme and to play a role in the expression of at least 11 proteins in E. coli. In an N. gonorrhoeae strain carrying a regF::mTn3Cm3 mutation constructed by allelic exchange, it was observed that pilin expression was enhanced. Our results were consistent with a model in which (i) in N. gonorrhoeae, RegF acts as a negative regulator of pilE transcription, and (ii) in E. coli, RegF increases pilE transcription by preventing sigma 54-associated steric hindrance at pilE promoters described previously.

Determinants of Helicobacter pylori pathogenicity.

Helicobacter pylori is a recently recognized bacterial pathogen associated with diverse pathologies of varying severity, such as chronic gastritis, peptic ulceration, mucosa-associated lymphoid tissue (MALT) lymphoma, and gastric carcinoma. We here present a review of our current knowledge on the properties of H. Pylori that adapt it to its particular niche by allowing it to survive in the stomach and to colonize the gastric mucosa, as well as those that underlie its persistence and pathogenicity. While the bacterial determinants that preclude the persistent colonization of the gastric mucosa are better understood, those associated with pathogenicity appear to result from the possibility for some of the bacteria of the species to synthesize products that directly or indirectly damage the gastric mucosa, cause a persistent inflammatory reaction, and/or perturb the regulation of acid secretion.

Positive regulation of the expression of the Escherichia coli pts operon. Identification of the regulatory regions.

The pts operon of Escherichia coli is composed of the ptsH, ptsI and crr genes coding for three proteins central to the phosphoenolpyruvate dependent phosphotransferase system (PTS), the HPr, enzyme I and EIIIGlc proteins, respectively. We previously showed that transcription from the promoter region located upstream from the pts operon is regulated by two control circuits, which can occur independently from each other. Transcription of the pts operon is (1) stimulated by the CAP-cAMP complex and (2) enhanced during growth on glucose, a PTS substrate. The DNA regions involved in regulation of the expression of the pts operon have been identified. Two promoters, P0 and P1, separated by 100 bp are located upstream from the pts operon. In these promoter regions, we identified two sequences showing similarity with the consensus of CAP-binding sites, CAPa located near P0 and CAPb located in the -35 region of P1. In vivo experiments showed that binding of CAP-cAMP at the CAPa site stimulates transcription from the P0 promoter. The binding sites of CAP-cAMP and/or RNA-polymerase on a DNA fragment containing both P0 and P1 promoters as well as both CAPa and CAPb sites were examined by the technique of DNase I footprinting. These in vitro experiments suggested that CAP-cAMP binding at the CAPb site might also play a role in regulation of the pts operon expression. In addition, we showed that the DNA region carrying the CAPa site is important for regulation by glucose. We finally propose that the expression of the pts operon is controlled by two alternative positive regulatory mechanisms, which are designed to allow activation of the pts operon under a great variety of growth conditions.

Mutational analysis of the enzyme IIIGlc of the phosphoenolpyruvate phosphotransferase system in Escherichia coli.

The phosphoenolpyruvate phosphotransferase system (PTS) component EIIIGlc is responsible for transport and phosphorylation of glucose via EIIGlc. It also regulates the catabolism of other carbon sources, such as lactose and maltose, by modulating both the intracellular concentrations of the corresponding inducers and of cAMP. Mutational analysis of EIIIGlc was performed in order to identify crucial residues mediating the interactions between EIIIGlc and its target proteins. Such mutations were isolated by in vitro hydroxylamine mutagenesis of the cloned EIIIGlc gene, crr. Five mutated EIIIGlc impaired in the function of inducer exclusion were obtained. However, these mutations did not abolish the function of EIIIGlc in the transport and phosphorylation of glucose, nor in activation of adenylate cyclase. A single amino acid change was found for each mutation, which is located in a restricted area of the polypeptide chain: Gly47-->Ser47 for the HA2 and HA5 mutations, Ala76-->Thr76 for HA4 mutation and Ser78-->Phe78 for HA3 mutation, indicative of quaternary interactions between the corresponding region of EIIIGlc and its target protein(s).

Positive regulation of the pts operon of Escherichia coli: genetic evidence for a signal transduction mechanism.

The pts operon of Escherichia coli is composed of the genes ptsH, ptsI, and crr, which code for three proteins of the phosphoenolpyruvate-dependent phosphotransferase system (PTS): the HPr, enzyme I (EI), and EIIIGlc proteins, respectively. These three genes are organized in a complex operon in which the major part of expression of the distal gene, crr, is initiated from a promoter region within ptsI. Expression from the promoter region of the ptsH and ptsI genes has been studied in vivo by using gene fusions with lacZ. Transcription from this promoter region is under the positive control of catabolite activator protein (CAP)-cyclic AMP (cAMP) and is also enhanced during growth in the presence of glucose (a PTS substrate). This report describes a genetic characterization of the mechanism by which growth on glucose causes transcriptional stimulation of the pts operon. This regulation is dependent on transport through the glucose-specific permease of the PTS, EIIGlc. Our results strongly suggest that transcriptional regulation of the pts operon is the consequence of an increase in the level of unphosphorylated EIIGlc which is produced during glucose transport. Furthermore, overproduction of EIIGlc in the absence of transport was found to stimulate expression of the pts operon. We also observed that CAP-cAMP could cause stimulation independently of the EIIGlc and that glucose could activate in the absence of cAMP in a strain overproducing EIIGlc. Our results indicate that glucose acts like an environmental signal through a mechanism of signal transduction. A sequence similarity between the C terminus of EIIGlc and the consensus of transmitter modules of the sensor proteins defined by E. C. Kofoid and J. S. Parkinson (Proc. Natl. Acad. Sci. USA 85:4981-4985, 1988) suggests that EIIGlc might have properties in common with the sensors of the two-component systems.

Antisense expression at the ptsH-ptsI locus of Escherichia coli.

A Mud(Ap, lac) prophage has been shown to be inserted into the ptsH gene of E. coli. The insertion is likely to have generated an operon fusion revealing antisense transcription at this locus. This suggests that the ORF previously identified, overlapping with ptsH ORF in the opposite orientation, might be functional. A model of regulation for the ptsH-ptsI-crr operon transcription is presented which accounts for antisense transcription.

The ptsH, ptsI, and crr genes of the Escherichia coli phosphoenolpyruvate-dependent phosphotransferase system: a complex operon with several modes of transcription.

The ptsH, ptsI, and crr genes, coding for three of the proteins of the phosphoenolpyruvate-dependent phosphotransferase system (PTS) (HPr, enzyme I, and enzyme IIIGlc, respectively) have been studied by determination of their nucleotide sequence and analysis of their expression. The three genes constitute an operon, but analysis of the ptsH, ptsI, and crr transcripts by Northern (RNA) blotting revealed the existence of three major mRNA species. One encompassed the three cistrons, a second one the ptsH gene and part of the ptsI gene, and the third one only the distal gene crr. The short crr transcripts were initiated inside the ptsI open reading frame at points which were identified by S1 mapping. Expression of the genes was studied in vivo by using operon and protein fusions between the lacZ gene and the ptsH, ptsI, or crr gene on IncW low-copy-number plasmids. The present study showed that (i) the ptsH, ptsI, and crr genes exhibited high basal expression, (ii) transcription of the ptsH and ptsI genes was stimulated threefold by the cyclic AMP-cyclic AMP receptor protein complex and also by growth on glucose, but only in the presence of an active enzyme IIGlc, (iii) crr-specific expression was not sensitive to the complex or to growth on glucose, and (iv) under the growth conditions tested, the major part of crr transcription was initiated from internal promoters.

Analysis of the ptsH-ptsI-crr region in Escherichia coli K-12: nucleotide sequence of the ptsH gene.

The nucleotide sequence of an Escherichia coli DNA segment containing the ptsH gene and the first 162 nucleotides of the ptsI gene encoding, respectively, Hpr and enzyme I of the phosphoenolpyruvate-dependent glycose phosphotransferase system (PTS), was determined. The ptsH promoter was localized using the S1 mapping technique. A nucleotide sequence very similar to the consensus binding site for cAMP receptor protein was found in the -35 region of the ptsH promoter. The ptsH gene is transcribed in the same direction as the ptsI gene and the crr gene (encoding enzyme IIIGlc of the PTS). Analysis of the nucleotide sequence substantiates the notion that the ptsH-ptsI-crr genes constitute a polycistronic operon.

Analysis of the ptsH-ptsI-crr region in Escherichia coli K-12: evidence for the existence of a single transcriptional unit.

A cosmid containing the ptsH, ptsI and crr genes of Escherichia coli coding for three components of the phosphoenolpyruvate: sugar phosphotransferase system (PTS) has been isolated. The products of these genes were identified using the maxicell technique. The cloning of the PTS region as a whole allowed us to map and order ptsH, ptsI and crr genes in a 3.8-kb DNA fragment and determine that ptsI and crr are transcribed from a common promoter. They, therefore, constitute a single transcriptional unit which is likely to include also the ptsH gene. In addition, the crr gene may have a secondary promoter located inside ptsI.