Bicarbonate transport mechanisms in rabbit ciliary body epithelium.

Sections of whole ciliary body dissected from Dutch belted rabbits were incubated with the cell entrappable pH probe BCECEF-AM. This led to a highly specific localization of epifluorescence emission at the exposed, non-pigmented cell layer (npe) of the dual layered epithelium that covers this organ. The BCECF-loaded tissue sections were superfused in a flow-through chamber and the intracellular pH (pHi) of small groups (10-20) of cells was derived from the ratio of the emission intensities derived from excitations at 490 and 440 nm. In CO2/HCO3- Ringer's, npe pHi = 7.09 +/- 0.11. Replacement of CO2/HCO3- by Hepes increased pHi by 0.22 +/- 0.02, indicating alkali secretory activity under the bicarbonate-rich conditions. Replacement of Cl- by gluconate elicited a rapid, 0.6-U increase in pHi. This effect exhibited little dependence on Na+ and was inhibited by 0.5 mM dihydro-4,4'-diisothiocyanatostilbene -2,2'-disulfonate (H2DIDS). These results indicate the presence of an electroneutral Cl-/base exchange activity. Elevation of [K-] (by partial replacement of Na+) also elicited increases in pHi. In Cl(-)-free media pHi reached 7.8-8.0, a condition under which intracellular [HCO3-] is at least twice as high as its extracellular value. This effect did not occur in the absence of Na+. The Na(+)-dependent high [K+]-induced pHi increase was inhibited by H2DIDS. The effects of Ba2+ on pHi, alone and in combination with high [K+], as well as that of full K+ removal, suggested that the link between high [K+] and pHi increase was mainly due to the effect of cell depolarization on an electronegative Na+ dependent HCO3- transporter. Under normal physiological conditions, the two acid/base transport systems are the main determinants of npe pHi.