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Differential modulation of a polymorphism in the COOH terminus of the -subunit of the human epithelial sodium channel by protein kinase C

¹Division of Pulmonary Medicine, The Children's Hospital of Philadelphia, and ²Department of Pediatrics, University of Pennsylvania School of Medicine, Philadelphia; and ³Departments of Medicine and of Cell Biology and Physiology, University of Pittsburgh, Pittsburgh, Pennsylvania

Submitted 5 July 2005 ; accepted in final form 12 September 2005

	ABSTRACT

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
The A663T polymorphism of the -subunit of the human epithelial sodium channel (hENaC) increases the functional and surface expression of -hENaC in Xenopus laevis oocytes. The context of this residue in the COOH terminus of -hENaC is important for this effect, as a homologous change in murine ENaC (mENaC), A692T, does not alter functional and surface expression of mENaC. Query of a phosphoprotein database suggested that the -T663 residue might be phosphorylated by PKC. General inhibition of PKC with calphostin C decreased the functional and surface expression of T663-hENaC and not A663-hENaC, and was without effect on A692-mENaC, T692-mENaC, and a chimeric m(1–678)/h(650–669)T663, m-ENaC. These data suggest that residues outside of the -hENaC COOH terminus are important for modulation of T663-hENaC trafficking by PKC. In contrast, expression of PKC decreased the functional and surface expression of T663-hENaC and the functional expression of m(1–678)/h(650–669)T663, m-ENaC, and was without effect on A663-hENaC, A692-mENaC, or T692-mENaC. PKC did not phosphorylate the COOH terminus of either T663-hENaC or A663-hENaC in vitro, suggesting that it acts indirectly to regulate hENaC trafficking. T663-hENaC was retrieved from the oocyte membrane more slowly than A663-hENaC, and calphostin C increased the rate of T663-hENaC removal from the oocyte membrane to a rate similar to that of A663-hENaC. In contrast, PKC did not alter the rate of removal of T663-hENaC from the oocyte membrane, suggesting that PKC altered rates of T663-hENaC biosynthesis and/or delivery to the plasma membrane. These data are consistent with PKC isoform-specific effects on the intracellular trafficking of T663- vs. A663-hENaC.

trafficking; oocyte; phosphorylation

ENaCs are composed of three structurally related subunits, termed -, -, and -ENaC, that likely assemble as an ₂,₁,₁ tetramer (10, 17), although alternate subunit stoichiometries have been proposed (25). The three subunits have limited (30–40%) sequence identity but share a common topology of two membrane-spanning domains and intracellular NH₂ and COOH termini (6, 20, 26).

Changes in ENaC functional expression are associated with alterations in blood pressure (12, 13). ENaC loss-of-function mutations lead to type I pseudohypoaldosteronism, a disorder characterized by volume depletion, hypotension, and hyperkalemia (8, 22), as well as profuse respiratory secretions and increased mucociliary clearance (16). In contrast, ENaC gain-of-function mutations cause Liddle's syndrome, a disorder characterized by volume expansion, hypokalemia, and hypertension (24) but, interestingly, little pulmonary phenotype (3). Some common human ENaC (hENaC) polymorphisms may segregate with blood pressure (i.e., T594M) (4), suggesting that ENaC polymorphisms that alter functional channel expression may contribute to the development of hypertension in the general population.

A663T is a common polymorphism in the COOH terminus of the -subunit of hENaC, and there are conflicting data reported as to whether this polymorphism segregates with blood pressure (1, 30). We have previously shown that Xenopus laevis oocytes expressing wild-type T663-hENaC had significantly higher currents than oocytes expressing A663 and that these the higher currents were associated with higher levels of cell surface expression of channels, suggesting that this polymorphism altered channel trafficking (21). This polymorphism is present in the distal COOH terminus of the -subunit, a region that is not well conserved between human and mouse -subunits and that may influence interaction with the cystic fibrosis transmembrane conductance regulator (32). Interestingly, we demonstrated that the A692T mutation in mouse ENaC (mENaC), corresponding to human A663T, was not associated differences in functional -mENaC expression, whereas replacement of the distal COOH terminus of the mouse -subunit with the distal COOH terminus of the human -subunit restored the functional differences that were observed with the human A663T polymorphism.

That T663 is potentially modifiable by phosphorylation, and from our previous observations that mutation of T663 to D663 does not alter the functional expression of hENaC in oocytes (21) suggests the hypothesis that phosphorylation of T663 may regulate its increased functional and surface expression in X. laevis oocytes. Our data suggest that global inhibition of PKC, and specific expression of PKC, can regulate the functional and surface expression of T663-hENaC, and not A663-hENaC, and that the context of the distal COOH terminus of the ENaC -subunit is important for this effect. Our data also suggest that global inhibition of PKC and expression of PKC influence the intracellular trafficking of the T663-hENaC by different mechanisms. Finally, our data suggest that regulation of T663-hENaC by PKC does not result from direct phosphorylation of T663 by PKC and that PKC-dependent regulation of T663-hENaC does not account for the enhanced functional and surface expression of T663-hENaC.

	MATERIALS AND METHODS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION GRANTS REFERENCES

 
Materials. Calphostin C was purchased from Calbiochem (La Jolla, CA). All other reagents were purchased from Fisher Chemical.

Expression of ENaC and PKC in oocytes. -, -, and -hENaC cDNAs were from M. J. Welsh (University of Iowa). mENaC cDNAs have been described and used by our group previously (17). All mutants and mouse/human chimeras were described previously by our group (21, 32). cDNAs for murine PKC and a kinase-dead enhanced green fluorescent protein-murine PKC fusion protein (K472N; active site lysine replaced by asparagine) were a gift of Dr. C. Stubbs (Jefferson Medical College).

cRNAs for wild-type and mutant -hENaC and -mENaC, wild-type -hENaC and -mENaC, wild-type -hENaC and -mENaC, and PKC and kinase-dead PKC were synthesized from linearized plasmids containing the appropriate cDNAs using appropriate RNA polymerases (T₃, T₇, or SP6, mMessage mMachine, Ambion, Austin, TX) and stored at –80°C. cRNA concentration was determined spectroscopically. Stage V-VI oocytes were surgically harvested from female X. laevis (NASCO, Fort Atkinson, WI, or Xenopus Express, Plant City, FL) and pretreated with 2 mg/ml collagenase (type IV, Sigma), as previously described (23). Oocytes were injected with 2 ng/subunit of hENaC cRNAs or 0.33 ng/subunit of mENaC cRNAs in 50 nl of H₂O. In some experiments, 5 ng of PKC cRNA or 2–20 ng of kinase-dead PKC cRNA were coinjected with the hENaC cRNAs. After injection, oocytes were incubated at 18°C in modified Barth's saline [MBS; (in mM) 88 NaCl, 1 KCl, 2.4 NaHCO₃, 15 HEPES, 0.3 Ca (NO₃)₂, 0.41 CaCl₂, 0.82 MgSO₄, pH 7.2] supplemented with 10 µg/ml sodium penicillin, 10 µg/ml streptomycin sulfate, and 100 µg/ml gentamicin sulfate. In some experiments, a protein kinase inhibitor was added to the MBS immediately after injection. The animal protocol was approved by the Children's Hospital of Philadelphia's and the University of Pittsburgh's Institutional Animal Care and Use Committees.

Two-electrode voltage clamp. Two-electrode voltage clamp (TEV) was performed 24–48 h after cRNA injection at room temperature using a DigiData 1320 interface and Axon Geneclamp 500B Amplifier (Axon Instruments, Foster City, CA). Data were acquired at 200 Hz and analyses were performed using pClamp 8.0 or 8.1 software (Axon Instruments) on 833-MHz Pentium III Personal Computers (Dell Computer, Austin, TX). Pipettes were pulled from borosilicate glass capillaries (World Precision Instruments, Sarasota, FL) with a Micropipette Puller (Sutter Instrument, Novato, CA) and had a resistance of 0.5–5 M when filled with 3 M KCl and inserted into the bath solution. Oocytes were maintained in a recording chamber with 1 ml of bath solution and continuously perfused with bath solution at a flow rate of 4–5 ml/min. The bath solution contained (in mM) 100 Na gluconate, 2 KCl, 1.8 CaCl₂, 3 BaCl₂, 10 tetraethylammonium Cl, and 10 HEPES, pH 7.4. A series of voltage steps (1 s) from –140 to + 60 mV (adjusted for resting membrane potential) in 20-mV increments were performed, and whole cell currents were recorded 750 ms after initiation of the –100-mV voltage step for data analysis. ENaC-mediated current was defined as the difference in whole oocyte current at –100 mV holding potential (adjusted for resting membrane potential) before and after addition of 10 µM amiloride-HCl (Sigma) to the bath solution.

Whole oocyte and cell surface expression. Surface expression was examined by a cell surface biotinylation assay as we have previously described (21, 32). To facilitate detection of biotinylated hENaC subunits, these experiments used a -hENaC with a COOH-terminal V5 epitope tag (-V5) as previously described (11). Briefly, cRNAs for -V5-hENaC were coinjected into X. laevis oocytes. After 48 h, oocytes were mechanically stripped of their vitelline membranes in hypertonic media (300 mM sucrose in MBS without penicillin, streptomycin, and gentamicin; MBSnoAbx). Oocytes were then washed sequentially with MBSnoAbx, 10 mM triethylamine in MBSnoAbx, and surface proteins were labeled with 1.5 mg/ml sulfo-NHS-Biotin (Pierce) in triethylamine/MBSnoAbx for 30 min on ice. The biotinylation reaction was quenched with 5 mM glycine in MBS (4 separate 5-min incubations on ice). Oocytes (10/group) were subsequently washed with MBS, lysed in 0.15 M NaCl, 0.01 M Tris·HCl, pH 8.0, 0.01 M EDTA, 1.0% Nonidet P-40, 0.5% sodium deoxycholate, 1.0 mM phenylmethanesulfonyl fluoride, 0.1 mM N--p-tosyl-L-lysine chloromethyl ketone, 0.1 mM L-1-tosylamide-2-phenylethyl-chloromethyl ketone, and 2 µg/ml aprotinin for 1 h at 4°C, and centrifuged at 13,000 g for 15 min at 4°C. Biotinylated proteins were precipitated with streptavidin-agarose (Pierce) and subjected to SDS-PAGE. Biotinylated -subunits were detected on immunoblots probed with an anti-V5 antibody. Densitometry was performed using an AlphaImager 2200 system (AlphaInnotech, San Leandro, CA).

Whole oocyte expression of -V5-hENaC was assessed by immunoblotting of whole oocyte lysate prepared using the lysis buffer and procedure described above. Whole oocyte expression of PKC was similarly detected by immunoblot of whole oocyte lysate using an antibody purchased from BD Biosciences.

As a control for the integrity of the plasma membrane of the stripped oocytes, we assessed the recovery of biotinylated GAPDH in concurrent experiments. Biotinylated GAPDH was not recovered by streptavidin precipitation as detected by immunoblot despite it being readily detected by whole oocyte immunoblotting, suggesting that our oocytes were not leaky after mechanical stripping of the vitelline membrane.

In vitro phosphorylation. COOH-terminal glutathione S-transferase (GST) fusion proteins containing the COOH-terminal 20 amino acids of T663- and A663-hENaC were created by blunt-end ligation of AvrII/SphI fragments of the respective -hENaC plasmids into the EcoRI site of pGEX4T2 (Amersham). Orientation and in-frame translation were confirmed by automated DNA sequencing in The Children's Hospital of Philadelphia Nucleic Acid and Protein Core.

GST, GST-T663, or GST-A663 was expressed in Escherichia coli BL21, immobilized on glutathione-Sepharose 4B beads (Amersham), and subject to in vitro phosphorylation using the SignaTECT PKC assay system buffers, active PKC (Upstate Cell Signaling), and [-³²P]ATP (10 µCi, 3,000 Ci/mmol, DuPont New England Nuclear). Bound GST or GST fusion proteins were eluted by boiling SDS-PAGE sample buffer, resolved by SDS-PAGE, and stained with Coomassie blue. Phosphorylation was detected by fluorography. As a positive control for these assays, phosphorylation of biotinylated neurogranin_(28-43) provided in the SignaTECT PKC assay kit for PKC was assayed in parallel according to the manufacturer's protocol. In each experiment, phosphorylation of the neurogranin substrate was increased at least 10-fold over control (by liquid scintillation counting), suggesting that the lack of phosphorylation of the GST or GST fusion proteins was not due to a problem in the assay.

Assessment of hENaC delivery to and removal from the oocyte plasma membrane. To assess the rate of delivery of hENaC to the oocyte membrane, we made use of the observations that ENaC mutants where a cysteine was introduced into the "amiloride binding site" can be irreversibly blocked by treatment with [2-(trimethylammonium)ethyl] methanethiosulfonate bromide (MTSET). The time-dependent recovery of benzamil-sensitive whole cell currents reflects delivery of unmodified channels to the cell surface. Benzamil (100 µM) was used for these studies as channels containing amiloride binding site mutations are relatively amiloride insensitive (7, 27). We therefore constructed the G536C mutation in -hENaC using the Quik-Change kit (Promega) and confirmed its sequence by automated sequencing the Children's Hospital of Philadelphia Nucleic Acid and Protein Core. Oocytes were then injected with T663G536C- or A663G536C-hENaC as described above. Twenty-four to thirty-six hours after injection, whole oocyte currents were determined by TEV before application of MTSET, after 2 applications of MTSET (1 mM, 5 min each), and every 5 min for 25 min after removal of MTSET and washing of the oocyte. Benzamil (100 µM) was then added, and the remaining whole oocyte current that was insensitive to benzamil inhibition was determined by TEV. We then calculated the benzamil-sensitive current at a given point by determining the difference between the whole oocyte current at that point and the whole oocyte current remaining after addition of benzamil.

To assess the rate of removal of hENaC from the oocyte membrane, oocytes were injected with cRNAs as described above. Twenty-four to thirty-six hours after injection, amiloride-sensitive current was determined by TEV before (t = 0) and after 2, 4, and 6 h of incubation with brefeldin A (5 µM). Brefeldin A was used to block delivery of new channels to the oocyte membrane. Amiloride-sensitive currents were expressed relative to the initial amiloride-sensitive current (t = 0), and pseudo-first-order rate constants for decline of amiloride-sensitive current were determined for each individual oocyte, as well as the means and SE (SigmaPlot 2000).

Statistical analyses. Whole cell amiloride-sensitive current data are expressed relative to that of wild-type ENaC. To decrease the influence of batch-to-batch variability in ENaC expression, data (except those in Fig. 2) were normalized by the mean amiloride-sensitive current for the control condition (usually T663-hENaC) within a batch of oocytes before the combining of data of multiple independent batches for statistical analysis. These data are presented as means ± SE, and P values were determined by a two-tailed t-test or ANOVA. When a Poisson distribution, rather than a Gaussian distribution, best described these combined data, P values were determined by a two-tailed t-test or ANOVA after a square root transformation to better approximate a Gaussian distribution (34). A P value 0.05 was considered significant. We also independently analyzed the statistical significance of these data without normalization and transformation using the Wilcoxon rank sum/Mann-Whitney U-test for nonparametric results, and obtained similar P values to the method outlined above (data not shown). Other data that were normally distributed (including those in Fig. 2) are expressed as means ± SE with P values determined by a two-tailed t-test or paired t-test as appropriate. All statistical data analyses were performed with SigmaStat version 2.03.

View larger version (23K): [in this window] [in a new window]   Fig. 2. PKC activation reduces hENaC functional expression without altering surface expression in oocytes. A: T663- or A663-hENaC was expressed in oocytes, and 2-electrode voltage clamp (TEV) was performed before and after treatment with 200 nM PMA for 20 min. Amiloride-sensitive whole cell currents were determined at –100-mV holding potential (adjusted for resting membrane potential). Values are means ± SE, with the P value determined by a paired t-test as described in MATERIALS AND METHODS. B: hT663- or A663-ENaC, where the -subunit had a COOH-terminal V5 epitope tag (-V5), was expressed in oocytes. Cell surface biotinylation was performed as described in MATERIALS AND METHODS either without or with exposure to 200 nM PMA for 20 min, and -V5-hENaC was recovered by streptavidin-agarose precipitation and quantitated by immunoblotting with an anti-V5 antibody. A representative immunoblot (n = 3 independent experiments) is shown. C: representative immunoblots of whole oocyte lysates of T663- and A663-injected oocytes demonstrating similar expression of -V5-hENaC after treatment with 200 nM PMA for 20 min are also shown and are similarly representative of n = 3 independent experiments.

	RESULTS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION GRANTS REFERENCES

View larger version (19K): [in this window] [in a new window]   Fig. 1. Amino acid sequences of the COOH termini of human (h), mouse (Mur), and rat -subunit of the epithelial sodium channel (ENaC; -ENaC). Amino acid residue numbers at the beginning and end of each sequence are indicated. Gray shading indicates identity. Residue 663 of -hENaC and its homologous residue (692) in -mENaC and rat -ENaC are highlighted in black.

Influence of PKC activation on hENaC functional and surface expression. We first assessed the influence of acute activation of PKC with PMA on the functional expression of hENaC in oocytes. Consistent with the data of others (2), acute, nonspecific activation of PKC with PMA caused a decrease in amiloride-sensitive current, or functional expression of both T663- and A663-hENaC in oocytes (Fig. 2A). This decrease in functional expression was not associated with a change in hENaC surface expression as assessed by surface biotinylation of -V5-hENaC (Fig. 2B) or whole oocyte expression as assessed by immunoblot of -V5-hENaC (Fig. 2C). These data are thus consistent with acute, nonspecific activation of PKC altering ENaC open probability (P_o) or unitary conductance in oocytes.

Influence of PKC inhibition on hENaC functional and surface expression. We next assessed the influence of tonic inhibition of PKC on the functional and surface expression of T663- and A663-hENaC in oocytes. Oocytes were injected with T663- or A663-hENaC and then incubated either with, or without 200 nM calphostin C, a non-isotype-selective PKC inhibitor that binds to the PKC diacyl glycerol binding site, for 24–48 h. As shown in Fig. 3A, calphostin C decreases the ENaC functional expression in oocytes injected with T663-hENaC but does not alter the functional expression of A663-hENaC in oocytes. This pattern of T663- and A663-hENaC functional expression after exposure to calphostin C corresponded to the surface expression of these hENaCs. Whole oocyte expression of -V5-hENaC was unaltered by calphostin C for T663- and A663-hENaC (Fig. 3B; densitometry of the surface biotinylation experiments is shown in Fig. 3C). These data are thus consistent with PKC selectively regulating the trafficking of T663-hENaC in oocytes.

View larger version (25K): [in this window] [in a new window]   Fig. 3. PKC inhibition selectively reduces T663-hENaC functional and surface expression in oocytes. A: T663- or A663-hENaC was expressed in oocytes, and TEV was performed after incubation in the absence (gray bars) or presence (open bars) of 200 nM calphostin C for 24–48 h. Amiloride-sensitive whole cell currents were determined at –100-mV holding potential (adjusted for resting membrane potential) and are expressed relative to the mean whole oocyte current for T663-hENaC-expressing oocytes. Values are means ± SE with the P value determined by 1-way ANOVA as described in MATERIALS AND METHODS. B: hT663- or A663-ENaC, where the -subunit had a COOH-terminal V5 epitope tag (-V5), was expressed in oocytes in the absence or presence of 200 nM calphostin C for 24–48 h. Cell surface biotinylation was performed as described under in MATERIALS AND METHODS, and -V5-hENaC was recovered by streptavidin-agarose precipitation and quantitated by immunoblotting with an anti-V5 antibody. A representative immunoblot (n = 5 independent experiments) is shown. A representative immunoblot of whole oocyte lysates of T663- and A663-injected oocytes demonstrating similar expression of -V5-hENaC is also shown and is similarly representative of n = 5 independent experiments. C: densitometric analysis of the surface biotinylation experiments was performed as described in MATERIALS AND METHODS and are expressed as means ± SE of n = 5 independent experiments, normalized to values obtained with oocytes expressing T663-V5-hENaC. Open bars indicate oocytes incubated in the presence of 200 nM calphostin C for 24–48 h after injection, whereas oocytes represented by gray bars were incubated under control conditions. P values were determined by ANOVA compared with T663-V5-hENaC.

View larger version (17K): [in this window] [in a new window]   Fig. 4. Influence of PKC inhibition on mENaC and chimeric ENaC in oocytes. T692- or A692m-ENaC (A) or m(1–678)/h(650–669)T663m (m-hT663)- or m(1–678)/h(650–669)A663m (m-hA663)-ENaC (B) chimera was expressed in oocytes, and TEV was performed after incubation in the absence (gray bars) or presence (open bars) of 200 nM calphostin C for 24–48 h. Amiloride-sensitive whole cell currents were determined at –100-mV holding potential (adjusted for resting membrane potential) and are expressed relative to the mean whole oocyte current for T692-m-ENaC (A)- or m(1–678)/h(650–669)T663m-ENaC (B) chimera-expressing oocytes. Values are means ± SE, with the P value determined by 2-tailed t-test as described in MATERIALS AND METHODS. ns, Not significant.

Influence of PKC on hENaC functional and surface expression.

View larger version (31K): [in this window] [in a new window]   Fig. 5. PKC expression selectively reduces T663-hENaC functional and surface expression in oocytes. A: T663- or A663-hENaC cRNA was injected into oocytes either alone or together with 5 ng cRNA for PKC. Whole oocyte lysates were prepared, and PKC was detected by immunoblotting. B: T663- or A663-hENaC cRNA was injected into oocytes either alone (gray bars) or coinjected with 5 ng cRNA for PKC (open bars), and TEV was performed after 24–48 h. Amiloride-sensitive whole cell currents were determined at –100-mV holding potential (adjusted for resting membrane potential) and are expressed relative to the mean whole oocyte current for T663-hENaC-expressing oocytes. Values are means ± SE, with the P value determined by 1-way ANOVA as described in MATERIALS AND METHODS. C: T663- or A663-hENaC, where the -subunit had a COOH-terminal V5 epitope tag (-V5), was expressed in oocytes either without or with coinjection of 5 ng PKC cRNA. Cell surface biotinylation was performed as described in MATERIALS AND METHODS, and -V5-hENaC was recovered by streptavidin-agarose precipitation and quantitated by immunoblotting with an anti-V5 antibody. A representative immunoblot (n = 5 independent experiments) is shown. A representative immunoblot of whole oocyte lysates of T663- and A663-injected oocytes demonstrating similar expression of -V5-hENaC is also shown and is similarly representative of n = 5 independent experiments. D: densitometric analysis of the surface biotinylation experiments was performed as described in MATERIALS AND METHODS and are expressed as means ± SE, n = 5 independent experiments, normalized to values obtained with oocytes expressing T663-V5-hENaC. Open bars indicate oocytes coinjected with ENaC and 5 ng PKC cRNA, whereas oocytes represented by gray bars were injected with ENaC alone. P values were determined by ANOVA compared with T663-V5-hENaC.

View larger version (17K): [in this window] [in a new window]   Fig. 6. Influence of PKC expression on mENaC and chimeric ENaC in oocytes. T692- or A692-mENaC (A) or m(1–678)/h(650–669)T663 (m-hT663)- or m(1–678)/h(650–669)A663m (m-hA663)-ENaC chimera (B) cRNA was injected either alone (gray bars) or was coinjected with PKC cRNA (5 ng). Amiloride-sensitive whole cell currents were determined 24–48 h after injection at –100-mV holding potential (adjusted for resting membrane potential) and are expressed relative to the mean whole oocyte current for T692-mENaC (A) or m(1–678)/h(650–669)T663m-ENaC (B) chimera-expressing oocytes. Values are means ± SE, with the P value determined by 2-tailed t-test as described in MATERIALS AND METHODS.

View larger version (15K): [in this window] [in a new window]   Fig. 7. Kinase-dead PKC expression does not influence T663-hENaC functional expression in oocytes. Oocytes were injected with cRNA for -T663-hENaC (2 ng/subunit) and the indicated amount of cRNA for a kinase-dead (K472N) PKC. After 24–48 h, whole oocyte amiloride-sensitive currents at –100-mV holding potential (adjusted for baseline transmembrane potential) were measured by TEV. Values are means ± SE expressed relative to the mean whole oocyte current for oocytes injected with T663-hENaC alone with statistical significance assessed by ANOVA as described in MATERIALS AND METHODS.

PKC does not directly phosphorylate the COOH terminus of -hENaC.

View larger version (23K): [in this window] [in a new window]   Fig. 8. PKC does not phosphorylate T663 in vitro. GST and COOH-terminal fusions of glutathione S-transferase (GST) containing the COOH-terminal 20 amino acids of -hENaC, GST-T663, and GST-A663 were expressed in Escherichia coli, immobilized on glutathione-Sepharose 4B, and subject to in vitro phosphorylation with PKC and [-32P]ATP as described in MATERIALS AND METHODS. GST, GST-T663, and GST-A663 were subsequently resolved by SDS-PAGE. A: Coomassie blue-stained SDS-PAGE demonstrating expression of GST, GST-T663, and GST-A663. B: fluorogram (3-day exposure) of A demonstrating lack of 32P associated with GST, GST-T663, and GST-A663. The mobility of GST is indicated by the black arrowhead in the left margin, and the mobility of GST-T663 and GST-A663 are indicated by the gray arrowhead in the right margin. In A and B, the mobility of the molecular weight standards are indicated in the left margin. C: representative positive control phosphorylation of neurogranin(28-43) by active PKC was performed using the SignaTECT kit according to the manufacturer's protocol as described in MATERIALS AND METHODS. These data are presented as counts/minute determined by liquid scintillation counting and are the average of duplicate determinations. Data in A–C are each representative of n = 3 independent experiments.

Influence of the A663T polymorphism on hENaC trafficking in oocytes.

View larger version (13K): [in this window] [in a new window]   Fig. 9. A663T polymorphism influences hENaC intracellular trafficking. A: to assess the rate of hENaC delivery to the oocyte membrane, oocytes were injected with either A663G536C- or T663G536C-hENaC. After 24 h, benzamil (100 µM)-sensitive currents were determined by TEV before, during, and after covalent blockade of these channels with 1 mM MTSET as described in MATERIALS AND METHODS. Values are means ± SE presented as the benzamil-sensitive current relative to that of the initial benzamil-sensitive current to account for batch-to-batch and oocyte-to-oocyte variability. These data are derived from 5 different batches of oocytes. B: to assess the rate of removal of hENaC from the oocyte membrane, oocytes were injected with A663 (triangles)- or T663-hENaC (squares). After 24–36 h, amiloride-sensitive currents were determined by TEV, and the oocytes were subsequently incubated in 5 µM brefeldin A. Amiloride-sensitive currents were again determined by TEV after 2, 4, and 6 h of incubation in brefeldin A. These amiloride-sensitive currents were expressed relative to the amiloride-sensitive current before incubation with brefeldin A (means ± SE), and apparent first-order rate constants were fit as described in MATERIALS AND METHODS and compared by a 2-tailed t-test. These data were derived from 4 different batches of oocytes.

Differential effects of PKC inhibition and PKC expression on the removal of T663-hENaC from the oocyte membrane. As shown above, both global inhibition of PKC with calphostin C (Fig. 3) and expression of PKC (Fig. 5) reduced functional and surface expression of T663-hENaC. As this result seemed paradoxical, we sought further mechanistic insight by assessing the influence of calphostin C and PKC expression on the rate of retrieval of T663-hENaC from the oocyte plasma membrane. Global inhibition of PKC with calphostin C increased the rate constant for T663-hENaC removal from the oocyte membrane (Fig. 10A). Interestingly, the rate constant for T663-hENaC removal from the oocyte membrane in the presence of calphostin was similar to that for the removal of A663-hENaC (Fig. 9B). In contrast, coexpression of PKC and T663-hENaC did not alter the rate constant for removal of T663-hENaC from the oocyte plasma membrane (Fig. 10B), suggesting that PKC affects rates of biosynthesis and/or delivery of T663-hENaC to the plasma membrane.

View larger version (14K): [in this window] [in a new window]   Fig. 10. Differential effects of PKC inhibition and PKC expression on the removal of T663 from the oocyte membrane. The apparent first-order rate constant for removal of T663-hENaC from the oocyte membrane was determined as described in MATERIALS AND METHODS and the legend for Fig. 9B for oocytes injected with T663-hENaC and incubated in the absence (squares) or presence (circles) of 200 nM calphostin C for 24–36 h prior to assay (A) or oocytes injected with T663-hENaC either alone (squares) or coinjected with 5 ng cRNA for PKC (circles; B). Values are means ± SE presented as amiloride-sensitive currents relative to the initial amiloride-sensitive current for each individual oocyte and result from 5 and 3 batches of oocytes for A and B, respectively.

	DISCUSSION

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That T663 is potentially modified by phosphorylation, and our previous data that mutation of T663 to D663 does not alter the functional expression of hENaC in oocytes (21), led us to test the hypothesis that phosphorylation of T663 in hENaC may regulate its increased functional and surface expression in X. laevis oocytes. Query of a protein phosphorylation prediction database suggested potential phosphorylation of T663 by PKC, so we specifically tested the hypotheses that the action of PKC and, specifically PKC might regulate the increased functional and surface expression of T663- vs. A663-hENaC via the context of the COOH-terminal 20 amino acids of -hENaC.

Activation of PKC by phorbol esters inhibits ENaC activity in renal epithelia (5, 18, 19, 33). In A6 cells, phorbol ester-dependent activation of PKC results in a rapid inhibition of ENaC, and these inhibitory effects are maintained over 24–28 h. While the rapid inhibition of ENaC activity reflect a reduction in channel P_o, the long-term inhibitory effects of phorbol esters are due to a MAPK/ERK1/2 dependent reduction in the levels of - and -subunit expression (5, 29). In contrast, PKC activation reduces levels of -subunit expression in parotid cells via a MAPK/ERK-dependent pathway (35).

We observed that global, acute activation of PKC by a phorbol ester did not yield differential effects on T663- and A663-hENaC, thus failing criterion 1. In contrast global, tonic inhibition of PKC with calphostin C decreased the functional and surface expression of T663-hENaC without influencing A663-hENaC, satisfying criterion 1. Inhibition of PKC with chronic calphostin C exposure also satisfied criterion 2, as there was essentially no effect of calphostin C on the functional expression of either T692- or A692-mENaC. However, the effect of calphostin C did not satisfy criterion 3, as its effect on the mENaC background is not observed in the m(1–678)/h(650–669)-T663m-ENaC chimera. These data suggest that, whereas a PKC may influence T663-hENaC functional and surface expression, this effect is not mediated solely through the COOH-terminal 20 amino acids of T663-hENaC.

One can speculate about a few potential mechanisms by which this might occur. For example, calphostin C might inhibit more than one isoform of PKC that differentially regulates hENaC and mENaC at sites distinct from the COOH terminus. The present studies do not directly address which calphostin C-inhibited PKC isoform(s) endogenous within oocytes differentially regulates hENaC (T663) and mENaC (T692).

In contrast, our data regarding the influence of PKC expression do satisfy our first three criteria for selective modulation of functional and surface expression of this polymorphic hENaC in the context of the COOH-terminal 20 amino acids of -ENaC. Expression of PKC selectively decreased T663-hENaC functional and surface expression but did not alter A663-hENaC functional or surface expression. Expression of PKC also did not influence the functional expression of either T692- or A692-mENaC, and introduction of the COOH-terminal 20 amino acids of -hENaC into mENaC [m(1–678)/h(650–669)-T663m-ENaC] resurrected the influence of PKC expression. These data are therefore consistent with our hypothesis that PKC selectively influences the trafficking of T663-hENaC, but not A663-hENaC, in the context of the COOH-terminal 20 residues of T663-hENaC.

While consistent with our hypothesis that PKC would selectively regulate the trafficking of T663-hENaC, but not A663-hENaC, the decrease in functional and surface expression of T663-hENaC caused by expression of PKC failed criterion 4. Our prediction, based on our published data that T663D-hENaC had essentially the same functional expression in oocytes as T663-hENaC (21), was that selective phosphorylation of T663 would increase T663-hENaC trafficking and functional expression. The selective regulation of T663-hENaC vs. A663-hENaC by PKC suggests that stimuli and signaling pathways that alter PKC activity in epithelial cells may selectively affect the activity of T663-hENaC and thereby potentially modulate a susceptibility to hypertension conferred by this polymorphism.

Our data also suggest that, even though it is predicted to be a substrate for PKC, T663 is in fact not a substrate for this kinase, and that PKC influences T663-hENaC trafficking through an indirect mechanism. Such regulation of ENaC trafficking by phosphorylation of proteins that interact with ENaC rather than ENaC itself is well described, with the best example being the increase in ENaC functional and surface expression on activation of the serum and glucocorticoid regulated kinase (SGK). SGK, rather than phosphorylating ENaC directly, phosphorylates the E3-ubiquitin ligase Nedd4–2, which leads to decreased interaction of Nedd4–2 with ENaC and decreased removal of ENaC from the plasma membrane (9, 28). While other kinases might activate ENaC by preferentially phosphorylating T663 in a species-specific manner, these remain to be identified.

Our experiments examining rates of delivery and removal of hENaC from the plasma membrane suggest that the increase in surface expression of T663-hENaC, relative to that of A663-hENaC, is a result of a reduced rate of removal of T663-hENaC from the plasma membrane. Inhibition of endogenous PKC activity by calphostin C led to an increase in the rate of removal of T663-hENaC from the plasma membrane, suggesting than one (or more) active PKC isoforms are modulating rates of T663-hENaC endocytosis. Expression of PKC did not affect rates of T663-hENaC endocytosis, suggesting that 1) PKC is not one of the PKC isoforms that modulates rates of T663-hENaC endocytosis and 2) PKC-dependent inhibition of T663-hENaC reflects a reduced rate of biosynthesis and/or delivery of T663-hENaC to the plasma membrane.

In summary, our data suggest that PKC selectively regulates the functional and surface expression of the T663-hENaC allele of the common polymorphism A663T in the COOH terminus of -hENaC and that the context of the COOH-terminal 20 residues of -hENaC are important for this effect. Furthermore, our results with calphostin C suggest that other PKC isoforms selectively modulate T663-hENaC surface expression. We predict that the alleles of the A663T polymorphism will have a differential response to signals and stimuli that result in activation of specific PKC isoforms. Such differential regulation may ultimately result in altered hENaC function and, consequently, altered risk for developing hypertension.

	GRANTS

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This work was supported by National Institute of Diabetes and Digestive and Kidney Diseases Grants DK-54354 and DK-58046. R. C. Rubenstein is an Established Investigator of the American Heart Association.

	FOOTNOTES

 

Address for reprint requests and other correspondence: T. R. Kleyman, Renal-Electrolyte Div., Dept. of Medicine, A919 Scaife Hall, 3550 Terrace St., Pittsburgh, PA 15261 (e-mail: kleyman{at}pitt.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.

	REFERENCES

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