Helicobacter pylori-mediated gastric pathogenesis is attenuated by treatment of 2-deoxyglucose and metformin.

Helicobacter pylori infection causes chronic inflammation in the stomach, which is linked to the development of gastric cancer. The anti-inflammatory and anticancer effects of a glycolysis inhibitor 2-deoxyglucose (2DG) and an antidiabetic medication metformin (Met) have gotten attention. Using a Mongolian gerbil animal model, we investigated H. pylori-mediated gastric pathogenesis and how this pathogenesis is influenced by 2DG and Met. Five-week-old male gerbils were infected with H. pylori strain 7.13. After 2 weeks of infection, gerbils were fed 2DG-containing food (0.03% w/w), Met-containing water (0.5% w/v), or both (Combi) for 2 (short-term) or 10 weeks (long-term). Gastric pathogenesis and host response to H. pylori infection were examined by macroscopic and histopathologic analysis of gerbils' stomach. As a result, indicators of gastric pathogenesis by H. pylori infection including infiltration of polymorphonuclear neutrophils and lymphocytes, intestinal metaplasia, atrophy, and proliferation of gastric epithelial cells were attenuated by short-term administration of 2DG, Met, or Combi. When the infection was sustained for long-term, gastric pathogenesis in drug-treated gerbils was equivalent to that in untreated gerbils, with the exception that the infiltration of neutrophil was reduced by 2DG. Colonization of H. pylori in stomach was unaffected by both short- and long-term treatments. Our findings demonstrate that the progression of gastric pathogenesis induced by H. pylori infection can be attenuated by the short-term individual or combinational treatment of 2DG and Met, implying that 2DG or Met could be considered as a treatment option for gastric diseases in the early stages of infection.

Characterization of East-Asian Helicobacter pylori encoding Western EPIYA-ABC CagA.

The polymorphic bacterial oncoprotein, CagA shows geography-dependent variation in the C-terminal Glu-Pro-Ile-Tyr-Ala (EPIYA) motifs; East-Asian H. pylori isolates carry the ABD type while Western isolates carry the ABC type. In Western isolates, the EPIYA-C motif is sometimes found in multi-copy and this genotype is associated with disease severity. Interestingly, a small number of East-Asian H. pylori isolates have been found to carry Western ABC-type CagA. To gain a better understanding of these unusual isolates, the genomes of four Korean H. pylori clinical isolates carrying ABC-type CagA were sequenced via third generation (Pac-Bio SMRT) sequencing technology. The obtained data were utilized for phylogenetic analysis as well as comparison of additional virulence factors that are known to show geographic-dependent polymorphisms. Three of four isolates indeed belonged to the hpEastAsia group and showed typical East-Asian polymorphism in virulence factors such as homA/B/C, babA/B/C, and oipA. One isolate grouped to HpAfrica and showed typical Western polymorphism of virulence factors such as cagA, homA/B/C, and oipA. To understand the occurrence of the multi-copy EPIYA-C motif genotype in an East-Asian H. pylori background, the Korean clinical isolate, K154 was analyzed; this strain belonged to hpEastAsia but encoded CagA EPIYA-ABCCCC. Based on DNA sequence homology within the CagA multimerization (CM) sequence that flanked the EPIYA-C motifs, we predicted that the number of C motifs might change via homologous recombination. To test this hypothesis, K154 was cultured for one generation and 287 single colonies were analyzed for the number of EPIYA-C motifs using PCR-based screening and DNA sequencing verification. Three out of 284 (1%) single colony isolates showed changes in the number of EPIYA-C motifs in vitro; one isolate increased to five EPIYA-C motifs, one decreased to three EPIYA-C motifs, and one completely deleted the EPIYA-C motifs. The capacity for dynamic changes in the number of EPIYA-C repeats of CagA may play a role in generating important intraspecies diversity in East-Asian H. pylori.

Evolutionary mechanism leading to the multi-cagA genotype in Helicobacter pylori.

Infection with CagA+ Helicobacter pylori strains is linked to an increased risk for gastric diseases, including gastric cancer. Recent evidence indicates that dynamic expansion and contraction of cagA copy number may serve as a novel mechanism to enhance disease development. Herein, comparative genomic analysis divided hpEurope into two groups: hpEurope/type-A and type-B. Only hpEurope/type-B displayed the multi-cagA genotype. Further analysis showed that cagPAI appears to have been independently introduced into two different H. pylori types, termed pre-type-A and pre-type-B, which consequently evolved to cagPAI type-A and type-B, respectively; importantly, all multi-cagA genotype strains displayed cagPAI type-B. Two direct cagA-flanking repeats of a genetic element termed CHA-ud were essential for the multi-cagA genotype in strain PMSS1 (hpEurope/type-B and cagPAI type-B). Furthermore, introduction of this genetic element into strain G27 (hpEurope/type-A and cagPAI type-A) was sufficient to generate the multi-cagA genotype. The critical steps in the evolution of the multi-cagA genotype involved creation of CHA-ud at cagA upstream in cagPAI type-B strains followed by its duplication to cagA downstream. En masse, elucidation of the mechanism by which H. pylori evolved to carry multiple copies of cagA helps to provide a better understanding of how this ancient pathogen interacts with its host.

Spread of resistant gram negatives in a Sri Lankan intensive care unit.

BACKGROUND: Infections with multi drug resistant (MDR) organisms are a major problem in intensive care units (ICUs). Proper infection control procedures are mandatory to combat the spread of resistant organisms within ICUs. Well stablished surveillance programmes will enhance the adherence of the staff to infection control protocols. The study was conducted to assess the feasibility of using basic molecular typing methods and routine hospital data for laboratory surveillance of resistance organisms in resource limited settings. METHODS: A retrospective study was conducted using consecutive Gram negative isolates obtained from an ICU over a six month period. Antibiotic sensitivity patterns and random amplified polymorphic DNA (RAPD) based typing was performed on the given isolates. RESULTS: Of the seventy isolates included in the study, seven were E.coli. All E.coli were MDRs and Extended Spectrum ß lactamse (ESBL) producers carrying bla CTX-M. Fourteen isolates were K.pneumoniae, and all were MDRs and ESBL producers. All K.pneumoniae harboured bla SHV while 13 harboured bla CTX-M. The MDR rate among P.aeruginosa was 13% (n=15) while all acinetobacters (n=30) were MDRs. Predominant clusters were identified within all four types of Gram negatives using RAPD and the ICU stay of patients overlapped temporally. CONCLUSION: We propose that simple surveillance methods like RAPD based typing and basic hospital data can be used to convince hospital staff to adhere to infection control protocols more effectively, in low and middle income countries.