Effect of omeprazole-induced achlorhydria on trefoil peptide expression in the rat stomach.

BACKGROUND: Omeprazole is an inhibitor of the H+K+ ATPase of the gastric parietal cell, which is used clinically to suppress gastric acid secretion. It has also been found to inhibit gastric mucin production; however, its effects on the synthesis and secretion of the trefoil peptides, which are also expressed by mucus cells, and which play a key role in cytoprotection and epithelial repair, are unknown. METHODS: Rats (n=8) were given either omeprazole (30 mg/kg per day; p.o.) or inert carrier for 1 week, and the effects on synthesis and peptide expression of the gastric trefoil peptides, TFF1/pS2 and TFF2/SP, were compared. RESULTS: As expected, omeprazole treatment abolished H+ ion production with a mean gastric juice pH of 7.2 compared with 2.4 for controls. The omeprazole group had elevated total protein levels of 35-fold and TFF1/pS2 peptide levels elevated fourfold, respectively, but not TFF2/SP peptide in gastric juice, suggesting that the increased pH reduced the viscosity of adherent mucus, thereby increasing gastric juice concentrations by dissolution of adherent TFF1/pS2 and increased secretion. Concomitant with increased TFF1/pS2 secretion was a fall in predominantly antral mucosal trefoil peptide concentrations. In contrast to trefoil secretory rates, the steady-state synthesis of both TFF1/pS2 and TFF2/SP was unchanged after omeprazole treatment, implying both a large cellular pool of processed peptide and rapid secretion. CONCLUSION: The increase in the concentration of TFF1/pS2 in gastric secretions during chronic omeprazole-induced achlorhydria may be important in preventing tissue injury and promoting repair in response to an increased luminal bacterial population.

Resistance to apoptosis is a mechanism of adaptation of rat stomach to aspirin.

Adaptation of the gastric mucosa to nonsteroidal anti-inflammatory drug-induced injury is a well-documented phenomenon, but the mechanisms are not known. We investigated whether changes in stress protein expression and apoptosis play roles in adaptation of rat stomach to aspirin. RT-PCR and Western blotting techniques were used to analyze mRNA and protein expression of HSP72 and HSP90 and cleavage of caspase 3 protein. Apoptosis was detected by the TUNEL method and quantified. HSP72 mRNA and protein expression was unchanged in adapted mucosa, whereas HSP90 mRNA and protein levels decreased. Caspase 3 protein was activated, and the number of apoptotic cells increased in mucosa after one aspirin dose. However, in adapted mucosa after aspirin, activated caspase 3 and the number of apoptotic cells had returned to basal levels. Induction of the stress response was found not to be a mechanism of mucosal adaptation against multiple doses of aspirin. Our results lead us to propose instead that resistance to aspirin-induced apoptosis plays a role in the protective phenomenon of adaptation.