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AimThis study aimed to explore the molecular mechanisms for the parietal cell loss and fundic hyperplasia observed in gastric mucosa of mice lacking the carbonic anhydrase 9 (CAIX).MethodsWe assessed the ability of CAIX‐knockout and WT gastric surface epithelial cells to withstand a luminal acid load by measuring the pH i of exteriorized gastric mucosa in vivo using two‐photon confocal laser scanning microscopy. Cytokines and claudin‐18A2 expression was analysed by RT‐PCR.Results CAIX‐knockout gastric surface epithelial cells showed significantly faster pH i decline after luminal acid load compared to WT. Increased gastric mucosal IL‐1β and iNOS, but decreased claudin‐18A2 expression (which confer acid resistance) was observed shortly after weaning, prior to the loss of parietal and chief cells. At birth, neither inflammatory cytokines nor claudin‐18 expression were altered between CAIX and WT gastric mucosa. The gradual loss of acid secretory capacity was paralleled by an increase in serum gastrin, IL‐11 and foveolar hyperplasia. Mild chronic proton pump inhibition from the time of weaning did not prevent the claudin‐18 decrease nor the increase in inflammatory markers at 1 month of age, except for IL‐1β. However, the treatment reduced the parietal cell loss in CAIX‐KO mice in the subsequent months.ConclusionsWe propose that CAIX converts protons that either backflux or are extruded from the cells rapidly to CO 2 and H2O, contributing to tight junction protection and gastric epithelial pH i regulation. Lack of CAIX results in persistent acid backflux via claudin‐18 downregulation, causing loss of parietal cells, hypergastrinaemia and foveolar hyperplasia.
Background/Aims: Enterocytes express a number of NHE isoforms with presumed localization in the apical (NHE2, 3 and 8) or basolateral (NHE1) membrane. Functional activity and localization of enterocyte NHE isoforms were assessed using fully differentiated Caco-2BBe cells, whose genetic expression profile closely resembles mature enterocytes. Methods: The activity of the different NHEs was analyzed by fluorometric pHi-metry in a perfusion chamber with separate apical and basolateral perfusion, using specific inhibitors and shRNA knockdown of NHE2. The expression of the NHEs and of other relevant acid extrusion transporters was quantified by qPCR. Results: Quantitative comparison of the mRNA expression levels of the different NHE isoforms in 14 day-differentiated Caco-2BBe cells showed the following order: NHE2>NHE8>NHE3>NHE1. Acid-activated NHE exchange rates in the basolateral membrane were >6-fold higher than in the apical membrane. 79 ± 3 % of the acid-activated basolateral Na+/H+ exchange rate displayed a NHE1-typical inhibitor profile, and no NHE2/3/8 typical activity could be observed. Analysis of the apical Na+/H+ exchange rates revealed that approximately 51 ± 3 % of the total apical activity displayed a NHE2/8-typical inhibitor profile and 31 ± 6 % a NHE3-typical inhibitor profile. Because no selective NHE2 inhibitor is available, a stable NHE2 knockdown cell line (C2NHE2KD) was generated. C2NHE2KD displayed a reduced NHE2-typical apical Na+/H+ exchange rate and maintained a lower steady-state pHi, despite high expression levels of other acid extruders, in particular NBCn1 (Slc4a7). Conclusion: Differentiated Caco-2BBe cells display particularly high mRNA expression levels of NHE2, which can be functionally identified in the apical membrane. Although at low intracellular pH, NHE2 transport rate was far lower than that of NHE1. NHE2 activity was nevertheless essential for the maintenance of the steady-state pHi of these cells.
BackgroundThe maintenance of epithelial function and barrier integrity is achieved by continuous renewal of the colonic epithelium through proliferation, migration and differentiation. Sodium hydrogen exchanger 2 (NHE2) is highly expressed in the colonic epithelium, where it is involved in Na+/H+ exchange, water absorption and pHi regulation. However, NHE2 deficiency in mice does not result in diarrheal phenotype. NHE2 is expressed in the cryptal region, where colonocytes exit the stem cell niche and migrate toward the surface.Aim and methodsTo study the role of NHE2 in colonocyte migration, we silenced NHE2 in the self‐differentiating Caco 2Bbe (C2Bbe) colonic cell line and studied the migration of cells using wound scratch assay. To analyze colonocyte migration during self‐renewal, NHE2−/− and WT mice were pulse‐labeled with bromodeoxyuridine (BrdU) and sacrificed at different time points. Sections taken from identical colonic segments were studied immunohistochemically.ResultsThe rate of colonocyte migration, defined by the occurrence of BrdU‐positive cells along the crypt‐villus axis was significantly higher in the colon of NHE2−/− mice compared to the control littermates. This was associated with a significant reduction in E‐cadherin and ZO‐1 expression in the basal parts of the crypts, pointing to alterations of the adhesion and tight junction formation of the colonocytes during the early stages of differentiation. Additionally, increased mRNA expression of β‐catenin was detected in isolated NHE2−/− colonic crypts compared to the control. To substantiate these findings, C2Bbe cells were stably transfected with shRNA, generating a cell line with ~70 % downregulated expression of NHE2. A significant increase of the migration rate, but reduced cell proliferation was observed in the NHE2 knock‐down compared to the mock transfected cells. This was accompanied with a significant decrease of E‐cadherin, but enhanced β‐catenin expression.ConclusionsOur results show that NHE2 is involved in the processes of colonocyte proliferation and migration along the crypt axis. Alterations in the cell adhesion formation, the Wnt/β‐catenin signaling pathway and disturbed formation of the E‐cadherin/β‐catenin complex, possibly induced by a lower pHi in NHE2‐deficient colonocytes, may be responsible for the increase in colonocyte migratory speed.Support or Funding InformationVolkswagen Foundation (VW‐Vorab), SFB621/C9, Se460/9‐4 and 21‐1.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.
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