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Logo of nihpaAbout Author manuscriptsSubmit a manuscriptNIH Public Access; Author Manuscript; Accepted for publication in peer reviewed journal;
J Biol Chem. Author manuscript; available in PMC May 13, 2013.
Published in final edited form as:
PMCID: PMC3652382
NIHMSID: NIHMS465822

Bicarbonate-regulated Adenylyl Cyclase (sAC) Is a Sensor That Regulates pH-dependent V-ATPase Recycling*

Abstract

Modulation of environmental pH is critical for the function of many biological systems. However, the molecular identity of the pH sensor and its interaction with downstream effector proteins remain poorly understood. Using the male reproductive tract as a model system in which luminal acidification is critical for sperm maturation and storage, we now report a novel pathway for pH regulation linking the bicarbonate activated soluble adenylyl cyclase (sAC) to the vacuolar H+ATPase (V-ATPase). Clear cells of the epididymis and vas deferens contain abundant V-ATPase in their apical pole and are responsible for acidifying the lumen. Proton secretion is regulated via active recycling of V-ATPase. Here we demonstrate that this recycling is regulated by luminal pH and bicarbonate. sAC is highly expressed in clear cells, and apical membrane accumulation of V-ATPase is triggered by a sAC-dependent rise in cAMP in response to alkaline luminal pH. As sAC is expressed in other acid/base transporting epithelia, including kidney and choroid plexus, this cAMP-dependent signal transduction pathway may be a widespread mechanism that allows cells to sense and modulate extracellular pH.

We recently identified bicarbonate-activated soluble adenylyl cyclase (sAC)1 as a chemosensor mediating bicarbonate-dependent elevation of cAMP (1), defining a potential transduction pathway for cells to sense variations in bicarbonate, as well as the closely related parameters, pCO2 and pH (13). sAC is distinct from transmembrane adenylyl cyclases. It is insensitive to regulation by forskolin or heterotrimeric G proteins (2) but is directly activated by bicarbonate ions. It does not have predicted transmembrane domains and is present in both soluble and particulate fractions of cellular extracts (46). Mammalian sAC is similar to bicarbonate-regulated adenylyl cyclases present in cyanobacteria (1, 2), suggesting there may be a unifying mechanism for the bicarbonate regulation of cAMP signaling in many biological systems.

sAC is highly expressed in spermatozoa (7) where it is proposed to mediate the bicarbonate-dependent cAMP elevation that precedes capacitation, hyperactivated motility, and acrosome reaction needed for fertilization (1). While spermatozoa mature and are stored along the epididymal lumen, they are kept in a quiescent state by an acidic pH of 6.5–6.8 and a low bicarbonate concentration of 2–7 mM (8). We have previously shown (9, 10) that a sub-population of epithelial cells, the so-called clear cells, are important players in the acidification capacity of the epididymis. Clear cells express high levels of the V-ATPase in their apical pole, and are responsible for the bulk of proton secretion in the vas deferens. Proton secretion by clear cells occurs in a chloride-independent but bicarbonate-dependent manner (11). Similarly to kidney intercalated cells, epididymal clear cells regulate their rate of proton secretion via V-ATPase recycling between intracellular vesicles and the apical plasma membrane (12). In these cells, as well as proton-secreting cells in the turtle bladder, an increase in V-ATPase surface expression and in apical surface area (including microvilli) closely correlates with an increase in proton secretion (1315). Proton-secreting epithelial cells actively regulate their rate of proton secretion in response to variations in the pH of their immediate environment (15). However, the molecular entities underlying this response still remain unknown. In the present study, we tested whether bicarbonate-regulated sAC might play a role in the dynamic V-ATPase recycling that occurs in these cells.

EXPERIMENTAL PROCEDURES

Laser Capture Microdissection and RT-PCR

Epithelial cells from rat cauda epididymidis were harvested by laser capture microdissection, and mRNA was extracted and amplified in vitro following a T7-based amplification procedure, as we recently described (16). For RT-PCR, oligonucleotide primer pairs were designed to amplify a short sequence in the 3′ end of the cDNA. Primers were synthesized by Sigma-Genosys (The Woodlands, TX) and are listed in Table I. The identity of PCR products was confirmed by direct sequencing (MGH, Molecular Biology DNA Sequencing Core Facility).

Table I
Sequence of the primers used for PCR PPB1, B1 subunit of the V-ATPase; PPE, E subunit of the V-ATPase; CAII, carbonic anhydrase II.

Western Blotting

Adult rats were anesthetized and perfused through the left ventricle with PBS (10 mM phosphate buffer containing 0.9% NaCl), pH 7.4, containing protease inhibitors (Complete, Roche). The epididymis was removed and the cauda region was dissected and homogenized. Electrophoresis and immunoblotting were performed as described previously (16), using a monoclonal antibody (R21) raised against the catalytic regions (C1 and C2) of sAC (6). Protein was added at 20 μg/lane, and the antibody was used at a concentration of 1:250.

Tissue Fixation and Immunofluorescence

Adult male Sprague-Dawley rats were anesthetized with sodium pentobarbital (65 mg/kg body weight, intraperitoneally) and perfused via the left ventricle with PBS (pH 7.4) followed by a fixative containing 4% paraformaldehyde, 10 mM sodium periodate, 70 mM lysine, and 5% sucrose (PLP) as described previously (11, 12). Kidney and male reproductive tract organs were harvested and further fixed by immersion in the same fixative overnight. Immunofluorescence was performed on 4 μm cryostat sections. An affinity-purified chicken polyclonal antibody against the E subunit of the V-ATPase was used. This antibody has been characterized previously (17, 18). To localize sAC, two antibodies were used. An affinity-purified polyclonal rabbit antiserum described previously (1) and monoclonal antibody R21 (6), both against the catalytic regions (C1 and C2) of sAC.

In Vivo Perfusion of the Distal Cauda Epididymidis

Adult male Sprague-Dawley rats were anesthetized with sodium pentobarbital as described above. The vas deferens was cannulated through the lumen with a micro cannula (0.4 mm OD, 0.2 mm ID; Kent Scientific Coorporation, Torrington, CT) connected to a 10-ml syringe. A small incision was made in the distal cauda epididymal region to allow the perfusate to exit the tubule. Perfusion was performed retrogradely at a rate of 45 μl/min using a syringe pump (Model 341B, Fisher). The lumen was initially washed free of sperm with PBS (10 mM sodium phosphate, 2 mM potassium phosphate, 137 mM NaCl, 2.7 mM KCl) adjusted to different pH values (6.5, 6.8, 7.1, or 7.8), as indicated under “Results.” Horseradish peroxidase (HRP, Sigma) was added to the perfusate at a concentration of 5 mg/ml to detect endocytosis in the absence or presence of inhibitors and/or cpt-cAMP as indicated under “Results.” At the end of the experimental period, the luminal solution was changed for HRP-free ice-cold PBS for 3 min (in the continued presence of agonists or inhibitors, if applicable) to wash the lumen free of HRP. The vas deferens and cauda epididymidis were harvested and fixed by immersion in a solution containing 4% paraformaldehyde, 10 mM sodium periodate, 75 mM lysine, and 5% sucrose (PLP) for 5 h at room temperature, or overnight at 4 °C (11, 12). Tissues were then washed in PBS, pH 7.4, and stored in PBS containing 0.02% sodium azide. At least three vas deferens and cauda epididymidis were perfused for each condition described. A minimum of 10 cells per tissue were examined by confocal microscopy for a total of at least 30 cells per condition.

Immunogold Electron Microscopy

Small pieces of PLP-fixed epididymis were post-fixed by immersion in phosphate buffer containing 4% paraformaldehyde and 0.05% glutaraldehyde for 4 h at room temperature. For V-ATPase immunogold staining, pieces of tissues were embedded at low temperature with HM20 resin as described previously (10). Double labeling for V-ATPase and HRP was performed on LR White Resin embedded sections.

Quantification of Gold Particle Labeling

The relative amount of V-ATPase present in the apical microvilli of clear cells was determined from the number of V-ATPase-associated gold particles per unit length of apical membrane. Gold particles present in the apical membrane including microvilli were counted for each cell, and the number was divided by the total length of apical membrane and microvilli for that cell. Using a Wacom graphics tablet and NIH Image software, at least ten cells were analyzed in each group. Data are presented as mean ± S.E.

Cyclase Assay

Cyclase assays were performed in 100 μl reaction volume with 100 ng of His6-tagged rat sACt purified over a nickel-nitrilotriacetic acid affinity column as described (1) in the presence of 50 mM Tris-HCl buffer, pH 7.5, 20 mM creatinephosphate, 100 units/ml creatine phosphokinase, 1 mM cAMP, 2.5 mM ATP, 5 mM MgCl2, and 50 mM NaHCO3 for 30 min at 30 °C. Estrogen compounds were purchased from Steraloids, Inc. (Newport, RI).

RESULTS

sAC Expression and Localization in the Epididymis and Kidney

Epididymal epithelial cells were harvested by laser capture microdissection, and mRNA was amplified in vitro. RT-PCR detected sAC mRNA, and the presence of other clear cell markers confirmed the validity of this preparation (Fig. 1A). Western blot analysis using a specific monoclonal antibody, R21, against the N-terminal portion of sAC (6) detected a major band at around 48 kDa, the predicted molecular mass of the sACt splice variant (2, 19), in the cauda epididymidis (Fig. 1B). sAC was localized by immunofluorescence using two different anti-sAC antibodies. Monoclonal antibody R21 gave a strong staining in clear cells, which were identified by their positive staining for the V-ATPase (Fig. 1C). No specific immunoreactivity was detected in adjacent principal cells, but surrounding muscle tissue and, as previously described (1, 7), spermatozoa were positive. The same pattern of staining was obtained using an affinity-purified anti-sAC rabbit polyclonal antiserum, but no staining was detected using control pre-immune serum (data not shown). sAC is also expressed in the kidney, where it is located in epithelial cells of distal tubules (Fig. 2A), thick ascending limb of Henle (Fig. 2, A and B) and collecting ducts (Fig. 2, B and C), consistent with previous results showing bicarbonate-stimulated adenylyl cyclase activity in rat kidney (20). Proton secretion is a common function of epididymal clear cells and of renal distal tubules, thick ascending limb of Henle, and collecting duct intercalated cells. Thus, sAC is highly expressed in specialized proton-secreting cells of epididymal and renal epithelia, where it might play a role in regulating acid/ base transport in these tissues. To test for a potential role of sAC in modulating proton secretion, we used the epididymis as a model system.

Fig. 1
sAC detection and localization in the epididymis
Fig. 2
sAC localization in the kidney

V-ATPase Recycling Is Modulated by Luminal pH

Cauda epididymidis was perfused in vivo through the lumen with HRP, a marker of endocytosis, in PBS adjusted to different pH values. Double immunofluorescence labeling for HRP and V-ATPase was performed on PLP-fixed cryostat sections. At the physiological luminal pH of 6.8, clear cells, identified by their positive immunoreactivity for V-ATPase, show a high endocytic activity compared with adjacent principal cells (Fig. 3, A and B, arrows). Electron microscopy double immunogold labeling for HRP and V-ATPase showed that a sub-population of HRP-containing endosomes clearly contain V-ATPase, indicating that the proton pump is actively recycled at physiological luminal pH (Fig. 3C). The effect of luminal pH variations on V-ATPase recycling was examined using confocal microscopy. At the acidic pH of 6.5, V-ATPase is distributed between the apical microvilli and intracellular sub-apical vesicles (Fig. 4, A, A′, and A″). Double labeling for HRP indicated that the V-ATPase-containing vesicles partially co-localize with HRP-containing endosomes (yellow staining), indicating that a significant amount of V-ATPase is located in the endocytic compartment. In contrast, at the alkaline luminal pH of 7.8, V-ATPase is mainly located in apical microvilli (Fig. 4, B, B′, and B″, green) and not in sub-apical HRP-containing endosomes (red staining). Almost no co-localization of V-ATPase and HRP is observed, indicating a very low rate of V-ATPase internalization. In addition, clear cells exposed to luminal pH 7.8 exhibit more developed V-ATPase-positive microvilli compared with cells exposed to pH 6.5. The lack of co-localization of V-ATPase with HRP-labeled endosomes and the increased length of V-ATPase positive microvilli indicate that translocation of V-ATPase from sub-apical vesicles to the apical membrane occurs at alkaline luminal pH. These results were confirmed by immunogold electron microscopy showing intracellular vesicle localization of V-ATPase at luminal pH 6.5 (Fig. 4C), and its predominant localization in extensive apical microvilli at pH 7.8 (Fig. 4D). Quantification of the number of V-ATPase-associated gold particles showed a significant increase in the apical membrane density of V-ATPase molecules at alkaline pH compared with acidic pH (Fig. 4E; p < 0.05). Thus, apical V-ATPase amplification occurs via both microvilli extension and an increase in V-ATPase density in the membrane. These results show that clear cells respond to variations in luminal pH by inducing a rapid (within 15 min), pH-dependent shuttling of V-ATPase between the intracellular HRP-positive endocytic compartment and apical microvilli. This alkaline-induced apical membrane V-ATPase accumulation is a potential mechanism to restore luminal pH to its physiological acidic value.

Fig. 3
V-ATPase recycling at physiological luminal pH
Fig. 4
Effect of luminal pH on V-ATPase recycling

cAMP Induces the Apical Translocation of V-ATPase

Previous studies have shown that cAMP stimulates proton secretion in a variety of acidifying epithelial cells (2123) and induces the exocytic insertion of many actively recycling membrane proteins, including AQP2, CFTR, and GLUT4 (2426). To determine whether the pH-related translocation of V-ATPase was modulated by cAMP, cauda epididymidis were perfused at luminal pH of 6.5 with PBS containing the cAMP permeant analogue, 8-(4-chorophenylthio)-cAMP, (cpt-cAMP, 1 mM; Sigma) for 15 min. Under these conditions, V-ATPase was present in the apical microvilli and no co-localization of V-ATPase and HRP was observed, indicating that cAMP induced a translocation of V-ATPase from intracellular vesicles to the apical membrane, even at acidic luminal pH (Fig. 5A).

Fig. 5
Role of cAMP, intracellular HCO3 and sAC in V-ATPase recycling

Intracellular Bicarbonate Is Essential for the Alkaline pH-induced V-ATPase Translocation

Because sAC is directly activated by bicarbonate ions, we examined the potential contribution of intracellular HCO3 in the pH- and cAMP-dependent V-ATPase recycling. CO2/HCO3 is the main buffer in biological systems, and the equilibrium between HCO3 and H with CO2 and H2O is catalyzed by carbonic anhydrases. Clear cells express very high levels of the cytosolic carbonic anhydrase type II (11, 27), and we have shown that the carbonic anhydrase inhibitor, acetazolamide, markedly decreases the rate of proton secretion in isolated vas deferens (11). We, therefore, hypothesized that intracellular bicarbonate production via carbonic anhydrase type II in response to an alkaline luminal pH (and subsequent increase in intracellular pH) could activate sAC. Elevation of cAMP in response to sAC stimulation would then induce an accumulation of V-ATPase in the apical membrane. Cauda epididymidis were perfused in vivo with PBS at pH 7.8, in the presence of acetazolamide (100 μM; Sigma) for 15 min, to inhibit intracellular bicarbonate production via carbonic anhydrase type II. Under these conditions, clear cells showed an almost complete absence of apical microvilli, and V-ATPase was present in the cytoplasmic and sub-apical regions (Fig. 5B). It, therefore, appears that bicarbonate production via carbonic anhydrase is an essential step in the translocation of the V-ATPase from intracellular vesicles into the apical membrane at alkaline luminal pH. Addition of cpt-cAMP (1 mM) to the luminal perfusate for 10 min at the end of the acetazolamide treatment, but in the continued presence of acetazolamide, induced a reappearance of V-ATPase in apical microvilli (Fig. 5C). Because almost all V-ATPase molecules had been internalized at the end of the acetazolamide treatment (Fig. 5B), the apical V-ATPase localization observed upon subsequent addition of cAMP clearly demonstrates that cAMP induced exocytosis of the pump.

sAC Is Involved in the pH-regulated V-ATPase Recycling

To determine whether sAC was involved in this intracellular bicarbonate- and cAMP-dependent response, we examined the effect of luminal alkaline pH on V-ATPase distribution after inhibition of sAC. Catechol derivatives of estrogen, but not the parent estrogen compounds, were thought to inhibit soluble adenylyl cyclase activity from testis (28), and we confirmed these observations using recombinant purified rat sAC protein (Fig. 6). Rat sAC activity was inhibited by 1,3,5(10)-estratrien-2,3,17β-diol (2-hydroxyestradiol; 2-OH estradiol) with an IC50 of 10 μM, and inhibition was non-competitive with substrate ATP. The parent compound 1,3,5(10)-estratrien-3,17β-diol (estradiol) was essentially inert up to 100 μM. Cauda epididymidis were perfused at pH 7.8 in the presence of the sAC inhibitor, 2-hydroxyestradiol (20 μM) for a period of 20 min. Under these conditions, V-ATPase was distributed between apical microvilli and sub-apical vesicles (Fig. 5D) in a manner similar to that observed at pH 6.5 (compare with Fig. 4A). A significant amount of V-ATPase co-localized with HRP-containing endosomes (Fig. 5D, yellow), indicating that inhibition of sAC prevents the usual alkaline pH-induced response (compare with Fig. 4B). Addition of cpt-cAMP for 10 min at the end of the 2-hydroxyestradiol period and in the continued presence of 2-hydroxyestradiol induced a redistribution of V-ATPase into apical microvilli (Fig. 5E), demonstrating that clear cells had retained their ability to respond to cAMP despite the presence of catechol estrogens. Negative controls were conducted by using estradiol (20 μM), which does not inhibit sAC. Under these conditions, clear cells underwent the same V-ATPase translocation to the apical membrane (Fig. 5F) as that observed normally at pH 7.8 or in the presence of cpt-cAMP. In addition, no effect of estradiol was observed on V-ATPase localization at luminal pH 6.5 (data not shown), demonstrating that estradiol is not an activator of V-ATPase exocytosis. These results demonstrate that blockage of V-ATPase apical translocation by catechol estrogens was specifically attributed to inhibition of sAC.

Fig. 6
Direct inhibition of purified rsACt by 2-hydroxyestradiol

Luminal Bicarbonate Induces the Apical Translocation of V-ATPase

Finally, we examined whether clear cells had the ability to respond to variations in luminal bicarbonate in addition to variations in pH. The effect of an increase in luminal bicarbonate at constant pH on V-ATPase localization and recycling was examined. Cauda epididymidis were perfused with either PBS adjusted to pH 7.1 or a solution containing 12 mM bicarbonate and equilibrated with 5% CO2 (pH 7.1). Clear cells exposed to luminal bicarbonate exhibited more developed V-ATPase-positive apical microvilli, indicating higher apical membrane translocation of the pump, compared with clear cells exposed to the same pH in absence of bicarbonate (compare Fig. 7A and B). The sAC inhibitor 2-hydroxyestradiol prevented the bicarbonate-induced V-ATPase apical translocation (Fig. 7C). Quantification of the area occupied by the V-ATPase-labeled microvilli, normalized for the width of the cells at the apical membrane border, indicated a significant increase in apical microvilli extension in the presence of bicarbonate (Fig. 7E and G) compared with the absence of bicarbonate (Fig. 7D and G), and confirmed that sAC inhibition prevented the bicarbonate-mediated V-ATPase microvilli translocation (Fig. 7F and G).

Fig. 7
Effect of luminal bicarbonate concentration on sAC-mediated V-ATPase recycling

DISCUSSION

The present data show that the distribution of the V-ATPase in specialized proton-secreting cells of the epididymis, the so-called clear cells, is closely related to luminal pH. At alkaline luminal pH, the V-ATPase is mainly located in well developed apical microvilli, and at acidic pH, it is actively recycling between sub-apical endosomes and the apical membrane. We showed that intracellular production of bicarbonate is essential for the alkaline pH-induced response and that cAMP induces an apical translocation of V-ATPase identical to that induced by alkaline pH. Catechol estrogens, which are inhibitors of the newly identified soluble adenylyl cyclase, sAC, inhibit the alkaline-dependent V-ATPase redistribution, identifying sAC as the sensor responsible for the pH-dependent V-ATPase recycling. We propose that alkalinization of luminal pH, followed by an increase in intracellular pH in clear cells, leads to an elevation of intracellular bicarbonate concentration. Bicarbonate elevation activates sAC and triggers cAMP production, which in turn leads to the accumulation of V-ATPase in apical microvilli. The exact mechanism(s) responsible for the cAMP-induced apical translocation of V-ATPase remain unknown, and further studies will be required to identify the downstream target proteins involved in this process. Clear cells have also the ability to respond to an increase in luminal bicarbonate concentration at constant pH, presumably due to entry of bicarbonate across the apical membrane, and subsequent elevation in intracellular bicarbonate concentration followed by sAC activation. A potential candidate for the apical entry of bicarbonate might be NBC3, which is expressed in the apical membrane of clear cells (29).

Previous studies have demonstrated that primary cultures of epididymal principal cells respond to a variety of agonists by secreting bicarbonate into the lumen (3032). It was then proposed that bicarbonate secretion occurs during sexual arousal to “prime” spermatozoa before ejaculation (32). Although this finding was interesting, early micropuncture measurements had demonstrated that the luminal fluid of the epididymis is acidic and contains a low bicarbonate concentration (8, 33), indicating the presence of acidification mechanisms in this tissue. We have shown that clear cells, which express high levels of the V-ATPase in their apical pole, are key players in luminal acidification (9, 10) and that proton secretion by these cells is abolished upon inhibition of intracellular bicarbonate production by acetazolamide (11). Thus, the marked intracellular redistribution of V-ATPase observed in the present study in the presence of acetazolamide is in agreement with our previous results showing inhibition of proton secretion under these conditions. We propose that clear cells respond to a rise in luminal bicarbonate concentration following agonist-induced principal cell bicarbonate secretion, by increasing their rate of proton secretion. This would re-establish the pH of the lumen to its resting acidic value. The enrichment of sAC in clear cells compared with principal cells provides an exquisite mechanism for such a concerted interaction between principal and clear cells.

The present study also shows high expression of sAC in kidney thick ascending limbs, distal tubules, and collecting ducts. All epithelial cells from the thick ascending limbs and distal tubules, and intercalated cells from the collecting duct also express the V-ATPase (34). The presence of sAC in these segments, as well as the previously reported sAC expression in other acid/base transporting systems including the choroid plexus (1), indicate that the sAC-dependent cAMP signaling pathway may represent a general mechanism allowing these cells to regulate their rate of proton secretion.

This study is the first demonstration of the role of sAC in mediating V-ATPase-recycling in a native epithelium and provides the missing link between extracellular pH (or bicarbonate) signaling and intracellular response. Because sAC is expressed in many biological systems involved in acid/base transport, we propose that this bicarbonate-dependent cAMP pathway may represent a more universal mechanism allowing cells to sense and modulate the pH of their environment. The molecular entities underlying the response of cells to variations in the pH of their immediate environment still remain unknown. Our study unravels key components of a potentially widespread signaling pathway that could be applicable to many biological systems.

Acknowledgments

We thank the excellent technical assistance of Mary McKee.

Footnotes

*This study was supported by National Institutes of Health Grants HD40793 (to S. B.), DK38452 (to D. B. and S. B.), DK42956 (to D. B.), HD38722 (to L. R. L.), and GM62328 and HD42060 (to J. B.) and by NIH NRSA HD08684 (to N. P.-S.). The Microscopy Core Facility of the MGH Program in Membrane Biology is additionally supported by a Center for the Study of Inflammatory Bowel Disease (CSIBD) Center Grant DK43351 and Boston Area Diabetes and Endocrinology Research Center (BADERC) Award DK57521.

1The abbreviations used are: sAC, bicarbonate-activated soluble adenylyl cyclase; RT, reverse transcriptase; PBS, phosphate-buffered saline; HRP, horseradish peroxidase.

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