Dependence of cAMP meditated increases in Cl- and HCO(3)- permeability on CFTR in bovine corneal endothelial cells.

The cystic fibrosis transmembrane conductance regulator (CFTR) is present on the apical membrane of corneal endothelial cells. Increasing intracellular [cAMP] with forskolin stimulates an NPPB and glibenclamide-inhibitable apical Cl(-) and HCO(3)(-) permeability [Sun, X.C., Bonanno, J.A., 2002. Expression, localization, and functional evaluation of CFTR in bovine corneal endothelial cells. Am. J. Physiol. Cell Physiol. 282, C673-C683]. To definitively determine that the increased permeability is dependent on CFTR, we used an siRNA knockdown approach. Apical Cl(-) and HCO(3)(-) permeability and steady-state HCO(3)(-) flux were measured in the presence or absence of forskolin using cultured bovine corneal endothelial cells that were transfected with CFTR siRNA or a scrambled sequence control. CFTR protein expression was reduced by approximately 80% in CFTR siRNA treated cultures. Forskolin (10 microM) increased apical chloride permeability by 7-fold, which was reduced to control level in siRNA treated cells. CFTR siRNA treatment had no effect on baseline apical chloride permeability. Apical HCO(3)(-) permeability was increased 2-fold by 10 microM forskolin, which was reduced to control level in siRNA treated cultures. Similarly, there was no effect on baseline apical HCO(3)(-) permeability by knocking down CFTR expression. The steady-state apical-basolateral pH gradient (DeltapH) at 4h in control cultures was increased approximately 2.5-fold by forskolin. In CFTR siRNA treated cells, the baseline DeltapH was similar to control, however forskolin did not have a significant effect. We conclude that forskolin induced increases in apical HCO(3)(-) permeability in bovine corneal endothelium requires CFTR. However, CFTR does not have a major role in determining baseline apical chloride or HCO(3)(-) permeability.

Role of carbonic anhydrase IV in corneal endothelial HCO3- transport.

PURPOSE: Carbonic anhydrase activity has a central role in corneal endothelial function. The authors examined the role of carbonic anhydrase IV (CAIV) in facilitating CO(2) flux, HCO(3)(-) permeability, and HCO(3)(-) flux across the apical membrane. METHODS: Primary cultures of bovine corneal endothelial cells were established on membrane-permeable filters. Apical CAIV was inhibited by benzolamide or siRNA knockdown of CAIV. Apical CO(2) fluxes and HCO(3)(-) permeability were determined by measuring pH(i) changes in response to altering the CO(2) or HCO(3)(-) gradient across the apical membrane. Basolateral to apical (B-to-A) HCO(3)(-) flux was determined by measuring the pH of a weakly buffered apical bath in the presence of basolateral bicarbonate-rich Ringer solution. In addition, the effects of benzolamide and CAIV knockdown on steady state DeltapH (apical-basolateral compartment pH) after 4-hour incubation in DMEM were measured. RESULTS: CAIV expression was confirmed, and CAIV was localized exclusively to the apical membrane by confocal microscopy. Both 10 microM benzolamide and CAIV siRNA reduced apparent apical CO(2) flux by approximately 20%; however, they had no effect on HCO(3)(-) permeability or HCO(3)(-) flux. The steady state apical-basolateral pH gradient at 4 hours was reduced by 0.12 and 0.09 pH units in benzolamide- and siRNA-treated cells, respectively, inconsistent with a net cell-to-apical compartment CO(2) flux. CONCLUSIONS: CAIV does not facilitate steady state cell-to-apical CO(2) flux, apical HCO(3)(-) permeability, or B-to-A HCO(3)(-) flux. Steady state pH changes, however, suggest that CAIV may have a role in buffering the apical surface.

Characterization of adenosine receptors in bovine corneal endothelium.

Previous studies indicated that adenosine can increase [cAMP](i) and stimulate fluid transport by corneal endothelium. The purpose of this study was to determine which adenosine receptor subtype(s) are expressed and to examine their functional roles in modulating [cAMP](i), [Ca(2+)](i) and effects on Cl(-) permeability in corneal endothelium. We screened bovine corneal endothelium (BCE) for adenosine receptor subtypes by RT-PCR and immunoblotting, and examined the effects of pharmacological agents on adenosine stimulated Cl(-) transport, [cAMP](i) and [Ca(2+)](i). RT-PCR indicated the presence of A(1) and A(2b) adenosine receptors, while A(2a) and A(3) were negative. Western blot (WB) confirmed the presence of A(2b) ( approximately 50 kDa) and A(1) ( approximately 40 kDa) in fresh and cultured BCE. Ten micromolar adenosine increased [cAMP](i) by 2.7-fold over control and this was inhibited 66% by 10 microm alloxazine, a specific A(2b) blocker. A(1) activation with 1 micromN(6)-CPA (a specific A(1) agonist) or 100 nm adenosine decreased [cAMP](i) by 23 and 6%, respectively. Adenosine had no effect on [Ca(2+)](i) mobilization. Indirect immunofluorescence localized A(2b) receptors to the lateral membrane and A(1) to the apical surface in cultured BCE. Adenosine significantly increased apical Cl(-) permeability by 2.2 times and this effect was nearly abolished by DMPX (10 microm), a general A(2) blocker. Adenosine-induced membrane depolarization was also inhibited by 33% (n=6) in the presence of alloxazine. Bovine corneal endothelium expresses functional A(1) and A(2b) adenosine receptors. A(1), preferentially activated at <1 microm adenosine, acts to decrease [cAMP](i) and A(2b), activated at >1 microm adenosine, increase [cAMP](i).

Role of NBC1 in apical and basolateral HCO3- permeabilities and transendothelial HCO3- fluxes in bovine corneal endothelium.

Corneal transparency and hydration control are dependent on HCO(3)(-) transport properties of the corneal endothelium. Recent work (13) suggested the presence of an apical 1Na(+)-3HCO(3)(-) cotransporter (NBC1) in addition to a basolateral 1Na(+)-2HCO(3)(-) cotransporter. We examined whether the NBC1 cotransporter contributes significantly to basolateral or apical HCO(3)(-) permeability and whether the cotransporter participates in transendothelial net HCO(3)(-) flux in cultured bovine corneal endothelium. NBC1 protein expression was reduced using small interfering RNA (siRNA). Immunoblot analysis showed that 5-15 nM siRNA decreased NBC1 expression by 80-95%, 4 days posttransfection. Apical and basolateral HCO(3)(-) permeabilities were determined by measuring the rate of pH(i) change when HCO(3)(-) was removed from the bath under constant pH or constant CO(2) conditions. Using either protocol, we found that cultures treated with NBC1 siRNA had sixfold lower basolateral HCO(3)(-) permeability than untreated or siCONTROL siRNA-treated cells. Apical HCO(3)(-) permeability was unaffected by NBC1 siRNA treatment. Net non-steady-state HCO(3)(-) flux was 0.707 +/- 0.009 mM.min(-1).cm(2) in the basolateral-to-apical direction and increased to 1.74 +/- 0.15 when cells were stimulated with 2 muM forskolin. Treatment with 5 nM siRNA decreased basolateral-to-apical flux by 67%, whereas apical-to-basolateral flux was unaffected, significantly decreasing net HCO(3)(-) flux to 0.236 +/- 0.002. NBC1 siRNA treatment or 100 muM ouabain also eliminated steady-state HCO(3)(-) flux, as measured by apical compartment alkalinization. Collectively, reduced basolateral HCO(3)(-) permeability, basolateral-to-apical fluxes, and net HCO(3)(-) flux as a result of reduced expression of NBC1 indicate that NBC1 plays a key role in transendothelial HCO(3)(-) flux and is functional only at the basolateral membrane.

[HCO3-]-regulated expression and activity of soluble adenylyl cyclase in corneal endothelial and Calu-3 cells.

BACKGROUND: Bicarbonate activated Soluble Adenylyl Cyclase (sAC) is a unique cytoplasmic and nuclear signaling mechanism for the generation of cAMP. HCO3- activates sAC in bovine corneal endothelial cells (BCECs), increasing [cAMP] and stimulating PKA, leading to phosphorylation of the cystic fibrosis transmembrane-conductance regulator (CFTR) and increased apical Cl- permeability. Here, we examined whether HCO3- may also regulate the expression of sAC and thereby affect the production of cAMP upon activation by HCO3- and the stimulation of CFTR in BCECs. RESULTS: RT-competitive PCR indicated that sAC mRNA expression in BCECs is dependent on [HCO3-] and incubation time in HCO3-. Immunoblots showed that 10 and 40 mM HCO3- increased sAC protein expression by 45% and 87%, respectively, relative to cells cultured in the absence of HCO3-. Furthermore, 40 mM HCO3- up-regulated sAC protein expression in Calu-3 cells by 93%. On the other hand, sAC expression in BCECs and Calu-3 cells was unaffected by changes in bath pH or osmolarity. Interestingly, BCECs pre-treated with10 microM adenosine or 10 microM forskolin, which increase cAMP levels, showed decreased sAC mRNA expression by 20% and 30%, respectively. Intracellular cAMP production by sAC paralleled the time and [HCO3-]-dependent expression of sAC. Bicarbonate-induced apical Cl- permeability increased by 78% (P < 0.01) in BCECs cultured in HCO3-. However for cells cultured in the absence of HCO3-, apical Cl- permeability increased by only 10.3% (P > 0.05). CONCLUSION: HCO3- not only directly activates sAC, but also up-regulates the expression of sAC. These results suggest that active cellular uptake of HCO3- can contribute to the basal level of cellular cAMP in tissues that express sAC.

Identification and cloning of the Na/HCO(3-) cotransporter (NBC) in human corneal endothelium.

Fluid secretion by the corneal endothelium is associated with the net flux of HCO(3)(-) from basolateral (stromal) to apical (anterior chamber) sides of the tissue. In this study we asked if Na(+)/HCO(3)(-) cotransporter (NBC-1) protein expression and functional activity are present in freshly isolated human corneal endothelium. Immunoblot analysis using a polyclonal antibody to NBC-1 showed a single band at approximately 130 kDa. Indirect immunofluorescence indicated that NBC-1 is expressed on the basolateral, but not apical side of human corneal endothelium. RT-PCR was used to determine whether the kidney or pancreatic isoform of NBC-1 is expressed. Using the specific primers for pNBC and kNBC isoforms, RT-PCR showed that only pNBC could be detected in human corneal endothelium. The product was cloned and confirmed by sequencing. Full-length NBC-1 was also cloned from human corneal endothelium. This clone (hcNBC) is 100% identical to the longer, more common form of NBC [pNBC; 1079 amino acids (aa); 122 kDa in human heart, pancreas and prostate]. To test for functional activity of NBC-1, freshly isolated endothelium was loaded with the pH sensitive fluorescent dye BCECF and HCO(3)(-) fluxes were measured. HCO(3)(-) fluxes were Na(+)-dependent, electrogenic and H(2)-DIDS sensitive. We conclude that the long isoform of the sodium bicarbonate cotransporter (pNBC-1) is expressed on the basolateral side of fresh human corneal endothelium (hcNBC). The shorter form, kNBC, could not be detected. As in bovine corneal endothelium, hcNBC is instrumental in loading HCO(3)(-) into endothelial cells from the basolateral membrane.

HCO(3)(-)-dependent soluble adenylyl cyclase activates cystic fibrosis transmembrane conductance regulator in corneal endothelium.

cAMP-dependent activation of the cystic fibrosis transmembrane conductance regulator (CFTR) regulates fluid transport in many tissues. Secretion by the corneal endothelium is stimulated by cAMP and dependent on HCO(3)(-). We asked whether HCO(3)(-) can secondarily increase CFTR permeability in bovine corneal endothelial cells (BCEC) by activating soluble adenylyl cyclase (sAC). Immunofluorescence suggests that sAC is distributed throughout the cytoplasm. HCO(3)(-) (40 mM) increased cAMP concentration 42% in the presence of 50 microM rolipram (a phosphodiesterase 4 inhibitor), and a standard HCO(3)(-) Ringer solution (28.5 mM) increased apical Cl(-) permeability by 78% relative to HCO(3)(-)-free solution. The HCO(3)(-)-dependent increase in Cl(-) permeability was reduced 60% by 20 mM NaHSO(3) (a weak agonist of sAC). NaHSO(3) alone increased apical Cl(-) permeability by only 13%. The HCO(3)(-)-dependent increase in Cl(-) permeability was reduced 57% in the presence of 50 microM Rp-adenosine 3',5'-cyclic monophosphorothioate, and 86% by 50 microM 5-nitro-2-(3-phenylpropyl-amino)benzoic acid but unaffected by 200 microM apical H(2)DIDS. CFTR phosphorylation was increased 23, 150, and 32% by 20 mM HSO(3)(-), 28.5 mM HCO(3)(-), and 28.5 mM HCO(3)(-) + 20 mM HSO(3)(-), respectively. Activation of apical Cl(-) permeability by 5 microM genistein was increased synergistically by HCO(3)(-) over that due to genistein and HCO(3)(-) alone. We conclude that HCO(3)(-)-stimulated sAC is a form of autocrine signaling that contributes to baseline cAMP production, thereby affecting baseline CFTR activity in BCEC. This form of autocrine signaling may be important in tissues that express sAC and exhibit robust HCO(3)(-) influx (e.g., ocular ciliary epithelium, choroid plexus, and airway epithelium).

Enhancement of HCO(3)(-) permeability across the apical membrane of bovine corneal endothelium by multiple signaling pathways.

PURPOSE: In this study, the involvement of signaling pathways in the regulation of HCO(3)(-) permeability across the apical membrane of the corneal endothelium was examined. METHODS: Cultured bovine corneal endothelial cells (CBCECs) were grown to confluence on permeable membranes. Apical and basolateral sides were perfused with a HCO(3)(-)-rich Cl(-)-free Ringer's solution (28.5 mM; pH 7.5). Relative changes in apical HCO(3)(-) permeability were assayed by pulsing the apical perfusion bath with a low-HCO(3)(-) Cl(-)-free Ringer's solution (2.85 mM; pH 6.5), in the presence or absence of agonists or inhibitors, and comparing the rates of change in intracellular pH (pH(i)), as measured with a pH-sensitive dye. Ca(2+)-activated signaling was measured with the Ca(2+)-sensitive dye Fura-2. Qualitative changes in membrane potential (E(m)) were measured with a voltage-sensitive dye. RT-PCR using calcium-activated chloride channel (CLCA)-specific primers was used to examine the expression of CLCA in the corneal endothelium. RESULTS: The adenoceptor agonist adenosine (20 M) enhanced HCO(3)(-) permeability by a factor of 2. Forskolin (40 microM) exerted a 6.3-fold increase of HCO(3)(-) permeability, which was inhibited by the Cl(-) channel blockers, glibenclamide (50 microM) and niflumic acid (100 microM). Adenosine triphosphate (ATP) and ATPgammaS, P(2) receptor agonists that increased intracellular Ca(2+) in corneal endothelium, enhanced HCO(3)(-) permeability by 87% and 79%, respectively. ATPgammaS induced depolarization of the E(m), consistent with anion channel activation, rather than activation of Ca(2+)-dependent K(+) channels, which could secondarily increase extrusion of anions by E(m) hyperpolarization. Cyclopiazonic acid (CPA), an endoplasmic reticulum (ER) Ca(2+)-pump inhibitor that increased [Ca(2+)](i), also enhanced HCO(3)(-) permeability by 95%. Both the calmodulin kinase II (CaMKII) inhibitor KN-62 and the PKC inhibitor bisindolylmaleimide I (BIMI), decreased HCO(3)(-) permeability induced by ATPgammaS. The PKC activator PMA also increased HCO(3)(-) permeability by a factor of 1.8. RT-PCR using CLCA-specific primers showed the expression of CLCA1 in both fresh and cultured BCECs. CONCLUSIONS: Activation of adenoceptors and purinoceptors enhances HCO(3)(-) permeability across the apical membrane of the cultured corneal endothelium. Multiple signaling pathways (PKA, PKC, and Ca(2+)/CaMKII) contribute to the HCO(3)(-) transport in cultured corneal endothelium. Both cAMP and Ca(2+)-activated Cl(-) channels (possibly CLCA) may be involved in HCO(3)(-) transport.

Expression, localization, and functional evaluation of CFTR in bovine corneal endothelial cells.

HCO-dependent fluid secretion by the corneal endothelium controls corneal hydration and maintains corneal transparency. Recently, it has been shown that mRNA for the cystic fibrosis transmembrane conductance regulator (CFTR) is expressed in the corneal endothelium; however, protein expression, functional localization, and a possible role in HCO transport have not been reported. Immunoblotting for CFTR showed a single band at approximately 170 kDa for both freshly isolated and primary cultures of bovine corneal endothelial cells. Indirect immunofluorescence confocal microscopy indicated that CFTR locates to the apical membrane. Relative changes in apical and basolateral chloride permeability were estimated by measuring the rate of fluorescence quenching of the halide-sensitive indicator 6-methoxy-N-ethylquinolinium iodide during Cl(-) influx in the absence and presence of forskolin (FSK). Apical and basolateral Cl(-) permeability increased 10- and 3-fold, respectively, in the presence of 50 microM FSK. FSK-activated apical chloride permeability was unaffected by H(2)DIDs (250 microM); however, 5-nitro-2-(3-phenylpropyl-amino)benzoic acid (NPPB; 50 microM) and glibenclamide (100 microM ) inhibited activated Cl(-) fluxes by 45% and 30%, respectively. FSK-activated basolateral Cl(-) permeability was insensitive to NPPB, glibenclamide, or furosemide but was inhibited 80% by H(2)DIDS. HCO permeability was estimated by measuring changes in intracellular pH in response to quickly lowering bath [HCO]. FSK (50 microM) increased apical HCO permeability by twofold, which was inhibited 42% by NPPB and 65% by glibenclamide. Basolateral HCO permeability was unaffected by FSK. Genistein (50 microM) significantly increased apical HCO and Cl(minus sign) permeability by 1.8- and 16-fold, respectively. When 50 microM genistein was combined with 50 microM FSK, there was no further increase in Cl(-) permeability; however, HCO permeability was reduced to the control level. In summary, we conclude that CFTR is present in the apical membrane of bovine corneal endothelium and could contribute to transendothelial Cl(-) and HCO transport. Furthermore, there is a cAMP-activated Cl(-) pathway on the basolateral membrane that is not CFTR.