Expression and localization of Na(+)-HCO(3)(-) cotransporter in bovine corneal endothelium.

Functional studies support the presence of the Na(+)-HCO(3)(-) cotransporter (NBC) in corneal endothelium and possibly corneal epithelium; however, molecular identification and membrane localization have not been reported. To test whether NBC is expressed in bovine cornea, Western blotting was performed, which showed a single band at approximately 130 kDa for freshly isolated and cultured endothelial cells, but no band for epithelium. Two isoforms of NBC have recently been cloned in kidney (kNBC) and pancreas (pNBC). RT-PCR was run using cultured and fresh bovine corneal endothelial and fresh corneal epithelial total RNA and specific primers for kNBC and pNBC. RT-PCR analysis for pNBC was positive in endothelium and weak in epithelium. The RT-PCR product was subcloned and confirmed as pNBC by sequencing. No specific bands for kNBC were obtained from corneal cells. Indirect immunofluorescence and confocal microscopy indicated that NBC locates predominantly to the basolateral membrane in corneal endothelial cells. Furthermore, Na(+)-dependent HCO(3)(-) fluxes and HCO(3)(-)-dependent cotransport with Na(+) were elicited only from the basolateral side of corneal endothelial cells. Therefore, we conclude that pNBC is present in the basolateral membrane of both fresh and cultured bovine corneal endothelium and weakly expressed in the corneal epithelium.

Basolateral Na(+)-K(+)-2Cl(-) cotransport in cultured and fresh bovine corneal endothelium.

PURPOSE: To examine whether Na(+)-K(+)-2Cl(-) cotransport has the potential to contribute to corneal endothelial ion and fluid transport in cultured and fresh bovine corneal endothelial cells. METHODS: Cl- and Na+ sensitive fluorescent dyes were used to measure furosemide-dependent ion fluxes in cultured and fresh endothelial cells. Immunoblot analysis and immunofluorescence were used to determine expression and location of the Na(+)-K(+)-2Cl(-)cotransporter (NKCC1). RESULTS: Application of furosemide (50-100 microM) reduced Cl- and Na+ influx in approximately 50% of trials using cultured cells and only 10% of trials with fresh cells; however, in all cases pretreatment with furosemide slowed Cl- efflux when cells were bathed in Cl(-)-free Ringer's. Double-sided perfusion of cultured cells indicated that furosemide-sensitive Cl- fluxes were located on the basolateral side. Immunoblot analysis revealed 174-kDa bands in both fresh and cultured cells, but the bands were denser in fresh endothelial cells. Immunofluorescence showed distinct lateral membrane staining in addition to significant amounts of perinuclear staining. CONCLUSIONS: The Na(+)-K(+)-2Cl(-) cotransporter is present in both fresh and cultured bovine corneal endothelium, and the expression is apparently higher in the fresh cells. The cotransporter is present on the lateral membrane consistent with a role in loading endothelial cells with Cl-, thereby possibly contributing to a transendothelial Cl- flux. However, in the resting cell, net flux through the transporter is often not apparent.

Apical and basolateral CO2-HCO3- permeability in cultured bovine corneal endothelial cells.

Corneal endothelial function is dependent on HCO3- transport. However, the relative HCO3- permeabilities of the apical and basolateral membranes are unknown. Using changes in intracellular pH secondary to removing CO2-HCO3- (at constant pH) or removing HCO3- alone (at constant CO2) from apical or basolateral compartments, we determined the relative apical and basolateral HCO3- permeabilities and their dependencies on Na+ and Cl-. Removal of CO2-HCO3- from the apical side caused a steady-state alkalinization (+0.08 pH units), and removal from the basolateral side caused an acidification (-0.05 pH units). Removal of HCO3- at constant CO(2) indicated that the basolateral HCO3- fluxes were about three to four times the apical fluxes. Reducing perfusate Na+ concentration to 10 mM had no effect on apical flux but slowed basolateral HCO3- flux by one-half. In the absence of Cl-, there was an apparent increase in apical HCO3- flux under constant-pH conditions; however, no net change could be measured under constant-CO2 conditions. Basolateral flux was slowed approximately 30% in the absence of Cl-, but the net flux was unchanged. The steady-state alkalinization after removal of CO2-HCO3- apically suggests that CO2 diffusion may contribute to apical HCO3- flux through the action of a membrane-associated carbonic anhydrase. Indeed, apical CO2 fluxes were inhibited by the extracellular carbonic anhydrase inhibitor benzolamide and partially restored by exogenous carbonic anhydrase. The presence of membrane-bound carbonic anhydrase (CAIV) was confirmed by immunoblotting. We conclude that the Na+-dependent basolateral HCO3- permeability is consistent with Na+-nHCO3- cotransport. Changes in HCO3- flux in the absence of Cl- are most likely due to Na+-nHCO3- cotransport-induced membrane potential changes that cannot be dissipated. Apical HCO3- permeability is relatively low, but may be augmented by CO2 diffusion in conjunction with a CAIV.