Acid-base balance in amphibian gastric mucosa.

TitleAcid-base balance in amphibian gastric mucosa.
Publication TypeJournal Article
Year of Publication1975
AuthorsSilen W, Machen TE, Forte JG
JournalAm J Physiol
Volume229
Issue3
Pagination721-30
Date Published1975 Sep
ISSN0002-9513
KeywordsAcid-Base Equilibrium, Animals, Anura, Bicarbonates, Carbon Dioxide, Electrophysiology, Gastric Mucosa, Hydrogen-Ion Concentration, Phosphates, Potassium, Rana catesbeiana, Solutions
Abstract

It has been established that H+ secretion can be maintained in frog stomach in the absence of exogenous CO2 by using a nutrient bathing fluid containing 25 mM H2PO4 (pH approximately equal to 4.5) or by lowering the pH of a nonbuffered nutrient solution to about 3.0-3.6. Exogenous CO2 in the presence of these nutrient solutions uniformly caused a marked decrease in H+ secretion, PD, adn short-circuit current (Isc) and an increase in transmucosal resistance (R). Elevation of nutrient [k+] to 83 mM reduced R significantly but transiently without change in H+ when nutrient pH less than 5.0, whereas R returned to base line and H+ increased when nutrient pH greater than 5.0. Acidification of the nutrient medium in the presence of exogenous CO2 results in inhibition of the secretory pump, probably by decreasing intracellular pH, and also interferes with conductance at the nutrient membrane. Removal of exogenous CO2 from standard bicarbonate nutrient solution reduced by 50% the H+, PD, and Isc without change in R; K+-free nutrient solutions reverse these changes in Isc and PD but not in H+. The dropping PD and rising R induced by K+-free nutrient solutions in 5% CO2 - 95% O2 are returned toward normal by 100% O2. Our findings support an important role for exogenous CO2 in maintaining normal acid-base balance in frog mucosa by acting as an acidifying agent.

DOI10.1152/ajplegacy.1975.229.3.721
Alternate JournalAm J Physiol
PubMed ID2015
Grant List090532 / / Wellcome Trust / United Kingdom

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