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

Department of Physiology and Biophysics, University of Colorado Health Sciences Center, Aurora, Colorado

Submitted 29 October 2004 ; accepted in final form 31 August 2005

	ABSTRACT

TOP ABSTRACT EXPERIMENTAL PROCEDURES RESULTS DISCUSSION GRANTS REFERENCES

 
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 PKC, GÖ-6976, significantly reduced PMA inhibition. PMA did not alter surface expression of the cotransporters, but it significantly increased hkNBCe1-PKC 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 PKC translocation inhibitor V1–2 peptide as well as BAPTA-AM (but not GÖ-6976), significantly reduced ANG II inhibition. At 10^–6 M, ANG II significantly decreased surface expression of the cotransporters and increased hkNBCe1-PKC 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 PKC 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 PKC 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.

PKC; MAPK; intracellular calcium; fluo 4; endocytosis

PMA, a potent PKC activator (4), has been reported to stimulate bicarbonate absorption by acting on the Na/HCO₃^– transporter in the renal PT (34, 39, 40). PMA has been found to stimulate or inhibit bicarbonate absorption, depending on exposure time (38). Another PKC inducer is the peptide hormone ANG II, which may be derived from the general circulation or synthesized in the kidneys. The Na⁺-HCO₃^– cotransporter is inhibited by high doses but stimulated by low doses of ANG II in the renal PT (8, 12, 15, 17, 33). It has been reported that PKC is involved in the ANG II-induced regulation of bicarbonate reabsorption in the renal PT (5, 11, 37). PMA and ANG II each induce a distinct pattern of activated PKC isoforms (3, 20, 26), which may have differential roles in the regulation of NBC1. However, the PKC isoforms involved in the PMA- or ANG II-induced regulation of NBC1 are not yet known.

We therefore sought to elucidate the role of PKC and some of its isoforms, as well as the role of intracellular Ca²⁺, in the PMA- and ANG II-induced regulation of human kidney NBC1 (hkNBCe1) encoded by the SLC4A4 gene expressed in Xenopus laevis oocytes.

	EXPERIMENTAL PROCEDURES

TOP ABSTRACT EXPERIMENTAL PROCEDURES RESULTS DISCUSSION GRANTS REFERENCES

 
Materials. PMA, 4-phorbol 12,13-didecanoate (4PDD), GF-109203X, GÖ-6976, the PKC translocation inhibitor V1–2 peptide EAVSLKPT, the PKC translocation inhibitor V1–2-s peptide negative control LSETKPAV, and PD-98059 were purchased from Calbiochem (San Diego, CA). [Asn¹,Val⁵]-ANG II acetate salt was purchased from Sigma (St. Louis, MO). BAPTA-AM, fluo- 4 pentapotassium salt, and ionomycin were purchased from Molecular Probes (Eugene, OR). Monoclonal anti-PKC (Anti-PKC, clone M4) was purchased from Upstate USA (Chicago, IL). Monoclonal anti-PKC mouse IgG2a (A-3), polyclonal anti-PKC (H-300) and anti-PKC (sc-213) rabbit antibodies, and Protein Plus A/G Agarose beads were purchased from Santa Cruz Biotechnology (Santa Cruz, CA). Living Colors full-length polyclonal GFP antibody was purchased from BD Biosciences/Clontech (Palo Alto, CA), and monoclonal anti-GFP antibody was purchased from Zymed Laboratories (South San Francisco, CA). Leibovitz's L-15 Medium and penicillin-streptomycin were purchased from Invitrogen (Carlsbad, CA). EZ-Link Sulfo-NHS-Biotin and immobilized neutravidin biotin binding protein were purchased from Pierce Biotechnology (Rockford, IL). All other chemicals were purchased from Sigma.

Preparation of oocytes. Female X. laevis frogs (NASCO) were anesthetized with 1.5 mg/ml tricaine. The ovarian lobes were surgically removed, dissected, and then treated with 2 mg/ml collagenase type IA in Ca²⁺-free ND96-HEPES solution. Oocytes were incubated at 18°C in OR3 medium, a 1:2 dilution in dH₂O of Leibovitz's L-15 Medium, supplemented with 50 U/ml of penicillin-streptomycin, 10 mM of HEPES, and titrated to pH 7.5.

Expression in X. laevis oocytes. The cDNAs encoding human hkNBCe1 and rat AT_1B (the kind gift from Dr. L. Pulakat, Bowling Green State University, Bowling Green, OH) were each subcloned into the pGH19 expression vector. A chimera of the EGFP-tagged hkNBCe1 cDNA was subcloned into pGH19 (the kind gift from Dr. L. V. Virkki, Institute of Physiology, University of Zurich, Zurich, Switzerland). DNAs were transcribed in vitro using an mMessageMachine kit (Ambion, Austin, TX) to generate synthesized capped mRNAs. Oocytes were injected with 50 nl of 0.5 ng/nl hkNBCe1 mRNA; 25 nl of 1 ng/nl hkNBCe1 mRNA plus 25 nl 1 ng/nl AT_1B mRNA; or 50 nl of dH₂O.

Solutions. Nominally bicarbonate-free ND96-HEPES solution contained 96 mM NaCl, 2 mM KCl, 1 mM MgCl₂, 1.8 mM CaCl₂, and 5 mM HEPES, pH 7.50. Bicarbonate-containing solutions were prepared by replacing 33 mM NaCl with 33 mM NaHCO₃ and equilibrating with 5% CO₂-balanced oxygen. Ca-free ND96-HEPES and bicarbonate-containing solutions were prepared by adding 0.5 mM EGTA. The osmolality of all solutions was 200 mosmol/kgH₂O.

Drug treatments. PMA, 4PDD, GF-109203X (GF), GÖ-6976 (GÖ), PD-98059 (PD), and BAPTA-AM were made as 1,000x stock solutions in DMSO and diluted with ND96-HEPES solution to the final concentrations before use. As a control, we used 0.1% DMSO. ANG II was made as a 10^–3 M stock in sterile dH₂O and diluted with ND96-HEPES solution to the final concentrations before use. Where indicated, 8 ng PKC translocation V1–2 inhibitor and negative control V1–2-s peptides, in 24 nl, were each injected into oocytes before the experiments.

Two-electrode oocyte voltage clamp. Oocytes were voltage-clamped at room temperature using a two-electrode oocyte clamp (Warner Instrument, New Haven, CT) and microelectrodes made by pulling borosilicate glass capillary tubing (Warner Instruments) on a microelectrode puller. The cells were impaled with microelectrodes filled with 3 M KCl (resistance = 0.3–1.0 M). The holding potential (V_h) was –50 mV. The currents were filtered at 20 Hz (four-pole Bessel filter) and digitized. An oocyte was placed in a chamber for constant superfusion with a 4-ml/min solution flow. Bath solutions were delivered with syringe pumps (Harvard Apparatus, South Natick, MA), and solutions were switched with pneumatically operated valves (Clippard Instrument Laboratory, Cincinnati, OH).

Biotinylation of surface proteins. Oocytes injected with hkNBCe1-EGFP mRNA or dH₂O were incubated in the presence or absence of 10 nM PMA for 10 min, and oocytes coinjected with hkNBCe1-EGFP and AT_1B mRNAs or dH₂O were incubated for 20 min in the presence or absence of 10^–6 M ANG II. Next, oocytes were incubated in the presence or absence of EZ-Link Sulfo-NHS-Biotin for 1 h at 4°C, and the biotinylated proteins were recovered from the membrane fractions with immobilized neutravidin biotin binding protein by precipitation overnight at 4°C. Proteins were boiled in Laemmli sample buffer and subjected to SDS-PAGE (25) and hkNBCe1-EGFP bands were detected by Western analysis with monoclonal anti-GFP antibodies using KODAK Image Station 440CF. The intensity of the hkNBCe1 bands was measured using ImageJ software (http://rsb.info.nih.gov/ij/).

Measurement of intracellular Ca. The Ca²⁺-sensitive fluorescent dye fluo 4 pentapotassium salt dissolved in 140 mM KCl, 1 mM MgCl₂, and 5 mM HEPES was injected into oocytes (27). Only the results obtained with oocytes that maintained a constant basal fluorescence before each experiment and that responded to ionomycin, added at the end of the experiment, were considered. Confocal images were taken at 20-s intervals for at least 20 min. At the beginning of each experiment, the oocytes were repetitively scanned and the integrated values of fluorescence were plotted as a function scan number. Laser power and gain were adjusted to lose not more than 0.1% fluorescence per scan to obtain constant signals throughout the whole experiment.

Confocal microscopy. Changes in the fluorescence of hkNBCe1-EGFP or in the fluorescence of Ca-sensitive dye fluo 4 in response to PMA or ANG II were measured in a confocal XY section of the near-plasma membrane region by excitation at 488 nm and emission at 510 nm (EGFP) or 525 nm (fluo 4) using a LSM510 microscope (Carl Zeiss Laser Scanning System, available at Light Microscopy Facility at UCHSC, see http://www.uchsc.edu/lightmicroscopy/) with a x25 NA 0.8-mm water-immersion objective and argon laser for excitation.

Coimmunoprecipitation. Oocytes treated for 10 min with 10 nM PMA or for 20 min with 10^–6 M ANG II were collected and homogenized in ice-cold Tris buffer (10 mM Tris·HCl, pH 7.5, 100 mM NaCl, 40 mM -glycero-phosphate, 10 mM Na pyrophosphate, 1.5 mM EDTA, 1 mM EGTA, 1 mM Na₃VO₄, 50 mM NaF, 10 µg/ml leupeptin, 10 µg/ml aprotinin, 200 µM PMSF). Membrane fractions were isolated by centrifugation at 15,000 g, and the pellets containing the membrane fraction were dissolved in ice-cold RIPA buffer (10 mM Tris·HCl, pH 7.5, 100 mM NaCl, 1 mM DTT, 0.5% Na deoxycholate, 0.1% SDS, 1% NP-40, 10 µg/ml leupeptin, 10 µg/ml aprotinin, 200 µM PMSF). The membranes were incubated overnight at 4°C with protein A/G PLUS-agarose beads and polyclonal rabbit anti-GFP antibodies, or with the beads in the absence of antibody. The beads were washed in high-salt RIPA buffer (RIPA buffer containing 200 mM NaCl). Proteins were boiled in Laemmli sample buffer and subjected to SDS-PAGE (25) and Western blot analysis using KODAK Image Station 440CF.

Our animal protocol was approved by the Institutional Animal Care and Use Committee at the University of Colorado Health Sciences Center [animal protocol #65105103(01)2A].

Data acquisition. NBC current (I_NBC) data were recorded digitally on a personal computer using an analog-to-digital converter (ADC-30, CONTEC Microelectronics, San Jose, CA) and sampling at a rate of 1 Hz.

Statistics and data analysis. All averages are reported as means ± SD, along with the number of observations (n). For ratios, averages are presented as log-normal means. The statistical significance of log-normal data was determined using an unpaired Student's t-test (21). Differences were considered significant at a level of P < 0.05.

	RESULTS

TOP ABSTRACT EXPERIMENTAL PROCEDURES RESULTS DISCUSSION GRANTS REFERENCES

 
Functional characterization of PMA inhibition of hkNBCe1 expressed in X. laevis oocytes. To determine the effects of PMA on hkNBCe1 function, we injected a synthesized mRNA encoding hkNBCe1-EGFP into oocytes and 3 days later performed electrophysiological experiments using a two-electrode oocyte voltage clamp. The EGFP tag did not appear to alter the function of hkNBCe1 and action of PMA, because voltage-clamp currents recorded from hkNBCe1-EGFP and wild-type hkNBCe1 were similar (data not shown). In bicarbonate-buffered solution, each molecule of activated electrogenic hkNBCe1 works to pump two HCO₃^– and one Na⁺ into the cell, thus translocating a net negative charge. This is reflected as a transient outward current in response to the depolarizing step from –50 to 0 mV in voltage-clamped oocytes expressing hkNBCe1.

Using oocytes constantly superfused with bicarbonate-buffered solution, a 10-min voltage clamp to –50 mV V_h was applied. When we recorded I_NBC in response to a 60-s depolarization, from –50 to 0 mV, we observed an immediate and large (peak 2 µA) transient outward "control" current (dashed traces marked with arrows in Fig. 1A). After 10-min treatment with 10 nM PMA with or without inhibitors or BAPTA-AM pretreatment, we recorded a "test" current in response to another depolarization (solid traces in Fig. 1A). We computed a "remaining" (normalized) current by dividing I_t (test current after treatment) by I_c (control current before treatment) (Fig. 1B).

View larger version (29K): [in this window] [in a new window]   Fig. 1. PMA inhibits hkNBCe1 via the PKC signaling pathway. A: voltage-clamp currents obtained from hkNBCe1-expressing oocytes treated with PMA (10 nM for 10 min; A), the inactive PMA analog 4PDD (400 nM for 10 min; B), the PKC inhibitor GF-109203X (GF; 100 nM; C) plus 10 nM PMA for 10 min, the specific inhibitor of Ca-dependent conventional PKC isoforms GÖ-6976 (GÖ; 200 nM for 25 min; D) followed by 10 nM PMA for 10 min, the chelator of intracellular Ca2+ BAPTA-AM (50 µM for 30 min; E) followed by 10 nM PMA for 10 min, BAPTA-AM (50 µM for 30 min; F) followed by 100 nM GF plus 10 nM PMA for 10 min, or BAPTA-AM (50 µM for 30 min; G) followed by GÖ (200 nM for 25 min) followed by 10 nM PMA for 10 min. Oocytes were superfused with 5% CO2/33 mM HCO3 solution, voltage-clamped to –50 mV for 10 min, and depolarized from –50 to 0 mV before treatment (dashed lines, arrows). Following treatment and depolarization, test currents were recorded (solid lines). A small background current of 25 nA was recorded in HCO3–-free solution, in the presence of the NBC1 inhibitor DIDS (200 nM), or in water-injected oocytes (data not shown). B: bars representing means ± SD of relative NBC peak currents acquired as the ratio of test to control peak currents (It/Ic) in n experiments. A-G as above. *P < 0.005 by Student's t-test.

To identify the PKC isoforms involved in PMA inhibition of hkNBCe1, we preincubated the cells for 25 min with 200 nM GÖ, a specific inhibitor of Ca-dependent conventional PKC, which significantly reduced PMA inhibition of NBC current (Fig. 1A, D; bar graph D in Fig. 1B), with the remaining current being 81.0 ± 7.2% (n = 6) of the controls. These findings clearly demonstrate that PMA-induced Ca-dependent conventional PKC isoforms are involved in hkNBCe1 inhibition in X. laevis oocytes.

To examine the role of Ca²⁺ in PMA inhibition of NBC current, we chelated intracellular Ca²⁺ by incubating oocytes for 30 min in 50 µM cell-permeable BAPTA-AM. This chelation reduced PMA inhibition of NBC current (Fig. 1A, E; bar graph E in Fig. 1B), with the remaining current being 74.1 ± 5.4% (n = 9) of the controls. Next, we applied 100 nM GF together with 10 nM PMA to the BAPTA-AM-pretreated oocytes. Ca²⁺ chelation did not alter GF-induced reduction of PMA inhibition of NBC (Fig. 1A, F; bar graph F in Fig. 1B), with the remaining current being 83.0 ± 12.2% (n = 6) of controls, indicating that there is no summation of GF and BAPTA effects. Similarly, a separate set of experiments indicated that there is no summation of GÖ and BAPTA effects in the presence of PMA, with the remaining current being 74.6 ± 4.1% (n = 5) of the controls (Fig. 1A, G; bar graph G in Fig. 1B). We also monitored intracellular Ca²⁺ in fluo 4-injected oocytes expressing hkNBCe1; 10 nM PMA does not increase fluorescence intensity of fluo 4-loaded oocytes (see Fig. 7A), indicating stable cytosolic Ca²⁺ concentration during PMA application. These findings clearly demonstrate that Ca²⁺ signaling is not involved in PMA inhibition of hkNBCe1 expressed in X. laevis oocytes.

View larger version (84K): [in this window] [in a new window]   Fig. 7. Ca2+ signaling in fluo 4-loaded oocytes. A: PMA does not increase cytosolic Ca2+ in oocytes expressing hkNBCe1. Serial confocal microscope images show similar fluorescence of Ca-sensitive fluo 4 dye in the same oocyte before and 40, 300, 600, and 900 s after 10 nM PMA. The fluorescence intensity in the ROI (inside the white dotted area) after PMA was 97.4 ± 2.4% (n = 4) of that before. B: ANG II increases cytosolic Ca2+ in oocytes coexpressing hkNBCe1 with AT1B. Serial confocal images show significant increase in fluorescence 40, 80, 180, 240, and 300 s after 10–6 M ANG II. The fluorescence intensity in the ROI 80–120 s after ANG II was 373.5 ± 4.23% (n = 3) of that before. The fluorescence intensity in the ROI 12–20 min (images not shown) after ANG II was 179.0 ± 1.5% (n = 3) of that before. C: 50 µM BAPTA-AM blocks ANG II increase in cytosolic Ca2+ in oocytes coexpressing hkNBCe1 with AT1B. Serial confocal images show similar fluorescence before BAPTA, 30 min after BAPTA and before ANG II, and 40, 80, 240, and 300 s after ANG II. In images taken of Ca-chelated oocytes after treatment with 10–6 M ANG II, the fluorescence intensity in the ROI was 97.0 ± 2.7% (n = 3) of that before. A, B, and C: oocyte diameter within shown focal plane is 465–580 µm, and depth of focus is 8–10 µm. D: changes in normalized fluorescence (F/F0) of Ca-sensitive fluo 4 taken every 20 s. : 10 nM PMA (shown in A); : 10–6 M ANG II (shown in B); : BAPTA with 10–6 M ANG II (shown in C). We also measured cytosolic Ca2+ in 10–10 M ANG II-treated oocytes coexpressing hkNBCe1 and AT1B (images are not shown); : 10–10 M ANG II; and : BAPTA with 10–10 M ANG II.

View larger version (34K): [in this window] [in a new window]   Fig. 2. High-concentration ANG II inhibition of hkNBCe1 is mediated by PKC-, Ca2+ and not by PKC. A: voltage-clamp currents obtained from oocytes expressing hkNBCe1 alone (A) and oocytes coexpressing hkNBCe1 and AT1B (B through H) treated with ANG II (10–6 M for 20 min; A and B), the PKC inhibitor GF (100 nM; C) plus 10–6 M ANG II for 20 min, the specific inhibitor of Ca-dependent PKC isoforms GÖ (200 nM for 25 min; D) followed by 200 nM GÖ plus 10–6 M ANG II for 20 min, the PKC translocation inhibitor peptide EAVSLKPT (8 ng in 24 nl injected into oocytes 1 h before the experiment; E) plus 10–6 M ANG II for 20 min, the negative control for the PKC translocation inhibitor peptide, LSETKPAV (8 ng in 24 nl injected into oocytes 1 h before the experiment; F) plus 10–6 M ANG II for 20 min, the chelator of intracellular Ca2+ BAPTA-AM (50 µM for 30 min; G) followed by 10–6 M ANG II for 20 min, or the specific inhibitor of the MAPK pathway PD-98059 (PD; 50 µM for 50 min; H) plus 10–6 M ANG II for 20 min. The protocol was identical to that in Fig. 1A. B: bars representing the means ± SD of relative NBC peak currents acquired as the ratio of test to control peak currents (It/Ic) in 6 experiments (11 experiments in bar B). A-H identical to those above. *P < 0.005 by Student's t-test.

We monitored intracellular Ca²⁺ in fluo 4-loaded oocytes coexpressing hkNBCe1 and AT_1B. We detected a large transient increase (peaking at a 3.8-fold increase of normalized fluorescence within first 1–3 min) followed by a sustained elevation of intracellular Ca²⁺ (1.8-fold of normalized fluorescence, within last 10–25 min) in oocytes treated with 10^–6 M ANG II, but not in oocytes preincubated for 30 min with 50 µM BAPTA-AM (see Fig. 7, B, C, and D). Next, voltage-clamped oocytes were incubated for 30 min with 50 µM BAPTA-AM, which significantly reduced inhibition of NBC current induced by 10^–6 M ANG II (Fig. 2A, G) to 88.1 ± 6.2% (n = 8) of control (bar graph G in Fig. 2B). These results suggest that intracellular Ca²⁺ is involved in high-concentration ANG II inhibition of NBC current.

AT₁ stimulation has been reported to activate the MAPK cascades (35). To determine whether MAPK is involved in ANG II inhibition, we pretreated oocytes for 50 min with 50 µM PD, a selective and cell-permeable MAPK (MEK) inhibitor, followed by a 20-min treatment with 10^–6 M ANG II plus 50 µM PD (Fig. 2A, H). We found that ANG II inhibition of NBC current was significantly reduced, with the remaining NBC current being 80.5 ± 10.2% (n = 6) of control (bar graph H in Fig. 2B). This finding is in agreement with earlier reports that MAPK is involved in the ANG II regulation of endogenous Na⁺-HCO₃^– cotransporter in the heart and kidney (1, 31).

Quantitation of plasma membrane hkNBCe1 proteins in the presence of PMA. To investigate whether PMA-activated PKC inhibits NBC current by inducing removal of hkNBCe1-EGFP proteins from the plasma membrane, we performed surface biotinylation using a membrane-impermeable derivative of biotin (sulfo-NHS-biotin). The EGFP tag did not appear to alter the level of the hkNBCe1 biotinylated protein (data not shown). Western blot analysis with anti-GFP monoclonal antibodies detected biotinylated hkNBCe1-EGFP protein as a 150-kDa band on SDS-PAGE (Fig. 3A); the difference in size between this band and the 130-kDa glycosylated hkNBCe1 (7) corresponds to the 26-kDa EGFP. We found that the intensity of the hkNBCe1 band from PMA-treated oocytes (Fig. 3A, lane 4) was 103.4 ± 13.2% (n = 6) of that of untreated cells (Fig. 3A, lane 3), indicating that a 10-min treatment with 10 nM PMA does not induce removal of the hkNBCe1 from the membrane. Negative controls (Fig. 3A, lanes 1, 2, 5, and 6) showed a complete absence of biotinylated hkNBCe1.

View larger version (71K): [in this window] [in a new window]   Fig. 3. A: surface biotinylation shows that 10 nM PMA does not remove hkNBCe1 from the membrane. Oocytes injected with hkNBCe1 or dH2O were treated for 10 min in the presence or absence of 10 nM PMA and subsequently incubated in the presence or absence of EZ-Link Sulfo-NHS-Biotin for 1 h at 4°C. Biotinylated proteins were recovered from membrane fractions by immunoprecipitation overnight with NeutrAvidin-conjugated beads and resolved by SDS-PAGE, and hkNBCe1-EGFP was detected by Western analysis using anti-GFP monoclonal antibodies (1:1,000). Lane 1: dH2O-injected oocytes, –PMA, +biotin. Lane 2: dH2O-injected oocytes, +PMA, +biotin. Lane 3: hkNBCe1-EGFP-injected oocytes, –PMA, +biotin. Lane 4: hkNBCe1-EGFP-injected oocytes, +PMA, +biotin. Lane 5: hkNBCe1-EGFP-injected oocytes, –PMA, –biotin. Lane 6: hkNBCe1-EGFP-injected oocytes, +PMA, –biotin. B: surface biotinylation shows that 10–6 M ANG II partially removes hkNBCe1 from the membrane. Oocytes injected with dH2O or coinjected with hkNBCe1 and AT1B were treated for 20 min in the presence or absence of 10–6 M ANG II and subsequently incubated in the presence or absence of EZ-Link Sulfo-NHS-Biotin. Biotinylated proteins were recovered from membrane fractions and resolved by SDS-PAGE, and hkNBCe1-EGFP was detected using anti-GFP antibodies (1:1,000). Lane 1: dH2O-injected oocytes, –ANG II, +biotin. Lane 2: dH2O-injected oocytes, +ANG II, +biotin. Lane 3: oocytes coinjected with hkNBCe1-EGFP and AT1B, –ANG II, +biotin. Lane 4: oocytes coinjected with hkNBCe1-EGFP and AT1B, +ANG II, +biotin. Lane 5: oocytes coinjected with hkNBCe1-EGFP and AT1B, –ANG II, -biotin. Lane 6: oocytes coinjected with hkNBCe1-EGFP and AT1B, +ANG II, –biotin. The intensity of the hkNBCe1-EGFP band from ANG II-treated oocytes was 68.6 ± 10.0% (n = 4) of intensity of that of untreated cells.

View larger version (87K): [in this window] [in a new window]   Fig. 4. A: 10 nM PMA does not reduce fluorescence of hkNBCe1-EGFP near the plasma membrane. Confocal microscope images of oocytes expressing hkNBCe1-EGFP show similar fluorescence of hkNBCe1-EGFP in the absence of PMA treatment (a) and after treatment for 10 min with 10 nM PMA (b). The fluorescence of hkNBCe1-EGFP near the plasma membrane at a scaling factor of 0.23 µM, with 488-nm excitation and 510-nm emission, was acquired with an LSM510 microscope (Zeiss) using a plan-Neofluor, water-immersion objective x25/0.8 mm with argon laser for excitation. In PMA-treated cells, the fluorescence intensity in the region of interest (ROI, inside the white dotted area) was 97.1 ± 15.4% (n = 3) of that in untreated cells. B: ANG II at 10–6 M reduces the fluorescence of hkNBCe1-EGFP near the plasma membrane. Confocal microscope images of oocytes coexpressing hkNBCe1-EGFP and AT1B show a significant reduction in hkNBCe1-EGFP fluorescence after treatment for 20 min with 10–6 M ANG II (b) compared with untreated oocytes (a). The fluorescence of hkNBCe1-EGFP near the plasma membrane at a scaling factor of 0.53 µM was acquired as above. In ANG II-treated cells, the fluorescence intensity in the ROI was 65.3 ± 18.7% (n = 4) of that in untreated cells.

To further show that 10^–6 M ANG II downregulates surface expression level of hkNBCe1 cotransporters, we performed confocal microscopy experiments, as described above (Fig. 4B). We found that the hkNBCe1-EGFP fluorescence near the plasma membrane of oocytes treated for 20 min with 10^–6 M ANG II (Fig. 4Bb) was significantly lower (65.3 ± 18.7%, n = 4) than that of untreated oocytes (Fig. 4Ba).

Coprecipitation of hkNBCe1 and PKC from oocyte membrane fractions. We performed coimmunoprecipitation to determine whether there was an association between hkNBCe1 proteins and endogenous PKC proteins at the plasma membrane of the X. laevis oocytes. One group of oocytes expressing hkNBCe1-EGFP or injected with dH₂O was treated with 10 nM PMA for 10 min. Another group of cells coexpressing hkNBCe1-EGFP and AT_1B or dH₂O-injected was treated with 10^–6 M ANG II for 20 min. The oocytes were homogenized, and the membranes were isolated from precleared homogenate by centrifugation for 1 h at 15,000 g. Immunoprecipitations were performed by incubating 500 µg membrane protein extracts with 50 µl of Protein A/G PLUS-Agarose beads conjugated to anti-GFP polyclonal antibodies overnight at 4°C.

Western blot analysis of the eluted proteins showed that recombinant hkNBCe1-EGFP and endogenous PKC were coprecipitated from membrane fractions of PMA-treated and -untreated oocytes (Fig. 5, lanes 1 and 2). We also found that PMA treatment increased the amount of PKC precipitated. The intensity of the PKC band from PMA-treated oocytes (Fig. 5A, lane 1) was 302.6 ± 53.3% (n = 4) of that from untreated oocytes (Fig. 5, lane 2).

View larger version (47K): [in this window] [in a new window]   Fig. 5. A: PMA increases the intensity of the PKC band coimmunoprecipitated with hkNBCe1 from oocyte membrane fractions. Oocytes injected with hkNBCe1 or dH2O and incubated for 10 min in the presence or absence of 10 nM PMA were homogenized, and each membrane fraction was immunoprecipitated with GFP polyclonal antibodies, followed by Western immunoblot analysis using monoclonal anti-GFP (1:1,000; top) and anti-PKC antibodies (specific to PKC) (1:1,000; bottom). Lane 1: oocytes expressing hkNBCe1-EGFP and treated with PMA. Lane 2: oocytes expressing hkNBCe1-EGFP not treated with PMA. Lane 3: control dH2O-injected oocytes treated with PMA. Lane 4: control H2O-injected oocytes not treated with PMA. Note the increase in the intensity of the PKC band in the PMA-treated (302.6 ± 53.3%, n = 4) compared with untreated oocytes. B: ANG II increases the intensity of the PKC band coimmunoprecipitated with hkNBCe1 from oocyte membrane fractions. Oocytes coinjected with hkNBCe1 and AT1B and incubated for 20 min in the presence or absence of 10–6 M ANG II, followed by Western analysis using monoclonal anti-GFP (1:1,000; top) and anti-PKC antibodies (1:1,000; bottom). Lane 1: oocytes coexpressing hkNBCe1-EGFP with AT1B not treated with ANG II. Lane 2: oocytes coexpressing hkNBCe1-EGFP with AT1B and treated with ANG II. Lane 3: control H2O-injected oocytes treated with ANG II. Lane 4: control H2O-injected oocytes not treated with ANG II. Note the increase in the intensity of the PKC band in the ANG II-treated (270.4 ± 59.0%, n = 4) compared with untreated oocytes.

Biphasic effect of ANG II. When we tested oocytes expressing hkNBCe1 without AT_1B, we found that neither 10^–11 nor 10^–6 M ANG II altered NBC current, with the remaining current being 92.2 ± 9 (n = 6) and 97.5 ± 10.2% (n = 6), respectively, of the control (data not shown). When we tested oocytes coexpressing hkNBCe1 with AT_1B, we found that a 20-min treatment with 10^–11 or 10^–10 M ANG II caused a moderate stimulation of NBC current, with the remaining current being 126.2 ± 6.6 (n = 6) and 121.6 ± 10.2% (n = 6), respectively, of the control (Fig. 6, bar graphs C1 and D1). In contrast, 10^–9 M ANG II had no effect on hkNBCe1 [remaining current, 97.3 ± 6.0% (n = 6) of the control; Fig. 6, bar graph E1], whereas 20-min treatments with 10^–8 and 10^–6 M ANG II significantly inhibited hkNBCe1, with the remaining currents being 62.8 ± 9.6 (n = 6) and 50.6 ± 7.7% (n = 11), respectively, of the control (Fig. 6, bar graphs F1 and G1). These results indicate that ANG II has a biphasic effect on hkNBCe1 coexpressed with AT_1B in oocytes.

View larger version (27K): [in this window] [in a new window]   Fig. 6. Biphasic effect of ANG II on hkNBCe1 coexpressed with AT1B in oocytes: role of PKC and intracellular Ca2+. Bars representing means ± SD of relative NBC peak currents acquired as the ratio of test to control current for 6 (11 in bar G1) experiments obtained from oocytes coexpressing hkNBCe1 and AT1B and treated with ANG II at concentrations of 10–11 M (C1), 10–10 M (D1), 10–9 M (E1), 10–8 M (F1), and 10–6 M (G1). Bars C2, D2, E2, F2, and G2: 100 nM GF was applied together with the indicated concentration of ANG II for 20 min. Bars C3, D3, E3, F3, and G3: intracellular Ca2+ was chelated by a 30-min pretreatment with 50 µM BAPTA-AM, followed by treatment with the indicated concentration of ANG II for 20 min. *P < 0.005. **P < 0.05 by Student's t-test.

	DISCUSSION

TOP ABSTRACT EXPERIMENTAL PROCEDURES RESULTS DISCUSSION GRANTS REFERENCES

 
PKC inhibition of hkNBCe1. At low concentrations, PMA is a potent PKC activator in many cells, including X. laevis oocytes (4, 41). We showed here that treatment for 10 min with 10 nM PMA results in a 50% reduction in the activity of the renal electrogenic Na⁺-HCO₃^– cotransporter, as assayed by the amplitudes of the current via hkNBCe1 in response to a depolarizing step in voltage-clamped oocytes. This PMA-specific inhibition is mediated by PKC, as indicated by the observation that GF significantly reduced hkNBCe1 inhibition. Moreover, PMA inhibition is mediated by Ca-dependent conventional PKC isoforms, as indicated by the observation that GÖ significantly reduced hkNBCe1 inhibition. PMA has been reported to cause a rapid redistribution of PKC activity from the cytosol to the membrane fraction of cells (22). Because hkNBCe1 localizes to membranes, the translocation of PKC makes it more accessible for interaction with the cotransporter. In PMA-untreated oocytes, we detected endogenous isoforms of PKC in the hkNBCe1-EGFP immunoprecipitates from the membrane fractions, suggesting a basal level of membrane association between hkNBCe1 and PKC. A 10-min treatment with 10 nM PMA enhanced the hkNBCe1-PKC interaction threefold. PMA has been reported to have differential effects on the surface expression of membrane proteins. For example, PMA induces retrieval of renal Na⁺/dicarboxylate cotransporters (29), type II Na⁺-phosphate cotransporters (14), and GABA_C receptors (24) expressed in X. laevis oocytes. In contrast, PMA does not alter the level of surface expression of CFTR expressed in X. laevis oocytes (6). Therefore, we performed surface biotinylation and confocal fluorescent imaging experiments to determine whether PMA-activated PKC alters the membrane expression of the hkNBCe1 cotransporters. Our data clearly indicate that a 10-min treatment with 10 nM PMA does not cause retrieval of the cotransporter from the membrane of X. laevis oocytes. Thus taken together, our electrophysiological, coprecipitation, biotinylation, and imaging data strongly suggest that PMA-activated PKC isoforms may inhibit hkNBCe1 via protein-protein interaction.

Importantly, we eliminated the possibility that Ca²⁺ signaling was involved in the observed PMA inhibition of NBC current. First, we directly monitored intracellular Ca²⁺ in PMA-treated fluo 4-loaded oocytes and detected no cytosolic Ca²⁺ elevation. Consequently, our observations that BAPTA reduces PMA inhibition of NBC current may be due to the reported ability of BAPTA to inactivate PKC (9). Second, we observed that in BAPTA-treated oocytes, both PKC inhibitors (GF or GÖ) reduced PMA inhibition of NBC current similarly to that in BAPTA-untreated oocytes, suggesting that Ca²⁺ signaling is not involved in PMA inhibition. How can Ca-dependent PKC isoforms be activated in the absence of cytosolic Ca²⁺ increase? It has been suggested that PMA directly binds to the diacylglycerol binding domain of PKC and activates Ca-dependent PKC isoforms in the absence of concurrent Ca²⁺ occupation of the Ca-binding domain (28).

To summarize, our results suggest that 1) Ca-dependent PKC isoforms mediate PMA-induced inhibition of hkNBCe1, 2) PMA increases the membrane interaction of PKC with hkNBCe1, and 3) PMA-activated PKC does not induce downregulation of hkNBCe1 cotransporter surface expression level (see model in Fig. 8).

View larger version (19K): [in this window] [in a new window]   Fig. 8. Putative model of PMA and ANG II inhibition of hkNBCe1. PMA diffuses across the cell membrane and directly activates Ca-dependent PKC isoforms. PKC isoforms inhibit hkNBCe1 via a protein-protein interaction resulting in possible phosphorylation of the cotransporter. PMA does not increase cytosolic Ca2+ and does not trigger downregulation of the surface expression level of cotransporters. ANG II binds to the AT1 receptor, activating PKC and Ca2+ signaling pathways. ANG II-activated Ca-independent novel PKC isoform inhibits hkNBCe1 via a protein-protein interaction resulting in possible phosphorylation of the cotransporter. ANG II-increased cytosolic Ca2+ may downregulate hkNBCe1 by triggering its internalization from the cell surface or inhibiting its recycling back to the cell surface.

Using a cell surface-biotinylation assay followed by Western blot analysis, we observed that treatment with 10^–6 M ANG II for 20 min significantly decreased the intensity of the biotinylated hkNBCe1-EGFP band. These findings were confirmed by confocal laser-scanning microscopy in living cells using time-lapse imaging of the near-membrane surface in oocytes coexpressing hkNBCe1-EFGP and AT_1B. We observed that ANG II caused a significant decrease in near-membrane EGFP fluorescence compared with untreated cells. Thus a 20-min treatment with 10^–6 M ANG II induces downregulation of surface expression level of hkNBCe1 cotransporters. Because 10^–6 M ANG II elevates cytosolic Ca²⁺ in fluo 4-loaded oocytes (Fig. 7B) and BAPTA significantly reduces ANG II inhibition of hkNBCe1 (Fig. 2B, bar G), we suggest that Ca²⁺ signaling may trigger the observed downregulation of cotransporters.

To summarize, our results suggest that 1) Ca-insensitive PKC isoform mediates ANG II-induced inhibition of hkNBCe1, 2) ANG II increases the membrane interaction of PKC with hkNBCe1, and 3) ANG II-induced intracellular Ca²⁺ elevation may trigger downregulation of the surface expression level of cotransporters in oocytes coexpressing hkNBCe1 and AT_1B (see model in Fig. 8).

Here, we present data that demonstrate that ANG II regulation of NBC1 in oocytes is similar to that in native epithelia. Specifically, ANG II has a biphasic effect on NBC1 in both oocytes (Fig. 6) and renal PT (8, 12, 15, 17, 33). In the mammalian kidney, however, the ANG II regulation of NBC1 is complicated by the expression of two types of AT receptors and several variants of electrogenic Na⁺-HCO₃^– cotransporters (30, 32). Nevertheless, presented data are valuable for the identification of key molecular mechanisms responsible for hormonal regulation of bicarbonate absorption in mammalian kidneys.

	GRANTS

TOP ABSTRACT EXPERIMENTAL PROCEDURES RESULTS DISCUSSION GRANTS REFERENCES

 
This work was supported by a Howard Hughes Medical Institute Grant (HHMI 76200-550102) to Dr. I. I. Grichtchenko.

	ACKNOWLEDGMENTS

 
We thank Dr. L. Pulakat (Bowling Green State University, Bowling Green, OH) for providing the AT_1B cDNA construct and Drs. A. Newton, S. R. Levinson, N. R. Zahniser, and A. Zweifach for helpful advice. We also thank R. Khera, C. Patel, D. Siino, and M. E. Kronberg for technical support.

	FOOTNOTES

 

Address for reprint requests and other correspondence: I. I. Grichtchenko, Dept. of Physiology and Biophysics, Univ. of Colorado Health Sciences Center, Mail Stop 8307, P.O. Box 6511, Aurora, CO 80045 (e-mail: irina.grichtchenko{at}uchsc.edu)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

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