Genome of Helicobacter pylori strain 908

Helicobacter pylori is a genetically diverse and coevolved pathogen inhabiting human gastric niches and leading to a spectrum of gastric diseases in susceptible populations. We describe the genome sequence of H. pylori 908, which was originally isolated from an African patient living in France who suffered with recrudescent duodenal ulcer disease. The strain was found to be phylogenetically related to H. pylori J99, and its comparative analysis revealed several specific genome features and novel insertion-deletion and substitution events. The genome sequence revealed several strain-specific deletions and/or gain of genes exclusively present in HP908 compared with different sequenced genomes already available in the public domain. Comparative and functional genomics of HP908 and its subclones will be important in understanding genomic plasticity and the capacity to colonize and persist in a changing host environment.     

Genomic methylation: a tool for typing Helicobacter pylori isolates

The genome sequences of three Helicobacter pylori strains revealed an abundant number of putative restriction and modification (R-M) systems within a small genome (1.60 to 1.67 Mb). Each R-M system includes an endonuclease that cleaves a specific DNA sequence and a DNA methyltransferase that methylates either adenosine or cytosine within the same DNA sequence. These are believed to be a defense mechanism, protecting bacteria from foreign DNA. They have been classified as selfish genetic elements; in some instances it has been shown that they are not easily lost from their host cell. Possibly because of this phenomenon, the H. pylori genome is very rich in R-M systems, with considerable variation in potential recognition sequences. For this reason the protective aspect of the methyltransferase gene has been proposed as a tool for typing H. pylori isolates. We studied the expression of H. pylori methyltransferases by digesting the genomic DNAs of 50 strains with 31 restriction endonucleases. We conclude that methyltransferase diversity is sufficiently high to enable the use of the genomic methylation status as a typing tool. The stability of methyltransferase expression was assessed by comparing the methylation status of genomic DNAs from strains that were isolated either from the same patient at different times or from different stomach locations (antrum and corpus). We found a group of five methyltransferases common to all tested strains. These five may be characteristic of the genetic pool analyzed, and their biological role may be important in the host/bacterium interaction.     

Construction of a Helicobacter pylori genome map and demonstration of diversity at the genome level.

Genomic DNA from 30 strains of Helicobacter pylori was subjected to pulsed-field gel electrophoresis (PFGE) after digestion with NotI and NruI. The genome sizes of the strains ranged from 1.6 to 1.73 Mb, with an average size of 1.67 Mb. By using NotI and NruI, a circular map of H. pylori UA802 (1.7 Mb) which contained three copies of 16S and 23S rRNA genes was constructed. An unusual feature of the H. pylori genome was the separate location of at least two copies of 16S and 23S rRNA genes. Almost all strains had different PFGE patterns after NotI and NruI digestion, suggesting that the H. pylori genome possesses a considerable degree of genetic variability. However, three strains from different sites (the fundus, antrum, and body of the stomach) within the same patient gave identical PFGE patterns. The genomic pattern of individual isolates remained constant during multiple subcultures in vitro. The reason for the genetic diversity observed among H. pylori strains remains to be explained.     

Genomics of Helicobacter pylori

During this review period, we have definitely entered into the genomic era. The Helicobacter pylori studies reported here illustrate the use of most of the technologies currently available to globally interrogate the genome of a pathogen. Global analysis of the gene content of H. pylori strains gives insight into the extent of its genetic diversity and its in vivo evolution. Our understanding of the particularities of H. pylori as a gastric pathogen colonizing a unique niche has been improved by studies aimed at: (i) the identification of H. pylori-specific genes; (ii) the establishment of correlations between the presence of one or a group of genes (or proteins) with clinical outcome; and (iii) the analysis of global regulatory circuits or responses to the extracellular signals. The response of host cells to H. pylori infection will be developed in the chapter 'H. pylori and gastric malignancies' by Sepulveda and Coehlo. Despite our knowledge of the H. pylori genome, the function of about one third of its total proteins is still unknown. Functional genomics are straightforward approaches for the identification of new gene functions or metabolic pathways as well as for the understanding of cellular processes and the detection of new virulence factors. In silico studies combined with experimental work will undoubtedly continue to develop. To date, the expansion of proteomics with refinements in mass spectrometry technology has illustrated that through immunoproteomics and comparative studies, relevant novel antigens can be identified. Genomics not only provides invaluable information on H. pylori but also opens new perspectives for diagnostic or therapeutic applications.     

Different Helicobacter pylori strains colonize the antral and duodenal mucosa of duodenal ulcer patients

Background. We have investigated the possibility that the same patients may be colonized by Helicobacter pylori strains of different genotypes or phenotypes in the antrum as compared to in the duodenum. The strains were typed for DNA fingerprints, different lipopolysaccharides (LPS), and Lewis antigen expression on the O –side chains of LPS.
Materials and Methods. Polymerase chain reaction (PCR) amplifications using primer sequences (i.e., the Enterobacterial Repetitive Intergenic Consensus [ERIC]) and randomly amplified polymorphic DNA (RAPD) elements were performed to asses chromosomal DNA diversity between H. pylori strains. The expression of different LPS types and Lewis antigens in the various H. pylori isolates were determined by whole bacterial enzyme-linked immunosorbent assays using monoclonal antibodies.
Results. Duodenal ulcer patients had different H. pylori genotypes in the duodenum as compared to in the antrum as shown by ERIC-PCR (44%) and by RAPD-PCR (75%). Different DNA patterns were found among the strains that were isolated from various regions of the duodenum in 4 of 16 patients (25%) as shown by ERIC-PCR and in 8 of 16 patients (50%) as shown by RAPD-PCR. Sixty-three percent of the duodenal ulcer patients had H. pylori strains with a different Lewis antigen phenotype in the duodenum as compared to in the antrum, and 3 of 16 patients (19%) had strains with different Lewis antigens expressed by strains from different duodenal biopsies from the same patient.
Conclusion. The results suggest that a mixed population of different H. pylori strains with marked variation, both genotypically and phenotypically, colonize the same patient.     

幽门螺杆菌感染的分子机制

幽门螺杆菌(Helicobacterpylori)是居留于人胃上皮组织并引起胃炎、消化性胃溃疡和胃癌的病原菌。近年来,随着幽门螺杆菌全基因组序列的报道和功能基因的研究深入,对幽门螺杆菌的感染的分子、免疫等机制逐渐阐明。现对幽门螺杆菌基因组特点和幽门螺杆菌黏附、毒性因子等对人体感染的分子机制等方面的研究进展做一综述。     

Evaluation of the homologous recombination in Helicobacter pylori

BACKGROUND: Most strategies for direct mutagenesis of Helicobacter pylori primarily involve genomic DNA cloning which is a time-consuming and expensive technique. METHODS: To make a gene replacement, we propose a strategy using polymerase chain reaction (PCR) amplicons to allow a double homologous recombination in the genome of H. pylori. Different strains were used to validate this strategy and we describe how the amplicon insertion was made with accuracy. Moreover, we looked for the shortest homologous sequence needed to allow a specific gene replacement in H. pylori without any deletion, insertion or mutation at the recombination site. All of the experiments were performed at the flaA locus, whose gene encodes the major flagellin. RESULTS: Amplicons bearing 500 or 150 bp flanking regions of flaA on each side (depending on the strain) were sufficient to allow the specific insertion of a 1173 bp chloramphenicol cassette into the genome of H. pylori. The insertion was accurate with no substitutions at the insertion locus. CONCLUSIONS: This information opens the door to other strategies for mutagenesis used for the identification of virulence factors without deleting genes, which would not be based on a negative screening system. For example, they could be useful in performing protein fusion for a better understanding of the virulence factor's mechanism.     

Detection of Helicobacter pylori in saliva and esophagus

The route of Helicobacter pylori transmission remains unclear and the currently suggested route is person-to-person transfer by faecal-oral and oral-oral mode. The aim of this study was to verify the presence of H. pylori in esophagus and saliva of humans. Saliva samples, mucosal biopsies from esophagus, gastric antrum and fundus were collected from 19 patients with positive Urea Breath Test (UBT). Gastric biopsies were used for H. pylori colture and antimicrobial susceptibility tests whereas saliva samples were collected to detect H. pylori with a Nested-PCR targeting 16S rRNA gene as well as esophagus biopsies which were also investigated with immunohistochemical staining. Helicobacter pylori was isolated in 18 patients both in gastric antrum and fundus. The molecular analysis, confirmed by comparative sequences evaluation, gave positive results in all saliva and esophageal samples whereas the immunohistochemistry revealed the presence of H. pylori in 15.8% (3/19) of the esophagus samples. Our data suggest that saliva and esophagus may be considered reservoirs for H. pylori in humans and emphasize the need to use more susceptible techniques for H. pylori detection, in particular in over-crowded sites. Identification of the transmission route of H. pylori is crucial in developing an effective plan of surveillance by finding new means of disease management.     

Spontaneous mutations in the Helicobacter pylori rpsL gene

Several studies have revealed that the Helicobacter pylori genome differs markedly from strain to strain, perhaps as a result of mutations arising during persistent infection and/or related to the observed variation in virulence. The development of a detection system for mutations in H. pylori genes might therefore help us to develop a better understanding of its mutability, and in this way help us to develop plans for investigating the relationship between its genomic variability and the pathogenesis of various gastric and duodenal diseases associated with the long-term H. pylori infections. We have therefore begun a study of H. pylori mutability using the endogenous rpsL gene as a marker. Spontaneous mutant frequencies were measured and compared among H. pylori strains, after incubation on plates containing 50 microg/ml of streptomycin for 10 days as a selection procedure. The rpsL gene of each streptomycin-resistant (Str(r)) mutant was amplified by polymerase-chain-reaction (PCR) and sequenced. All of the mutations we characterized were localized at codons 43 or 88 of the rpsL gene and were base transitions from A to G, replacing lysine with arginine. This is in contrast to the spontaneous Str(r) mutants isolated from Escherichia coli, which resulted from either A to G transitions at lysine codons 42 and 87, or A to T or C transversions at lysine codon 42. The spontaneous mutant frequencies of the rpsL gene in H. pylori were of the order of 10(-9), and there were significant differences in spontaneous mutant frequencies among the strains tested. This mutation detection system might be of value in screening clinical isolates for H. pylori mutator phenotypes.     

Isogenic variation of Helicobacter pylori strain resulting in heteroresistant antibacterial phenotypes in a single host in vivo

BACKGROUND: Antibiotic-susceptible and -resistant Helicobacter pylori can be present simultaneously in the same host. The aim of this study was to evaluate the genomic diversity of H. pylori strains resulting in heteroresistant antibacterial phenotypes. MATERIALS AND METHODS: Twenty-one pairs of H. pylori strains isolated from the antrum and body displaying heteroresistant antibacterial phenotypes were included. We compared the genotypes of paired-isolates by random arbitrarily primed polymerase chain reaction (PCR), flagella gene PCR-based restriction fragment length polymorphism, and flaA gene sequencing. In metronidazole-heteroresistant isolates, the sequence variation of rdxA and frxA genes was analyzed using phylogenetic analysis. RESULTS: The DNA fingerprinting patterns of the paired isolates revealed that 12 pairs (57.1%) were identical, whereas one pair (3.8%) was different. The remaining eight pairs (38.1%) of isolates showed minor heterogenecity in fingerprinting patterns. In flaA gene sequencing, these identical and similar isolates showed close sequence similarity between the antrum and body, whereas different isolate showed 31 points of different nucleotide sequences. Phylogenetic analysis of the metronidazole-heteroresistant pairs showed consistent genetic relatedness of each paired isolates despite the sequence variation of the rdxA or frxA genes in five pairs (71.4%). CONCLUSIONS: These results suggest that continuing genomic diversities in the same strain may play an important role in modulating the antibiotic-heteroresistant H. pylori in vivo.     

A genetic locus of Helicobacter pylori inversely associated with gastric intestinal metaplasia

The genomic contents of Helicobacter pylori strain C1 from a patient with gastric cancer and strain 98587 from a patient with duodenal ulcer disease were compared using a rapid subtractive hybridisation approach. A total of 11 tester-specific sequences representing gene specificity, DNA rearrangement and sequence variation were identified. This included two novel sequences, clone P32 and clone F5, which have no significant homologue in the database. H. pylori strains positive for clone P32 were less prevalent in patients with gastric intestinal metaplasia (12.5%) than in duodenal ulcer (39.1%) (p=0.036), or chronic gastritis (38.1%) (p=0.036). The results suggest that H. pylori clone P32 is potentially a useful marker for distinguishing intestinal metaplasia associated strains from others.     

Mucosal production of antigastric autoantibodies in Helicobacter pylori gastritis

Background. Apart form bacterial virulence factors of Helicobacter pylori , certain host factors influence the pathogenesis of H. pylori gastritis. In particular, antigastric autoantibodies that are detectable in the sera of a substantial proportion of H. pylori were shown to correlate with the development of gastric atrophy. The aim of this study was to analyze the possible antigastric autoimmune response in H. pylori gastritis at the site where the action is, i.e., in the gastric mucosa.
Material and Methods. Gastric biopsy specimens from antrum and corpus mucosa of 24 H. pylori –infected and of 33 noninfected patients were cultured for 3 days, and tissue culture supernatants were analyzed for the amount of locally produced IgA and IgG. Antigastric autoantibodies were screened in the sera and in the supernatants by means of immunohistochemistry.
Results. The infected patients had significantly higher concentrations of locally produced IgA, whereas the IgG concentrations were virtually the same in infected and noninfected patients. IgG or IgA antigastric autoantibodies, or both, were detectable only in the sera (38%) and supernatants (17%) of infected patients. Interestingly, the patient with the strongest local autoimmune response showed body-predominant H. pylori gastritis, with destruction of gastric glands and atrophy of the body mucosa.
Conclusions. These results demonstrate that antigastric autoimmune reactions are detectable at the site of the disease and might be relevant for the pathogenesis of gastric mucosa atrophy in H. pylori gastritis.     

Difluoromethylornithine is a novel inhibitor of Helicobacter pylori growth, CagA translocation, and interleukin-8 induction

Helicobacter pylori infects half the world's population, and carriage is lifelong without antibiotic therapy. Current regimens prescribed to prevent infection-associated diseases such as gastroduodenal ulcers and gastric cancer can be thwarted by antibiotic resistance. We reported that administration of 1% D,L-α-difluoromethylornithine (DFMO) to mice infected with H. pylori reduces gastritis and colonization, which we attributed to enhanced host immune response due to inhibition of macrophage ornithine decarboxylase (ODC), the rate-limiting enzyme in polyamine biosynthesis. Although no ODC has been identified in any H. pylori genome, we sought to determine if DFMO has direct effects on the bacterium. We found that DFMO significantly reduced the growth rate of H. pylori in a polyamine-independent manner. Two other gram-negative pathogens possessing ODC, Escherichia coli and Citrobacter rodentium, were resistant to the DFMO effect. The effect of DFMO on H. pylori required continuous exposure to the drug and was reversible when removed, with recovery of growth rate in vitro and the ability to colonize mice. H. pylori exposed to DFMO were significantly shorter in length than those untreated and they contained greater internal levels of ATP, suggesting severe effects on bacterial metabolism. DFMO inhibited expression of the H. pylori virulence factor cytotoxin associated gene A, and its translocation and phosphorylation in gastric epithelial cells, which was associated with a reduction in interleukin-8 expression. These findings suggest that DFMO has effects on H. pylori that may contribute to its effectiveness in reducing gastritis and colonization and may be a useful addition to anti-H. pylori therapies.     

Potential role of thiol:disulfide oxidoreductases in the pathogenesis of Helicobacter pylori

Helicobacter pylori infections are responsible for a sequence of molecular events which ultimately result in the development of gastric diseases. The pathogenesis of H. pylori has been studied extensively with strong focus on the identification of virulence factors. In contrast, the involvement of thiol:disulfide oxidoreductases in bacterial pathogenesis is less well understood. This paper provides a review of the current knowledge of H. pylori putative thiol:disulfide oxidoreductases, and their potential role in promoting virulence and colonization. Several bioinformatic analyses served to complete the information on these oxidoreductases of H. pylori.     

Pathogenesis of Helicobacter pylori Infection

Helicobacter pylori induces chronic inflammation of the gastric mucosa, but only a proportion of infected individuals develop peptic ulcer disease or gastric carcinoma. Reasons underlying these observations include differences in bacterial pathogenicity as well as in host susceptibility. Numerous studies published in the last year provided new insight into H. pylori virulence factors, their interaction with the host and consequences in pathogenesis. These include the role of bacterial genetic diversity in host colonization and persistence, outer membrane proteins and modulation of adhesin expression, new aspects of VacA functions, and CagA and its phosphorylation-dependent and -independent cellular effects. This article will also review the recent novel findings on the interactions of H. pylori with diverse host epithelial signaling pathways and events involved in the initiation of carcinogenesis, including genetic instability and dysregulation of DNA repair.     

Pathogenesis of Helicobacter pylori Infection

The clinical outcome of Helicobacter pylori infection is determined by a complex scenario of interactions between the bacterium and the host. The main bacterial factors associated with colonization and pathogenicity comprise outer membrane proteins including BabA, SabA, OipA, AlpA/B, as well as the virulence factors CagA in the cag pathogenicity island ( cag PAI) and the vacuolating cytotoxin VacA. The multitude of these proteins and allelic variation makes it extremely difficult to test the contribution of each individual factor. Much effort has been put into identifying the mechanism associated with H. pylori -associated carcinogenesis. Interaction between bacterial factors such as CagA and host signal transduction pathways seems to be critical for mediating the induction of membrane dynamics, actin-cytoskeletal rearrangements and the disruption of cell-to-cell junctions as well as proliferative, pro-inflammatory and antiapoptotic nuclear responses. An animal model using the Mongolian gerbil is a useful system to study the gastric pathology of H. pylori infection.     

幽门螺杆菌在胃内定植的相关影响因素

胃内定植是引起幽门螺杆菌(Helicobacter pylori,H.pylori)感染的先决条件。H.pylori可穿过胃黏液层并与胃上皮细胞相互作用。这个定植过程主要受到H.pylori动力和尿素酶的影响。同时H.pylori形态、胃内pH、外膜蛋白及益生菌等也在其中扮演重要角色。该研究主要对H.pylori胃内定植过程中的相关影响因素进行综述。     

Pretreatment antimicrobial susceptibilities of paired gastric Helicobacter pylori isolates: antrum versus corpus

Background. Antimicrobial susceptibility testing of Helicobacter pylori isolates is the most useful tool for guiding specific therapy, especially when primary resistance is suspected. However, the most informative gastric biopsy site for detection of resistant H. pylori isolates is uncertain. We sought to determine whether susceptibilities to commonly used antimicrobials (amoxicillin, clarithromycin, minocycline, and metronidazole) were related to biopsy site.
Methods. H. pylori isolates were obtained from patients who had duodenal ulcer and had not received any therapy directed against H. pylori. Agar-dilution minimum inhibitory concentrations of each antimicrobial were compared between paired H. pylori isolates from the antrum and the proximal corpus.
Results. Differences in minimum inhibitory concentrations exceeding twofold were observed within the pairs of H. pylori isolates in 5 of the 40 patients tested. In three patients with clarithromycin-resistant isolates and two with metronidazole-resistant isolates, both antral and corporeal specimens revealed resistance. However, no patient had pairs of isolates categorized as resistant at one site and sensitive at the other.
Conclusions. While we found that an individual may have a mixed H. pylori infection with respect to differing antimicrobial susceptibility in different parts of the stomach, a single biopsy specimen from either the antrum or the corpus should provide reliable detection of H. pylori isolates with primary resistance.