Propionate-initiated changes in intracellular pH in rabbit colonocytes

Background/Aims: Because regulation of intracellular pH (pHi) is critical to basic cell functions, most celts have evolved mechanisms to closely regulate intracellular acid-base balance. Short-chain fatty acids (SCFAs), the predominant luminal anion in the colon, acidify the cell interior in several cell systems, but their effect on their “natural target,” the colonocytes, has not been examined thoroughly. Methods: We monitored the pHi response to a model SCFA, propionate, in isolated cells and epithelial sheets from rabbit proximal colon loaded with the pH-sensitive dye 2′,7′-bis-(2-carboxyethyl)-5-(and -6) carboxyfluorescein.Results: SCFAs induced a characteristic pHi response curve in colonocytes: an immediate acidification and a recovery phase returning to baseline in 100–200 seconds. Acidification was altered by increasing concentrations of SCFAs, by increasing SCFA chain length, extracellular osmolarity, and intracellular pH, and finally, Na+ removal. The recovery phase was slowed by amiloride and 4-α-OH cinnamate, an inhibitor of proton-monocar-boxylate cotransport. Conclusions: Physiological concentrations of SCFAs have profound effects on intracellular pH. Simple diffusion of the SCFA may not explain the complexities of propionate-induced protonated acidification; the pH recovery phase may involve multiple processes including Na+-H+ exchange and H+-SCFA cotransport. Luminal constituents such as SCFAs may have significant effects on the intracellular pH and function of colonocytes.