Molecular & evolutionary genetics & drug resistance of the gastric pathogen, Helicobacter pylori.

Helicobacter pylori colonizes the gastric mucosa of more than half of all people worldwide and is the major cause of peptic ulcer disease and an early risk factor for gastric cancer, even though most infections are asymptomatic. Infection occurs preferentially in early childhood and once established tends to persist for years or decades. Much of the pathology H. pylori causes probably results from the host response to infection, which is affected by bacterial genotype, human host characteristics and environmental conditions. H. pylori is one of the most genetically diverse of bacterial species, with different genotypes predominating in different parts of the world. In particular, strains from India differ from those of Europe and East Asia in DNA sequence of several diagnostic gene segments. This outcome invites speculation about H. pylori origins and the possibility of Indian-specific genes that might be uncommon in Western strains. Much has been learned from H. pylori genome sequences, along with epidemiological, mutational, molecular and immunologic analyses. Candidate bacterial colonization and virulence genes and host responses are being identified, and the hypotheses being developed are amenable to tests in cell culture and animal models. These research efforts, many of which are collaborative and international, provide insights into mechanisms of establishment and persistence of H. pylori infection and virulence, and should lead to new, far more potent and cost effective anti-Helicobacter therapies or vaccines, and thereby major improvement in human health worldwide.

Estimation of vacuolating cytotoxin secreted by different strains of Helicobacter pylori using bead enzyme-linked immunosorbent assay & its correlation with bacterial genotype.

BACKGROUND & OBJECTIVES: A highly sensitive bead enzyme-linked immunosorbent assay was applied for the quantitative determination of vacuolating cytotoxin (VacA) released in the culture supernatant of 40 well characterized Helicobacter pylori strains in order to clarify the significance of allelic combination of the vacA gene as the predictor of the level of toxin secretion and also to determine the most appropriate genotype of H. pylori associated with high VacA release. Attempts were also made for the detection of VacA in the gastric juice of patients for the rapid diagnosis of H. pylori infection. METHODS: The genotypes of 40 H. pylori strains cultured from the gastric biopsy samples were determined by specific PCRs. The cell-free culture supernatant of the strains as well as the gastric juice of the patients were used for bead-ELISA and the purified VacA from the H. pylori strain ATCC49503 was used as positive control. RESULTS: Ninety per cent of the strains with vacAs1m1 allele combination secrete on an average 146.4 ng/ml of VacA while the corresponding value was 19.1 ng/ml for s1m2 strains. None of the s2m2 as well as the ice negative H. pylori strains produced detectable VacA in the medium while strains expressed the toxin irrespective of the presence or absence of cagA gene. Fifteen of 22 gastric juice samples yielded positive bead-ELISA results. INTERPRETATION & CONCLUSION: vacAs1, vacAm1 and iceA1 could be considered as the determinants of high VacA secretion. Also, the detection of VacA by bead-ELISA in the gastric juice could be considered as an alternative approach in the diagnosis of H. pylori infection.