Distinguishing among HCO 3- , CO 3= , and H + as Substrates of Proteins That Appear To Be "Bicarbonate" Transporters.

BACKGROUND: Differentiating among HCO 3- , CO 3= , and H + movements across membranes has long seemed impossible. We now seek to discriminate unambiguously among three alternate mechanisms: the inward flux of 2 HCO 3- (mechanism 1), the inward flux of 1 CO 3= (mechanism 2), and the CO 2 /HCO 3- -stimulated outward flux of 2 H + (mechanism 3). METHODS: As a test case, we use electrophysiology and heterologous expression in Xenopus oocytes to examine SLC4 family members that appear to transport "bicarbonate" ("HCO 3- "). RESULTS: First, we note that cell-surface carbonic anhydrase should catalyze the forward reaction CO 2 +OH - →HCO 3- if HCO 3- is the substrate; if it is not, the reverse reaction should occur. Monitoring changes in cell-surface pH ( Δ pH S ) with or without cell-surface carbonic anhydrase, we find that the presumed Cl-"HCO 3 " exchanger AE1 (SLC4A1) does indeed transport HCO 3- (mechanism 1) as long supposed, whereas the electrogenic Na/"HCO 3 " cotransporter NBCe1 (SLC4A4) and the electroneutral Na + -driven Cl-"HCO 3 " exchanger NDCBE (SLC4A8) do not. Second, we use mathematical simulations to show that each of the three mechanisms generates unique quantities of H + at the cell surface (measured as Δ pH S ) per charge transported (measured as change in membrane current, ΔIm ). Calibrating ΔpH S /Δ Im in oocytes expressing the H + channel H V 1, we find that our NBCe1 data align closely with predictions of CO 3= transport (mechanism 2), while ruling out HCO 3- (mechanism 1) and CO 2 /HCO 3- -stimulated H + transport (mechanism 3). CONCLUSIONS: Our surface chemistry approach makes it possible for the first time to distinguish among HCO 3- , CO 3= , and H + fluxes, thereby providing insight into molecular actions of clinically relevant acid-base transporters and carbonic-anhydrase inhibitors.

A secretagogue-small interfering RNA conjugate confers resistance to cytotoxicity in a cell model of Sjögren's syndrome.

OBJECTIVE: Sjögren's syndrome (SS) is characterized by xerophthalmia and xerostomia resulting from loss of secretory function due to immune cell infiltration in lacrimal and salivary glands. Current therapeutic strategies for SS use secretagogues to induce secretion via muscarinic receptor stimulation. The purpose of this study was to create a secretagogue-small interfering RNA (siRNA) conjugate to deliver siRNA into cells via receptor-mediated endocytosis, thereby altering epithelial cell responses to external cues, such as proinflammatory or death signals, while simultaneously stimulating secretion. METHODS: Based on our expertise with type 3 muscarinic receptor (M3), we used carbachol, a ligand specific for muscarinic receptor, as the secretagogue. Carbachol was synthesized with an active choline group and was conjugated with an siRNA that targets caspase 3. A human salivary gland (HSG) cell line was used to test the efficacy of this secretagogue-siRNA conjugate. RESULTS: Lipofectamine transfection of the conjugate into HSG cells resulted in a 78% reduction in the expression of the caspase 3 gene, while external conjugate treatment of HSG cells resulted in intracellular calcium release and induction of endocytosis at levels similar to those of carbachol stimulation, indicating that the siRNA and carbachol portions of the conjugate retained their function after conjugation. HSG cells treated with conjugate (without Lipofectamine transfection) exhibited a 50% reduction in caspase 3 gene and protein expression, indicating that our conjugate was effective in delivering functional siRNA into cells via receptor-mediated endocytosis. Furthermore, tumor necrosis factor α-induced apoptosis was significantly reduced in conjugate-treated cells. CONCLUSION: Our secretagogue-siRNA conjugate prevented cytokine-induced apoptosis in salivary gland epithelial cells, which is critical to maintaining fluid secretion and potentially reversing the clinical hallmark of SS.

PKC{alpha}{beta}{gamma}- and PKC{delta}-dependent endocytosis of NBCe1-A and NBCe1-B in salivary parotid acinar cells.

We examined membrane trafficking of NBCe1-A and NBCe1-B variants of the electrogenic Na(+)-HCO(3)(-) cotransporter (NBCe1) encoded by the SLC4A4 gene, using confocal fluorescent microscopy in rat parotid acinar cells (ParC5 and ParC10). We showed that yellow fluorescent protein (YFP)-tagged NBCe1-A and green fluorescent protein (GFP)-tagged NBCe1-B are colocalized with E-cadherin in the basolateral membrane (BLM) but not with the apical membrane marker zona occludens 1 (ZO-1). We inhibited constitutive recycling with monensin and W13 and detected that NBCe1-A and NBCe1-B accumulated in vesicles marked with the early endosomal marker early endosome antigen-1 (EEA1), with a parallel loss from the BLM. We observed that NBCe1-A and NBCe1-B undergo massive carbachol (CCh)-stimulated redistribution from the BLM into early endosomes. We showed that internalization of NBCe1-A and NBCe1-B was prevented by the general PKC inhibitor GF-109203X, the PKCalphabetagamma-specific inhibitor Gö-6976, and the PKCdelta-specific inhibitor rottlerin. We verified the involvement of PKCdelta by blocking CCh-induced internalization of NBCe1-A-cyan fluorescent protein (CFP) in cells transfected with dominant-negative kinase-dead (Lys376Arg) PKCdelta-GFP. Our data suggest that NBCe1-A and NBCe1-B undergo constitutive and CCh-stimulated endocytosis regulated by conventional PKCs (PKCalphabetagamma) and by novel PKCdelta in rat epithelial cells. To help develop a more complete model of the role of NBCe1 in parotid acinar cells we also investigated the initial phase of the secretory response to cholinergic agonist. In an Ussing chamber study we showed that inhibition of basolateral NBCe1 with 5-chloro-2,3-dihydro-3-(hydroxy-2-thienylmethylene)-2-oxo-1H-indole-1-carboxamide (tenidap) significantly decreases an initial phase of luminal anion secretion measured as a transient short-circuit current (I(sc)) across ParC10 cell monolayers. Using trafficking and functional data we propose a model that describes a physiological role of NBC in salivary acinar cell secretion.

Electrogenic NBCe1 (SLC4A4), but not electroneutral NBCn1 (SLC4A7), cotransporter undergoes cholinergic-stimulated endocytosis in salivary ParC5 cells.

Cholinergic agonists are major stimuli for fluid secretion in parotid acinar cells. Saliva bicarbonate is essential for maintaining oral health. Electrogenic and electroneutral Na(+)-HCO(3)(-) cotransporters (NBCe1 and NBCn1) are abundant in parotid glands. We previously reported that angiotensin regulates NBCe1 by endocytosis in Xenopus oocytes. Here, we studied cholinergic regulation of NBCe1 and NBCn1 membrane trafficking by confocal fluorescent microscopy and surface biotinylation in parotid epithelial cells. NBCe1 and NBCn1 colocalized with E-cadherin monoclonal antibody at the basolateral membrane (BLM) in polarized ParC5 cells. Inhibition of constitutive recycling with the carboxylic ionophore monensin or the calmodulin antagonist W-13 caused NBCe1 to accumulate in early endosomes with a parallel loss from the BLM, suggesting that NBCe1 is constitutively endocytosed. Carbachol and PMA likewise caused redistribution of NBCe1 from BLM to early endosomes. The PKC inhibitor, GF-109203X, blocked this redistribution, indicating a role for PKC. In contrast, BLM NBCn1 was not downregulated in parotid acinar cells treated with constitutive recycling inhibitors, cholinergic stimulators, or PMA. We likewise demonstrate striking differences in regulation of membrane trafficking of NBCe1 vs. NBCn1 in resting and stimulated cells. We speculate that endocytosis of NBCe1, which coincides with the transition to a steady-state phase of stimulated fluid secretion, could be a part of acinar cell adjustment to a continuous secretory response. Stable association of NBCn1 at the membrane may facilitate constitutive uptake of HCO(3)(-) across the BLM, thus supporting HCO(3)(-) luminal secretion and/or maintaining acid-base homeostasis in stimulated cells.

ANG II and calmodulin/CaMKII regulate surface expression and functional activity of NBCe1 via separate means.

We recently reported that ANG II inhibits NBCe1 current and surface expression in Xenopus laevis oocytes (Perry C, Blaine J, Le H, and Grichtchenko II. Am J Physiol Renal Physiol 290: F417-F427, 2006). Here, we investigated mechanisms of ANG II-induced changes in NBCe1 surface expression. We showed that the PKC inhibitor GF109203X blocks and EGTA reduces surface cotransporter loss in ANG II-treated oocytes, suggesting roles for PKC and Ca(2+). Using the endosomal marker FM 4-64 and enhanced green fluorescent protein (EGFP)-tagged NBCe1, we showed that ANG II stimulates endocytosis of NBCe1. To eliminate the possibility that ANG II inhibits NBCe1 recycling, we demonstrated that the recycling inhibitor monensin decreases surface expression, accumulates NBCe1-EGFP in endosomes, and inhibits NBCe1 current. Monensin and ANG II applied together produce greater inhibition of NBCe1 current than either did alone. This additive effect of monensin and ANG II suggests that ANG II stimulates internalization of NBCe1. We used the calmodulin (CaM) antagonist W13, which controls recycling by blocking the exit of the endocytosed cargo from early endosomes, to determine the role of CaM in NBCe1 trafficking. We demonstrated that W13 decreases surface expression of NBCe1, accumulates NBCe1-EGFP in endosomal-like formations, and inhibits NBCe1 current. W13 and ANG II applied together produce greater inhibition of NBCe1 current than either does alone, while W13 and monensin applied together do not. The additive effect of ANG II and W13 and lack of additive effect of monensin and W13 suggest that CaM is not involved in ANG II stimulation of internalization but controls recycling of endocytosed NBCe1. The CaM-activated enzyme CaM kinase II (CaMKII) applied with ANG II also gives an additive inhibitory effect, suggesting a role for CaMKII in NBCe1 recycling.

PMA- and ANG II-induced PKC regulation of the renal Na+-HCO3- cotransporter (hkNBCe1).

The renal electrogenic Na(+)-HCO3- cotransporter (hkNBCe1) plays a major role in the bicarbonate reabsorption by the kidney. We examined how PMA- and ANG II-activated PKCs regulate hkNBCe1 expressed with or without the ANG II receptors AT(1B) in Xenopus laevis oocytes. We found that 10 nM PMA halved the hkNBCe1 current detected in voltage-clamped oocytes. A PKC-specific inhibitor GF-109203X, and a specific inhibitor of Ca-dependent conventional PKCalphabetagamma, GO-6976, significantly reduced PMA inhibition. PMA did not alter surface expression of the cotransporters, but it significantly increased hkNBCe1-PKCalphabetagamma membrane association. We found that at 10(-6) M, ANG II halved the hkNBCe1 current detected in oocytes coexpressing cotransporters with AT(1B). A PKC-specific inhibitor GF-109203X, and a PKCepsilon translocation inhibitor epsilonV1-2 peptide as well as BAPTA-AM (but not GO-6976), significantly reduced ANG II inhibition. At 10(-6) M, ANG II significantly decreased surface expression of the cotransporters and increased hkNBCe1-PKCepsilon membrane association. Additionally, we found that at 10(-11) and 10(-10) M ANG II stimulated hkNBCe1 current. This effect was blocked by BAPTA-AM and partially reduced by GF-109203X. We also found that ANG II increased intracellular Ca2+ in fluo 4-loaded oocytes. Our results suggest that 1) PMA inhibition of hkNBCe1 is mediated by Ca-dependent PKCalphabetagamma and 10 nM PMA does not induce downregulation of cotransporter surface expression. 2) ANG II (10(-6) M) inhibition of hkNBCe1 is mediated by both Ca-independent PKCepsilon and downregulation of cotransporter surface expression, possibly triggered by intracellular Ca2+ mobilization. 3) Similar to proximal tubule, acute ANG II has a biphasic effect on hkNBCe1 coexpressed with AT(1B) in X. laevis oocytes.

Transport of volatile solutes through AQP1.

For almost a century it was generally assumed that the lipid phases of all biological membranes are freely permeable to gases. However, recent observations challenge this dogma. The apical membranes of epithelial cells exposed to hostile environments, such as gastric glands, have no demonstrable permeability to the gases CO2 and NH3. Additionally, the water channel protein aquaporin 1 (AQP1), expressed at high levels in erythrocytes, can increase membrane CO2 permeability when expressed in Xenopus oocytes. Similarly, nodulin-26, which is closely related to AQP1, can act as a conduit for NH3. A key question is whether aquaporins, which are abundant in virtually every tissue that transports O2 and CO2 at high levels, ever play a physiologically significant role in the transport of small volatile molecules. Preliminary data are consistent with the hypothesis that AQP1 enhances the reabsorption of HCO3- by the renal proximal tubule by increasing the CO2 permeability of the apical membrane. Other preliminary data on Xenopus oocytes heterologously expressing the electrogenic Na+-HCO3- cotransporter (NBC), AQP1 and carbonic anhydrases are consistent with the hypothesis that the macroscopic cotransport of Na+ plus two HCO3- occurs as NBC transports Na+ plus CO3(2-) and AQP1 transports CO2 and H2O. Although data - obtained on AQP1 reconstituted into liposomes or on materials from AQP1 knockout mice - appear inconsistent with the model that AQP1 mediates substantial CO2 transport in certain preparations, the existence of unstirred layers or perfusion-limited conditions may have masked the contribution of AQP1 to CO2 permeability.

Specificity of anion exchange mediated by mouse Slc26a6.

Recently, CFEX, the mouse orthologue of human SLC26A6, was localized to the brush border membrane of proximal tubule cells and was demonstrated to mediate Cl(-)-formate exchange when expressed in Xenopus oocytes. The purpose of the present study was to examine whether mouse Slc26a6 can mediate one or more of the additional anion exchange processes observed to take place across the apical membrane of proximal tubule cells. Influx of [(14)C]formate into Slc26a6-expressing oocytes was inhibited by sulfate, oxalate, and p-aminohippurate (PAH), indicating affinity for these anions. Measurements of uptake of [(14)C]oxalate, [(14)C]PAH, and [(35)S]sulfate indicated that Slc26a6 can mediate transport of oxalate and sulfate but not PAH. Studies of the effect of external anions on [(14)C]oxalate efflux demonstrated Slc26a6-mediated Cl(-)-oxalate, oxalate-formate, oxalate-oxalate, and oxalate-sulfate exchange. Two-electrode voltage clamp measurements indicated that Slc26a6-mediated Cl(-)-oxalate exchange is electrogenic. Intracellular pH recordings demonstrated that Slc26a6 can mediate Cl(-)-HCO(3)(-) exchange, but Cl(-)-OH(-) exchange was not detected. The presence of 100 microm oxalate inhibited the rate of Cl(-)-HCO(3)(-) exchange by 60%. We conclude that mouse Slc26a6 has affinity for oxalate, sulfate, and HCO(3)(-) in addition to Cl(-) and formate and can function in multiple exchange modes involving pairs of these anions. In the presence of high oxalate concentrations as found in renal tubular fluid and urine, Slc26a6 may largely function as an electrogenic Cl(-)-oxalate exchanger.