Home | Help | Feedback | Subscriptions | Archive | Search | Table of Contents

This Article Abstract Full Text (PDF, 487K) PPT slides of all figures Alert me when this article is cited Citation Map Services Email this article Similar articles in this journal Similar articles in PubMed Alert me to new content in the JGP Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via CrossRef Citing Articles via Google Scholar Google Scholar Articles by Adebamiro, A. Articles by Bridges, R. J. Search for Related Content PubMed PubMed Citation Articles by Adebamiro, A. Articles by Bridges, R. J. Social Bookmarking                            What's this?

Effect of Serine Protease Inhibition on ENaC Single Channel Properties

Adedotun Adebamiro¹, Yi Cheng³, John P. Johnson², and Robert J. Bridges³

¹ Department of Cell Biology and Physiology, University of Pittsburgh, Pittsburgh, PA 15261
² Renal-Electrolyte Division, Department of Medicine, University of Pittsburgh School of Medicine, Pittsburgh, PA 15261
³ Department of Physiology and Biophysics, Rosalind Franklin University of Medicine and Science, North Chicago, IL 60064

Correspondence to Robert J. Bridges: bob.bridges{at}rosalindfranklin.edu

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Endogenous serine proteases have been reported to control the reabsorption of Na⁺ by kidney- and lung-derived epithelial cells via stimulation of electrogenic Na⁺ transport mediated by the epithelial Na⁺ channel (ENaC). In this study we investigated the effects of aprotinin on ENaC single channel properties using transepithelial fluctuation analysis in the amphibian kidney epithelium, A6. Aprotinin caused a time- and concentration-dependent inhibition (84 ± 10.5%) in the amiloride-sensitive sodium transport (I_Na) with a time constant of 18 min and half maximal inhibition constant of 1 µM. Analysis of amiloride analogue blocker–induced fluctuations in I_Na showed linear rate–concentration plots with identical blocker on and off rates in control and aprotinin-inhibited conditions. Verification of open-block kinetics allowed for the use of a pulse protocol method (Helman, S.I., X. Liu, K. Baldwin, B.L. Blazer-Yost, and W.J. Els. 1998. Am. J. Physiol. 274:C947–C957) to study the same cells under different conditions as well as the reversibility of the aprotinin effect on single channel properties. Aprotinin caused reversible changes in all three single channel properties but only the change in the number of open channels was consistent with the inhibition of I_Na. A 50% decrease in I_Na was accompanied by 50% increases in the single channel current and open probability but an 80% decrease in the number of open channels. Washout of aprotinin led to a time-dependent restoration of I_Na as well as the single channel properties to the control, pre-aprotinin, values. We conclude that protease regulation of I_Na is mediated by changes in the number of open channels in the apical membrane. The increase in the single channel current caused by protease inhibition can be explained by a hyperpolarization of the apical membrane potential as active Na⁺ channels are retrieved. The paradoxical increase in channel open probability caused by protease inhibition will require further investigation but does suggest a potential compensatory regulatory mechanism to maintain I_Na at some minimal threshold value.

	INTRODUCTION

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Absorption of fluids and electrolytes is a function of many epithelia characterized, in many cases, by electrogenic Na⁺ transport where the rate limiting step is apical membrane entry mediated by the epithelial Na⁺ channel (ENaC) (Garty and Palmer, 1997). In addition to well-known endocrine regulation of ENaC through intracellular steroid receptors (Garty, 2000) and second messengers such as cAMP (Benos et al., 1996) and Ca²⁺ (Kunzelmann et al., 2001), a new means of regulation by extracellular proteases was recently described (Vallet et al., 1997) and referred to as channel activating protease (CAP) regulation of ENaC. CAP regulation of ENaC may play a role in a variety of physiological functions from blood pressure regulation (Snyder, 2002) to mucocilliary clearance in the airways (Boucher, 2004) and hearing (Rossier, 2004). Three putative CAPs, CAP1 (prostasin), CAP2 (TMPRSS4), and CAP3 (matriptase) that stimulate ENaC-mediated amiloride-sensitive Na⁺ transport (I_Na) in Xenopus oocytes have been cloned (Vuagniaux et al., 2002). These CAPs were predicted to be membrane-anchored proteins with extracellular serine protease domains. The importance of serine protease activity in ENaC regulation has been demonstrated in renal epithelial cell lines (Vallet et al., 1997; Nakhoul et al., 1998; Vuagniaux et al., 2000) and primary airway cells (Bridges et al., 2001; Donaldson et al., 2002) by serine protease inhibition.

Vallet et al. (2002) reported that both membrane anchoring and proteolytic activity were required for CAP1 activation of ENaC. However, the exogenous addition of chymotrypsin and trypsin have also been shown to stimulate I_Na in Xenopus oocytes (Chraibi et al., 1998), and trypsin stimulates I_Na in fibroblasts expressing ENaC (Caldwell et al., 2004). Recently, it was shown that the appearance of apparently smaller molecular weight forms of ENaC from MDCK cells heterologously expressing ENaC could be blocked by mutations that remove putative cleavage sites in ENaC and subunits for the protein convertase furin (Hughey et al., 2004). These mutations were associated with a significant decrease of I_Na in Xenopus oocytes expressing ENaC. Although exogenous proteases have no effect on the spontaneous I_Na in several native Na⁺ transporting epithelia, trypsin enhanced recovery of I_Na following inhibition by the serine protease inhibitors aprotinin and bikunin (Vallet et al., 1997; Bridges et al., 2001; Donaldson et al., 2002). Therefore, inhibition of the CAP pathway by specific protease inhibitors is sufficient to inhibit Na⁺ transport in numerous epithelia.

ENaC regulation by the CAP pathway could be mediated by changes in the single channel current (i_Na), the open probability (P_o), or the number of active channels (N_T). Studies using ENaC heterologously expressed in oocytes (Chraibi et al., 1998; Adachi et al., 2001) and fibroblasts (Caldwell et al., 2004) have yielded contradictory results in regards to how extracellular proteases regulate ENaC. In an effort to further clarify how ENaC is regulated by the CAP pathway we have used the amphibian renal epithelial cell line A6 and transepithelial current fluctuation analysis. Our results demonstrate that the protease inhibitor aprotinin reversibly inhibits I_Na. The decrease in I_Na was accompanied by a decrease in the number of open channels (N_o), an increase in i_Na, and a paradoxical increase in P_o. Because only the decrease in N_o can explain the decrease in I_Na we conclude that the CAP pathway regulates sodium transport by modulating the number of active ENaCs in the apical membrane.

	MATERIALS AND METHODS

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Cell Culture
A6 cells were maintained in amphibian medium (Biowhitaker) and 10% FBS (GIBCO BRL) in an incubator with humidified air and 4% CO₂ at 28°C as previously described (Rokaw et al., 1996). The cells were expanded on plastic tissue culture dishes and then seeded on Costar Transwell permeable supports (polycarbonate membrane of 0.4 µm pore size and 1 cm² area). Experiments were performed 14–21 d after seeding on the permeable supports and 24–48 h after media replacement.

Short-circuit Current (I_sc) Measurement
Costar Transwell cell culture inserts were mounted in Costar Ussing chambers and continuously voltage clamped to 0 mV with an automatic voltage clamp (Department of Bioengineering, University of Iowa). Four millivolt bipolar pulses were applied every minute, generating current deflections used to calculate the transepithelial resistance (R_T) with Ohms law. I_sc traces were digitized at 10 Hz and recorded using a DASA 6600 acquisition board and Acquire 6600 recording software (Gould Instrument System). The bath solution was identical in the apical and basolateral chambers and contained (in mM) 100 NaCl, 2.4 KHCO₃, 1 CaCl₂, 5 glucose. The pH of the solution was 8.0 when gassed with ambient air. All experiments were performed at room temperature.

Blocker-induced Fluctuation Analysis
A6 cells on Costar Transwell inserts were placed in Costar Ussing chambers and continuously short circuited with a low noise voltage clamp previously described (Van Driessche and Lindemann, 1978). The I_sc was high-pass filtered to remove the DC component and then subjected to anti-aliasing filtering and amplification. The resulting signal was digitized and Fourier transformed to generate power density spectra (PDS) normalized to the tissue surface area (Van Driessche and Lindemann, 1979). PDS were collected at 0.5 Hz fundamental frequency as averages of 30 sweeps over a frequency range of 0.5–350 Hz. The data was then fitted to a Lorentzian noise function S₀/(1 + (f/f_c)²) plus a "one over f" component defined as S1/f (Paunescu et al., 2000). "One over f" noise, also called flicker noise, is the excess noise that results from fluctuations in conductance of porous membranes held away from electrical equilibrium that decreases as 1/f (DeFelice, 1981). S1 is the low frequency power of the "one over f" noise with its decay characterized by ranging from 0.5 to 1.5. We determined the plateau power (S_o) and corner frequency (f_c) from fits of 44 data points in the 0.5–200 Hz range. Blocker-dependent parameters were determined as previously described (Helman and Baxendale, 1990; Els and Helman, 1997; Helman et al., 1998). We determined aprotinin-dependent changes in single channel parameters using two approaches; a cumulative 6-chloro-3,5-diaminopyrazine carboxamide (CDPC) concentration step and a pulse protocol (Helman et al., 1998). CDPC was chosen because its low affinity and high off rate (see below) permit measurements of Lorentzians at relatively uninhibited states and affords a number of experimental advantages. These advantages were well described by Helman and Baxendale (1990). First, low affinity CDPC blockade minimizes the poorly understood "autoregulatory" responses to significant current inhibition that occurs with higher affinity blockers. Second, CDPC permits simultaneous measurement of changes in steady-state current and blocker kinetics from spectral analysis necessary for the determination of the open probability from the three-state model. Third, a low affinity blocker by virtue of a high off rate reduces the relative error in the estimation of the off rate from the linear regression of the corner frequency versus blocker concentration.

The cumulative concentration step approach was performed by mounting A6 cells in a fixed bath volume (5 ml) where 4 µM aprotinin or PBS was added to the apical side. Apical and basolateral solutions were continuously mixed and oxygenated by a gas lift using air. After incubating in 4 µM aprotinin or PBS for 30 min, increasing doses of CDPC (in DMSO) were added to the apical bath to yield a cumulative increase in CDPC concentration. The concentrations used were 10, 20, 30, 40, and 50 µM CDPC. PDS were obtained 2 min after addition of each dose of CDPC and following establishment of a new steady-state I_sc. The ENaC-mediated Na⁺ current (I_Na) was taken as the I_sc before minus the I_sc remaining after addition of 10 µM amiloride and usually accounted for >90% of the I_SC. Blocker rate coefficients were calculated from the linear regression of 2f_c vs. blocker concentration using a pseudo-first order kinetic description where 2f_c = k_off + k_on · [B] (k_on and k_off are the apparent on- and off-coefficients of the blocker (B) interacting with the open channel) and the dissociation constant was calculated as K_d = k_off/k_on. For the pulse protocol, the Ussing chamber was modified to reduce the apical volume to 1.5 ml. The cells were continuously perfused at 5 ml/min with ringer containing 10 µM CDPC. At indicated time points, PDS were obtained, the solution was switched to one with 30 µM CDPC, PDS were again obtained, and then the solution was switched back to one with 10 µM CDPC. Three experimental periods were evaluated: (1) control, 30 min of perfusion without aprotinin; (2) aprotinin, 45 min of perfusion with a solution containing 10 µM aprotinin; and (3) washout, 30 min of perfusion without aprotinin. PDS were obtained at 10 and 30 µM CDPC at 10, 20, and 30 min of the control and washout periods and at 25, 35, and 45 min of the aprotinin period. The blocker rate coefficients were calculated from the two blocker concentrations and corner frequencies as:

where f_c(10) and f_c(30) are the corner frequencies at 10 and 30 µM CDPC and k_off = 2f_c(10) – k_on · 10 · µM. The single channel current amplitude (i_Na) was calculated as:

(1)

where I_Na is the amiloride-sensitive current thus allowing us to determine the number of open channels at 10 µM CPDC as N_o = I_Na(10)/i_Na. It has been extensively verified that CDPC and its analogs interact with ENaC-mediated amiloride-sensitive Na⁺ transport in a manner described satisfactorily by a three-state model (Lindemann and Van Driessche, 1978; Li and Lindemann, 1983; Abramcheck et al., 1985; Els and Helman, 1989, 1997; Helman and Baxendale, 1990; Els et al., 1991; Baxendale-Cox et al., 1997; Helman et al., 1998; Becchetti et al., 2002). The use of a closed-open blocked three-state model instead of two-state or more complicated four-state models is not the focus of this work and arguments for the use of a three-state model of CDPC blockade of I_Na in A6 cells can be found in Helman and Baxendale (1990) and Helman et al. (1998). Therefore, the open probability (P_o) was calculated assuming a three-state model where the blocker interacts with the open state using:

(2)

where I_Na(10) and I_Na(30) are the amiloride-sensitive current at 10 and 30 µM CDPC (Helman et al., 1998). The number of active channels (N_T) was calculated from

(3)

Cell Surface Biotinylation and Western Blot Analysis
Confluent A6 cell monolayers grown on permeable filters (Costar; 75 mm diameter) were treated with PBS, 10 µM aprotinin for 1 h, or 100 nM aldosterone for 6 h and then kept on ice. Cell surface biotinylation and Western blot analysis of ENaC subunits were performed according to the modified method as previously described (Gottardi et al., 1995; Hanwell et al., 2002). In brief, cells were washed three times in ice-cold PBS-CM (PBS with 1 mM MgCl₂ and 0.1 mM CaCl₂) and incubated with 1.5 mg/ml EZ-link Sulfo-NHS-S-S-biotin (Pierce Chemical Co.) in cold biotinylation buffer (10 mM triethanolamine, 2 mM CaCl₂, 150 mM NaCl, pH 9.0) with gentle agitation. Cells were washed once with quenching buffer (192 mM glycine, 25 mM Tris in PBS-CM) and incubated for 20 min with quenching buffer. Cells were then rinsed twice with PBS-CM, scraped in cold PBS, and pelleted at 2,000 rpm at 4°C. The cells were lysed in lysis buffer (1.0% Triton X-100, 150 mM NaCl, 5 mM EDTA, 50 mM Tris) and incubated on ice for 60 min before centrifugation (10 min at 14,000 g, 4°C). Supernatants were transferred to new tubes and protein concentration was determined with Coomassie plus protein assay kit (Pierce Chemical Co.). 750 µg of supernatant from each sample was incubated with 100 µl of 50% slurry of streptavidin–agarose beads for 2 h at 4°C. Beads were pelleted by brief centrifugation and then were washed three times with HNTG (20 mM HEPES, pH 7.5, 150 mM NaCl, 0.1% Triton X-100, 10% glycerol). Biotinylated proteins were eluted by boiling in sample buffer supplemented with 5% ß-mercaptoethanol. Proteins were separated on 4–20% SDS-PAGE and were transferred to Immobilon-P membranes (Millipore). Proteins were detected by Western blot with polyclonal antibodies against , ß, and ENaC subunits. ENaC antibodies were provided by C. Canessa (Yale University School of Medicine, New Haven, CT). The signal was developed with Supersignal west femto maximum sensitivity substrate (Pierce Chemical Co.) and detected with X-Omat Blue XB-1 imaging film (Kodak). Signal intensities were quantified with scanning densitometry (Bio-Rad Laboratories).

Statistical Analysis
Data points represent the mean of n individual experiments ± SEM. Statistical comparisons were performed with either unpaired t tests when comparing across experiments but paired t tests when comparing across conditions in the same cells. The P < 0.05 was considered significant. The P values are reported relative to 0.01 and 0.05 in the text and figure legends. Linear regressions were performed with Origin (Microcal). Nonlinear curve fittings were performed with Matlab (Mathworks).

Materials
Unless otherwise stated, all materials were obtained from Sigma-Aldrich.

	RESULTS

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Effect of Aprotinin on I_Na
Apical administration of 10 µM aprotinin resulted in a decrease of I_sc. Short circuit current traces of the effects of PBS and aprotinin on A6 cell sodium transport are shown in Fig. 1 (A and B). After a 25–30-min equilibration period following initiation of transepithelial voltage clamping, PBS or aprotinin was added to the apical side for 50 min followed by 10 µM amiloride to obtain a measure of net electrogenic sodium transport mediated by the amiloride-sensitive sodium channel ENaC (I_Na). We verified that under these experimental conditions >90% of the I_SC was amiloride sensitive (unpublished data). Thus any change in the I_SC can be attributed to a change in I_Na. The I_sc taken after the equilibration period is referred to as the control I_sc. As can be seen, aprotinin caused a time-dependent decrease in the I_SC that was not observed in the PBS (vehicle control) treated cells. The decrease in I_sc caused by aprotinin was apparent following a variable short lag phase of 30 s. In this subset of experiments, the PBS-treated monolayers had a control I_sc of 8.4 ± 1.36 µA/cm² (n = 12) that was not significantly changed (8.9 ± 1.08 µA/cm², P > 0.05) 50 min after addition of PBS but was reduced to 0.8 ± 0.13 µA/cm² upon addition of 10 µM amiloride. Parallel experiments with 10 µM aprotinin added to the apical side had control I_sc of 7.5 ± 1.25 µA/cm² (n = 12) that was reduced to 2.2 ± 0.55 µA/cm² (P < 0.01) 50 min after addition of aprotinin and further reduced to 0.5 ± 0.12 µA/cm² with the addition of 10 µM amiloride. Thus I_Na was reduced from 8.1 ± 1.1 µA/cm² in the PBS-treated cells to 1.7 ± 0.53 µA/cm² in the aprotinin-treated cells. These results are summarized in Fig. 1 C.

View larger version (17K): [in this window] [in a new window]   Figure 1. Effect of apically administered aprotinin on amiloride-sensitive ISC in A6 cell monolayers. A6 cells in Ussing chambers with symmetrical bath solutions continuously gassed with air were voltage clamped at 0 mV and ISC monitored. After a 25–30-min equilibration period (A) PBS or (B) aprotinin 10 µM was added to the apical bath. ISC was monitored for 50 min then 10 µM amiloride was added to the apical bath to determine INa. The current deflections are responses to 4 mV bipolar pulses used to measure transepithelial resistance. (C) The mean values of ISC before (shaded bar), 50 min after addition of PBS/aprotinin (hatched bars), and following addition of amiloride (filled bars) indicate substantial decrease of ISC by aprotinin. The error bars are ± SEM. Significant decrease was found in comparing ISC values before and 50 min following addition of aprotinin but not PBS with n = 12 and 14 filters for PBS and aprotinin experiments, respectively (*, P < 0.01).

View larger version (21K): [in this window] [in a new window]   Figure 2. Time and concentration dependence of the effect of aprotinin on INa. (A) INa after apical administration of PBS (filled squares) or 10 µM aprotinin (open circles) was plotted as a percentage of INa before administration (control) using data recorded at 5-min intervals. The data points plotted represent the mean values of 12 filters each for PBS and aprotinin addition with error bars corresponding to ± SEM. A small time-dependent increase in INa could be seen with PBS addition but was not consistently observed in all the filters measured. The solid line through the aprotinin data points represents a fit to an exponential decay % control INa = a*exp(–t/) + b ignoring the time = 0 data point. The constants a and b represent the percentage of INa sensitive and insensitive to 10 µM aprotinin, respectively. The mean control INa for the set of 24 filters used in this experiment was 8.2 ± 0.36 µA/cm2. (B) The % control INa was measured at 50 min after adding the indicated concentration 0, 1, 3, 6, 10 µM of aprotinin (filled squares) and demonstrated a concentration dependence to the aprotinin inhibition of INa. The solid line represents a fit to the inhibition curve % control = a*K1/2/K1/2 + [aprotinin] + b, where K1/2 is an inhibition constant; a and b represent the aprotinin sensitive and insensitive percentages of INa, respectively. The mean control INa for the set of 25 filters used in this experiment was 4.1 ± 0.30 µA/cm2. Error bars are ± SEM.

View larger version (16K): [in this window] [in a new window]   Figure 3. Aprotinin effect on blocker-induced fluctuation of INa in A6 cells. A6 cells in Ussing chambers were continuously voltage clamped at 0 mV and the ISC monitored on a strip chart for 30 min following addition of PBS (filled squares) or aprotinin 4 µM (open circles). Cumulative step increases in the concentration of CDPC in the apical bath were performed, the ISC and power density spectra were obtained at each blocker concentration 10, 20, 30, 40, and 50 µM. The values are given as the mean (n = 8 for PBS and n = 6 for aprotinin-treated A6 filters) ± SEM. (A) The INa following 30 min of PBS addition was significantly higher than INa following aprotinin addition (*, P < 0.01). In both conditions CDPC decreased the INa and the decrease could be explained by simple Michaelis-Menten inhibition kinetics (solid lines). (B) The So at increasing concentration of CDPC was biphasic and was fitted to a two-state channel blocking model (solid lines) in both cases. The difference in magnitude of So between PBS and aprotinin-treated A6 cells was significant (*, P < 0.01). (C) 2fc plots with linear regressions (solid lines) from which kon and koff were calculated were virtually identical for PBS and aprotinin-treated cells.

View larger version (17K): [in this window] [in a new window]   Figure 4. Typical current noise power spectral density in the absence (solid squares; 3.87 µA/cm2 INa) and presence (open squares; 1.67 µA/cm2 INa) of aprotinin are shown at 10 µM CDPC (A) and 30 µM CDPC (B). Corner frequencies were 47.6 and 50.2 Hz (A) (at 10 µM CDPC) in and 72.4 and 72.7 Hz (B) (at 30 µM CDPC) in the absence and presence of aprotinin, respectively. The solid lines represents the fit of the data to the sum of Lorentzian plus low frequency "1/f" noise.

View larger version (24K): [in this window] [in a new window]   Figure 5. Summary of the changes in the single channel parameters with aprotinin addition and reversal. (A) Summary of reduction in INa by aprotinin in the pulse protocol experiments. INa of cells continuously perfused with a ringer solution containing 10 µM CDPC was measured at 10-min intervals before addition of aprotinin (filled squares), then the cells were perfused with 10 µM aprotinin and INa measured at the indicated times (open squares) after which aprotinin was washed out (open triangles). At 10-min intervals, the CDPC concentration was pulsed to 30 µM and returned to 10 µM for analysis of blocker-induced fluctuations. (B) Summary of changes in iNa following perfusion of aprotinin and washout. The increase in iNa caused by aprotinin was significant (*, P < 0.01) and reversible. (C) Summary of changes in Po. The changes in Po were significant (*, P < 0.01) at 15 min after perfusing with aprotinin and returned to the pre-aprotinin control values following washout of aprotinin. (D) Summary of changes in No following aprotinin perfusion showed a significant decrease in No (*, P < 0.01) that was completely reversed upon removal of aprotinin. Values are reported as mean ± SEM for n = 8.

View larger version (20K): [in this window] [in a new window]   Figure 6. NT calculated from the Po and Kd decreased by 80% following 35 min of inhibition by aprotinin (open squares) compared with control conditions (solid squares). Inhibition of NT was reversed following washout of aprotinin (open triangles) and returned to control values within 30 min of washout.

View larger version (16K): [in this window] [in a new window]   Figure 7. Relationship of single channel parameters to INa. Individual values of (A) iNa, (B) Po, and (C) No under control conditions (filled squares) and during aprotinin treatment (open squares) plotted against INa. The data points from the wash conditions have been omitted for clarity. The lines are linear regressions to the control period data (solid line) and aprotinin period data (dotted line). The regressions for all three periods are summarized in Table I.

View larger version (26K): [in this window] [in a new window]   Figure 8. The effect of aprotinin and aldosterone on the relative abundance of ENaC subunits in the apical membrane of A6 cells. (A) A6 cells grown on permeable supports were treated either with PBS or 10 µM aprotinin for 1 h or 100 nM aldosterone for 6 h. Apical proteins were biotinylated and recovered with streptavidin–agarose beads. The recovered proteins were analyzed with antibodies against , ß, and Xenopus ENaC subunits. Representative Western blots are shown with the arrows indicating the migration of molecular mass standards. (B) Mean of relative changes in apical membrane abundance measured by scanning densitometry and normalized to the control density. The bars represent three independent experiments with error bars corresponding to ±SEM.

	DISCUSSION

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Kallikrein-like protease activity has been identified at the apical surface and in the apical medium of A6 cells forming a tight monolayer as well as from toad urinary bladder (Jovov et al., 1990). The kallikrein-like protease activity was inhibited by aprotinin at a concentration that inhibited Na⁺ transport in A6 cells and toad bladder (Margolius and Chao, 1980). Further, exogenous addition of trypsin and chymotrypsin have been shown to activate I_Na in epithelia pretreated with protease inhibitors and activate Na⁺-mediated currents in Xenopus oocytes expressing ENaC (Vallet et al., 1997; Bridges et al., 2001; Donaldson et al., 2002; Liu et al., 2002). Vallet et al. (1997), using expression cloning methods, identified a channel activating protease (CAP) from A6 cells that increased ENaC-mediated I_Na in Xenopus oocytes. The mammalian homologue of xCAP1 is prostasin/hCAP1 and coexpression of prostatin with ENaC also increases Na⁺-mediated currents (Vuagniaux et al., 2000; Adachi et al., 2001). Similar to the secretion of kallikrein-like proteases by amphibian renal cells, prostasin has been found to be secreted in an aldosterone-regulated manner in rat urine (Narikiyo et al., 2002). Bikunin, a Kunitz type serine protease inhibitor with two Kunitz domains, has a submicromolar potency for inhibiting Na⁺ transport in human bronchial epithelia (Bridges et al., 2001) and this correlates with the nanomolar inhibition constant reported for aprotinin inhibition of prostasin enzymatic activity in vitro (Shipway et al., 2004). These findings support the idea that prostasin and CAP1 are endogenous proteases that can regulate epithelial Na⁺ transport. Consistent with this view is that RNA silencing of CAP1 was sufficient to inhibit I_Na in the CF15 airway epithelial cell line to the extent observed with aprotinin on A6 and HBE cells (Tong et al., 2004). Expression cloning has identified two other such CAPs in mammalian renal cells that are capable of stimulating current in Xenopus oocytes coexpressing ENaC in an aprotinin-sensitive manner (Vuagniaux et al., 2002). Another possible protease that may regulate Na⁺ transport is the ubiquitous convertase furin, which modulated ENaC-mediated currents in the Chinese hamster ovary expression system (Hughey et al., 2004). However furin is not inhibited by aprotinin; consequently, the aprotinin inhibition of I_Na cannot be attributed to a furin pathway of channel activation in A6 cells and human bronchial epithelia. The relative importance of the individual proteases and the mechanism of their action in regulating Na⁺ transport are yet to be determined. The studies reported here were designed to investigate the mechanism of action of aprotinin inhibition of epithelial Na⁺ transport and thereby how aprotinin-sensitive proteases regulate Na⁺ transport.

Single Channel Properties
Na⁺ transport is a function of the single channel properties and can be expressed as I_Na = N_T*P_o*i_Na. Using noise analysis we studied the apical Na⁺ channels in the presence and absence of aprotinin and found that the decrease in I_Na caused by aprotinin can be explained by a decrease in the number of open channels (N_o) and these effects of aprotinin were fully reversible upon aprotinin washout. In contrast, aprotinin caused both i_Na and P_o to increase, and thus these changes cannot account for the decrease in I_Na. The i_Na averaged 0.45 pA under control conditions in the present study, which is similar to previously reported values in short-circuited A6 cells by noise analysis (Helman et al., 1998; Alvarez de la Rosa et al., 2004). Given the i_Na of 0.45 pA under control conditions and a single channel conductance of 4–6 pS for the highly selective Na⁺ channel in A6 cells (Palmer, 1992; Puoti et al., 1995), a driving force of 90 mV can be estimated for apical Na⁺ entry. A 90-mV effective electromotive force for Na⁺ movement across the apical membrane has been reported in A6 cell monolayers with resistances and I_Na in the range that we have measured (Granitzer et al., 1991). The average i_Na presented here is therefore consistent with the characteristic driving forces across the apical membrane of A6 cell monolayers and the conductance of sodium channels. Application of aprotinin to the apical bath caused a significant increase in i_Na. Therefore, the inhibition of I_Na by aprotinin cannot be explained by changes in i_Na. By definition, N_o = N_T*P_o, where N_T is the number of electrically detectable or active channels gating between the open and closed states. A decrease in N_o may arise from a decrease in N_T or a decrease in P_o of the active channels. The P_o of active channels at the apical membrane was measured and in the control condition averaged 0.2. This value of P_o is well within the range that has been measured by noise analysis and patch clamping for ENaC (Helman and Kizer, 1990). With application of aprotinin, the P_o doubled. The increase in P_o would be expected to increase N_o and I_Na; however, aprotinin causes a reduction in N_o and I_Na. Therefore, aprotinin inhibition of I_Na is explained by a decrease in N_T (Fig. 5).

To further elucidate the relationship between I_Na and the single channel properties we examined the individual data points from our pulse-protocol experiments. Considering the control conditions, we found a weak negative correlation between i_Na and I_Na. A negative correlation is expected because increased Na⁺ transport rates depolarize the cells, reducing the electromotive force across the Na⁺ channels (Granitzer et al., 1992; Blazer-Yost and Helman, 1997). The strength of the correlation is expected to be weak because the driving force across the apical membrane is variable due in part to a high variation in the basolateral resistance from one monolayer to another (Granitzer et al., 1991). Following apical administration of aprotinin, the negative correlation between i and I_Na became stronger. Such a correlation cannot explain the decrease in I_Na. It however suggests that the effect on i_Na is not simply due to the presence of aprotinin but follows the amount of inhibition of I_Na caused by the presence of aprotinin. It was found that a negative correlation occurs between the ratio I_Na^control/I_Na^aprotinin and i_Na^control/i_Na^aprotinin, thereby confirming that inhibition of I_Na by aprotinin produces the steep inverse relationship seen in the presence of aprotinin. In a similar manner, the P_o from cells under control conditions showed significant variation but a weak negative correlation was evident. This increasing P_o with decreasing I_Na may be related to a previously reported hyperpolarization-induced increase in ENaC P_o (Palmer and Frindt, 1988, 1996). As observed in the case of i_Na, with aprotinin treatment, the negative correlation between P_o and I_Na was intensified, supporting the notion that the P_o change accompanies the decreasing I_Na and is not simply due to the presence of aprotinin. For N_o, we found a strong positive correlation with I_Na both in the control condition and the in the presence of aprotinin. Since the apical conductance has been shown to be strongly positively correlated with I_Na in A6 cells (Granitzer et al., 1991; Helman and Liu, 1997) and the apical conductance is in large part given by the product of N_o and the single channel conductance, it is expected that under control conditions N_o would have a positive correlation with I_Na. This correlation persists following treatment with aprotinin. The decrease in I_Na following aprotinin treatment is only explained by a decrease in N_o that results from a decrease in N_T.

Mechanism of Inhibition of N_T by Aprotinin
Out of several possible explanations for the decrease in N_T caused by aprotinin, an intriguing explanation is that at the apical membrane there is a turnover of active channels into inactive channels in the presence of aprotinin. The inactive channels can be considered to be "capped" while the active channels are "uncapped." Because multiple proteases have been shown to increase ENaC activity in a variety of systems in a manner dependent on their proteolytic activity, it is possible that ENaC is the substrate for proteolytic uncapping. Alternatively, ENaC uncapping may occur through proteolysis of a closely associated ENaC regulatory protein, proteolytic generation of a stimulatory ligand, protein–protein interactions of ENaC extracellular domain and the protease, or through generation of intracellular second messengers. Activation of the trypsin receptor protease-activated receptor 2 (PAR2) does not stimulate ENaC (Danahay et al., 2001) and ENaC activation is independent of PAR2 (Chraibi et al., 1998). Furthermore, ENaC activation by serine proteases is independent of G protein–coupled receptors in oocytes (Chraibi et al., 1998) and fibroblasts (Caldwell et al., 2004), yet to date all known PARs are G protein–coupled receptors. There is no finding to support an intracellular second messenger requirement for the protease-mediated uncapping of ENaC. Protein–protein interactions in the extracytoplasmic domain between the protease dipeptidyl aminopeptidase-like protein, DPPX, and neuronal A-type K⁺ channels has been implicated in the redistribution of the neuronal channels from the ER to the plasma membrane as well as in the regulation of channel gating (Nadal et al., 2003). The function of DPPX is not associated with proteolytic activity; however it remains to be determined that the protease-like domain is required for DPPX channel-regulating activity. It is difficult to imagine that apically administered aprotinin is rapidly trafficked to the ER where it disrupts a possible DPPX-like interaction of ENaC with a serine protease or that once disrupted, reconstitution and trafficking occur on the time scale observed with exogenous protease reactivation of aprotinin inhibited I_Na in epithelia cells. Trafficking from a compartment closer to the apical membrane or direct activation by the protein–protein interaction may cause the uncapping event. If aprotinin inhibits a protease-dependent trafficking of ENaC to the apical membrane from intracellular pools, then the physical channel density is expected to decrease. The quantitation of apical membrane ENaC subunits by cell surface biotinylation, however, shows that the steady-state densities of , ß, and subunits were unchanged in the presence of aprotinin. Thus it appears unlikely that aprotinin mediates ENaC trafficking to alter steady-state sodium current in A6 cells. Recent investigations suggest that the biochemically detected apical membrane protein subunit density may be one to two orders of magnitude greater than electrically detectable channels (Alvarez de la Rosa et al., 2004). Although the aldosterone-mediated changes in subunit density and I_SC are detectable, a similar correlation could not be detected for the aprotinin-mediated changes in I_Na. These results may mean aprotinin does not alter cell surface expression of ENaC subunit or that any changes are beyond the resolution of present biochemical methods. The high level of subunit protein at the apical surface would also impair the detection of proteolytically cleaved ENaC subunits.

There is, however, some evidence to support the idea that uncapping may occur through proteolysis of ENaC. A low apparent molecular weight form of the subunit immunoreactive band on Western blots was induced by aldosterone (Masilamani et al., 1999). The new size was consistent with excision of an amino-terminal region immediately after the first transmembrane domain. Aldosterone up-regulation of CAP1 (Narikiyo et al., 2002) and subsequent ENaC cleavage may explain the observations by Masilamani et al. (1999). Molecular weight reductions attributable to proteolytic cleavages in and subunits in MDCK cells expressing ENaC were recently reported and found critical for channel activity (Hughey et al., 2003, 2004). In A6 cells, a fast and slow migrating ENaC immunoreactive band has been reported with the fast form seen primarily at the apical membrane (Alvarez de la Rosa et al., 2002). However, this fast migrating band form appears to result from the formation of stable disulfide bonds following maturation. Although extensive processing of ENaC resulting in the change of the apparent molecular weight of its subunits have been observed, the data remains inconclusive as to whether ENaC is proteolytically cleaved in A6 cells and whether the cleavage results in the phenomenon we term uncapping. Independent of the mechanism, protease-mediated uncapping was apparently irreversible in oocyte studies, suggesting that channels cannot be recapped (Chraibi et al., 1998).

A simple hypothesis that explains aprotinin inhibition of I_Na is that endocytosis of uncapped channels (i.e., active channels) is responsible for the loss of current in the presence of aprotinin, as aprotinin prevents the uncapping of capped channels (i.e., inactive channels) newly inserted into the apical membrane. The half-life (11–17 min) measured for the , ß, and ENaC subunits in the A6 apical membrane (Alvarez de la Rosa et al., 2002) is in good agreement with the time constant (18 min) for the decay in I_Na following administration of aprotinin. Taking changes in I_Na as a measure of the changes in N_T, the decrease is consistent with the retrieval of active channels from the apical membrane. This implies that aprotinin prevents a constitutive replacement of active channels while retrieval of already activated channels continues leading to an apparent turnover of uncapped channels into capped channels. If this notion is correct, aprotinin should not cause a change in cell surface protein subunit density, an expectation consistent with the biotinylation studies shown in Fig. 8. However, much higher half-life values have been reported for ENaC subunits (>24 h for and , 6 h for ß) in the apical membrane of A6 cells (Weisz et al., 2000; Kleyman et al., 2001). The discrepancies in the measurements of ENaC subunit half-lives at the apical membrane are yet to be resolved. Since subunit half-life measurements do not necessarily correlate with the actual half-life of an active channel, we emphasize that the remarkable agreement of the estimate of the time constant for the inhibition of I_Na by aprotinin with the biochemical half-life observed by Alvarez de la Rosa et al. (2002) provides a working hypothesis whereby we can test the requirement of trafficking in the regulation of ENaC by endogenous proteases.

A protease-mediated uncapping that increases the N_T is at odds with recent findings that trypsin stimulates increases in "NP_o," which is equivalent to N_o (Caldwell et al., 2004). However, the increase in NP_o was only demonstrated for channels with very low NP_o resulting in 10–100-fold increases of NP_o. Inhibition by aprotinin did not reveal the presence of these 100-fold lower P_o "near-silent" channels. If these very low P_O channels were present in the absence or in the presence of aprotinin, they probably contribute a very small fraction to the total I_Na. If the near-silent channels are present, they do not explain the aprotinin-insensitive current and would not be detected in the presence of high P_o channels remaining in the membrane. From the perspective of transepithelial blocker–induced fluctuation analysis, the near-silent channels if present are virtually inactive. Consequently, the reduction of N_T measured here is not inconsistent with a turnover of channels with high P_o to near-silent channels in the presence of aprotinin. However, our results suggest that the higher P_o channels observed in the presence of aprotinin results either from functional heterogeneity of the Na⁺ channels in the apical membrane or from compensatory increases in the P_O of active channels remaining in the membrane.

In conclusion, our data suggest there is an aprotinin-sensitive protease in the apical membrane that serves to uncap newly inserted inactive ENaC channels. It remains of interest to show whether the size of the uncapped (active) channel pool is regulated by direct proteolytic activation of apical membrane channels or via the proteolysis of coprotein(s) that in turn regulate channel activity. The possible involvement of intermediate second messengers in the protease-mediated regulation of ENaC channels will also require further investigation.

	ACKNOWLEDGMENTS

 
We are grateful to W. Van Driessche (K.U. Leuven, Leuven, Belgium) for providing the A6 cells.

This work was supported by National Institutes of Health grants R01-IR01DK61639 (to R. Bridges) and NRSA-F31DK015311 (to A. Adebamiro) and by the UNCF-Merck graduate research fellowship award (to A. Adebamiro).

Olaf S. Andersen served as editor.

Submitted: 11 March 2005
Accepted: 18 August 2005

	REFERENCES

Top ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 

Abramcheck, F.J., W. Van Driessche, and S.I. Helman. 1985. Autoregulation of apical membrane Na⁺ permeability of tight epithelia. Noise analysis with amiloride and CGS 4270. J. Gen. Physiol. 85:555–582.[Abstract/Free Full Text]

Adachi, M., K. Kitamura, T. Miyoshi, T. Narikiyo, K. Iwashita, N. Shiraishi, H. Nonoguchi, and K. Tomita. 2001. Activation of epithelial sodium channels by prostasin in Xenopus oocytes. J. Am. Soc. Nephrol. 12:1114–1121.[Abstract/Free Full Text]

Alvarez de la Rosa, D., H. Li, and C.M. Canessa. 2002. Effects of aldosterone on biosynthesis, traffic, and functional expression of epithelial sodium channels in A6 cells. J. Gen. Physiol. 119:427–442.[Abstract/Free Full Text]

Alvarez de la Rosa, D., T.G. Paunescu, W.J. Els, S.I. Helman, and C.M. Canessa. 2004. Mechanisms of regulation of epithelial sodium channel by SGK1 in A6 cells. J. Gen. Physiol. 124:395–407.[Abstract/Free Full Text]

Baxendale-Cox, L.M., R.L. Duncan, X. Liu, K. Baldwin, W.J. Els, and S.I. Helman. 1997. Steroid hormone-dependent expression of blocker-sensitive ENaCs in apical membranes of A6 epithelia. Am. J. Physiol. 273:C1650–C1656.[Medline]

Becchetti, A., B. Malik, G. Yue, P. Duchatelle, O. Al-Khalili, T.R. Kleyman, and D.C. Eaton. 2002. Phosphatase inhibitors increase the open probability of ENaC in A6 cells. Am. J. Physiol. Renal Physiol. 283:F1030–F1045.[Abstract/Free Full Text]

Benos, D.J., M.S. Awayda, B.K. Berdiev, A.L. Bradford, C.M. Fuller, O. Senyk, and I.I. Ismailov. 1996. Diversity and regulation of amiloride-sensitive Na⁺ channels. Kidney Int. 49:1632–1637.[Medline]

Blazer-Yost, B.L., and S.I. Helman. 1997. The amiloride-sensitive epithelial Na⁺ channel: binding sites and channel densities. Am. J. Physiol. 272:C761–C769.[Medline]

Boucher, R.C. 2004. New concepts of the pathogenesis of cystic fibrosis lung disease. Eur. Respir. J. 23:146–158.[Abstract/Free Full Text]

Bridges, R.J., B.B. Newton, J.M. Pilewski, D.C. Devor, C.T. Poll, and R.L. Hall. 2001. Na⁺ transport in normal and CF human bronchial epithelial cells is inhibited by BAY 39-9437. Am. J. Physiol. Lung Cell. Mol. Physiol. 281:L16–L23.[Abstract/Free Full Text]

Caci, E., C. Folli, O. Zegarra-Moran, T. Ma, M.F. Springsteel, R.E. Sammelson, M.H. Nantz, M.J. Kurth, A.S. Verkman, and L.J. Galietta. 2003. CFTR activation in human bronchial epithelial cells by novel benzoflavone and benzimidazolone compounds. Am. J. Physiol. Lung Cell. Mol. Physiol. 285:L180–L188.[Abstract/Free Full Text]

Caldwell, R.A., R.C. Boucher, and M.J. Stutts. 2004. Serine protease activation of near-silent epithelial Na⁺ channels. Am. J. Physiol. Cell Physiol. 286:C190–C194.[Abstract/Free Full Text]

Chraibi, A., and J.D. Horisberger. 2002. Na self inhibition of human epithelial Na channel: temperature dependence and effect of extracellular proteases. J. Gen. Physiol. 120:133–145.[Abstract/Free Full Text]

Chraibi, A., V. Vallet, D. Firsov, S.K. Hess, and J.D. Horisberger. 1998. Protease modulation of the activity of the epithelial sodium channel expressed in Xenopus oocytes. J. Gen. Physiol. 111:127–138.[Abstract/Free Full Text]

Danahay, H., L. Withey, C.T. Poll, S.F. van de Graaf, and R.J. Bridges. 2001. Protease-activated receptor-2-mediated inhibition of ion transport in human bronchial epithelial cells. Am. J. Physiol. Cell Physiol. 280:C1455–C1464.[Abstract/Free Full Text]

DeFelice, L.J. 1981. Introduction to Membrane Noise. Plenum Press, New York. 257 pp.

Donaldson, S.H., A. Hirsh, D.C. Li, G. Holloway, J. Chao, R.C. Boucher, and S.E. Gabriel. 2002. Regulation of the epithelial sodium channel by serine proteases in human airways. J. Biol. Chem. 277:8338–8345.[Abstract/Free Full Text]

Els, W.J., and S.I. Helman. 1989. Regulation of epithelial sodium channel densities by vasopressin signalling. Cell. Signal. 1:533–539.[CrossRef][Medline]

Els, W.J., and S.I. Helman. 1997. Dual role of prostaglandins (PGE2) in regulation of channel density and open probability of epithelial Na⁺ channels in frog skin (R. pipiens). J. Membr. Biol. 155:75–87.[CrossRef][Medline]

Els, W.J., S.I. Helman, and T. Mencio. 1991. Activation of epithelial Na channels by hormonal and autoregulatory mechanisms of action. J. Gen. Physiol. 98:1197–1220.[Abstract/Free Full Text]

Garty, H. 2000. Regulation of the epithelial Na⁺ channel by aldosterone: open questions and emerging answers. Kidney Int. 57:1270–1276.[CrossRef][Medline]

Garty, H., and L.G. Palmer. 1997. Epithelial sodium channels: function, structure, and regulation. Physiol. Rev. 77:359–396.[Abstract/Free Full Text]

Gottardi, C.J., L.A. Dunbar, and M.J. Caplan. 1995. Biotinylation and assessment of membrane polarity: caveats and methodological concerns. Am. J. Physiol. 268:F285–F295.[Medline]

Granitzer, M., T. Leal, W. Nagel, and J. Crabbe. 1991. Apical and basolateral conductance in cultured A6 cells. Pflugers Arch. 417:463–468.[CrossRef][Medline]

Granitzer, M., W. Nagel, and J. Crabbe. 1992. Basolateral membrane conductance in A6 cells: effect of high sodium transport rate. Pflugers Arch. 420:559–565.[CrossRef][Medline]

Hanwell, D., T. Ishikawa, R. Saleki, and D. Rotin. 2002. Trafficking and cell surface stability of the epithelial Na⁺ channel expressed in epithelial Madin-Darby canine kidney cells. J. Biol. Chem. 277:9772–9779.[Abstract/Free Full Text]

Helman, S.I., and L.M. Baxendale. 1990. Blocker-related changes of channel density. Analysis of a three-state model for apical Na channels of frog skin. J. Gen. Physiol. 95:647–678.[Abstract/Free Full Text]

Helman, S.I., and N.L. Kizer. 1990. Apical Sodium Ion Channels of Tight Epithelia as Viewed from the Perspective of Noise Analysis. Vol. 37. Academic Press, San Diego. 117–155.

Helman, S.I., and X. Liu. 1997. Substrate-dependent expression of Na⁺ transport and shunt conductance in A6 epithelia. Am. J. Physiol. 273:C434–C441.[Medline]

Helman, S.I., X. Liu, K. Baldwin, B.L. Blazer-Yost, and W.J. Els. 1998. Time-dependent stimulation by aldosterone of blocker-sensitive ENaCs in A6 epithelia. Am. J. Physiol. 274:C947–C957.[Medline]

Hughey, R.P., J.B. Bruns, C.L. Kinlough, K.L. Harkleroad, Q. Tong, M.D. Carattino, J.P. Johnson, J.D. Stockand, and T.R. Kleyman. 2004. Epithelial sodium channels are activated by furin-dependent proteolysis. J. Biol. Chem. 279:18111–18114.[Abstract/Free Full Text]

Hughey, R.P., G.M. Mueller, J.B. Bruns, C.L. Kinlough, P.A. Poland, K.L. Harkleroad, M.D. Carattino, and T.R. Kleyman. 2003. Maturation of the epithelial Na⁺ channel involves proteolytic processing of the - and -subunits. J. Biol. Chem. 278:37073–37082.[Abstract/Free Full Text]

Jovov, B., N.K. Wills, P.J. Donaldson, and S.A. Lewis. 1990. Vectorial secretion of a kallikrein-like enzyme by cultured renal cells. I. General properties. Am. J. Physiol. 259:C869–C882.[Medline]

Kleyman, T.R., J.B. Zuckerman, P. Middleton, K.A. McNulty, B. Hu, X. Su, B. An, D.C. Eaton, and P.R. Smith. 2001. Cell surface expression and turnover of the -subunit of the epithelial sodium channel. Am. J. Physiol. Renal Physiol. 281:F213–F221.[Abstract/Free Full Text]

Kunzelmann, K., R. Schreiber, and A. Boucherot. 2001. Mechanisms of the inhibition of epithelial Na⁺ channels by CFTR and purinergic stimulation. Kidney Int. 60:455–461.[CrossRef][Medline]

Li, J.H., and B. Lindemann. 1983. Competitive blocking of epithelial sodium channels by organic cations: the relationship between macroscopic and microscopic inhibition constants. J. Membr. Biol. 76:235–251.[CrossRef][Medline]

Li, J.H., L.G. Palmer, I.S. Edelman, and B. Lindemann. 1982. The role of sodium-channel density in the natriferic response of the toad urinary bladder to an antidiuretic hormone. J. Membr. Biol. 64:77–89.[CrossRef][Medline]

Lindemann, B., and W. Van Driessche. 1978. The mechanism of Na uptake through Na-selective channels in the epithelium of frog skin. Membrane Transport Processes. 1:155–179.

Liu, L., K.S. Hering-Smith, F.R. Schiro, and L.L. Hamm. 2002. Serine protease activity in m-1 cortical collecting duct cells. Hypertension. 39:860–864.[Abstract/Free Full Text]

Margolius, H.S., and J. Chao. 1980. Amiloride inhibits mammalian renal kallikrein and a kallikrein-like enzyme from toad bladder and skin. J. Clin. Invest. 65:1343–1350.[Medline]

Masilamani, S., G.H. Kim, C. Mitchell, J.B. Wade, and M.A. Knepper. 1999. Aldosterone-mediated regulation of ENaC , ß, and subunit proteins in rat kidney. J. Clin. Invest. 104:R19–R23.[Medline]

Nadal, M.S., A. Ozaita, Y. Amarillo, E. Vega-Saenz de Miera, Y. Ma, W. Mo, E.M. Goldberg, Y. Misumi, Y. Ikehara, T.A. Neubert, and B. Rudy. 2003. The CD26-related dipeptidyl aminopeptidase-like protein DPPX is a critical component of neuronal A-type K⁺ channels. Neuron. 37:449–461.[CrossRef][Medline]

Nakhoul, N.L., K.S. Hering-Smith, C.T. Gambala, and L.L. Hamm. 1998. Regulation of sodium transport in M-1 cells. Am. J. Physiol. 275:F998–F1007.[Medline]

Narikiyo, T., K. Kitamura, M. Adachi, T. Miyoshi, K. Iwashita, N. Shiraishi, H. Nonoguchi, L.M. Chen, K.X. Chai, J. Chao, and K. Tomita. 2002. Regulation of prostasin by aldosterone in the kidney. J. Clin. Invest. 109:401–408.[CrossRef][Medline]

Orce, G.G., G.A. Castillo, and H.S. Margolius. 1980. Inhibition of short-circuit current in toad urinary bladder by inhibitors of glandular kallikrein. Am. J. Physiol. 239:F459–F465.[Medline]

Palmer, L.G. 1992. Epithelial Na channels: function and diversity. Annu. Rev. Physiol. 54:51–66.[CrossRef][Medline]

Palmer, L.G., and G. Frindt. 1988. Conductance and gating of epithelial Na channels from rat cortical collecting tubule. Effects of luminal Na and Li. J. Gen. Physiol. 92:121–138.[Abstract/Free Full Text]

Palmer, L.G., and G. Frindt. 1996. Gating of Na channels in the rat cortical collecting tubule: effects of voltage and membrane stretch. J. Gen. Physiol. 107:35–45.[Abstract/Free Full Text]

Paunescu, T.G., B.L. Blazer-Yost, C.J. Vlahos, and S.I. Helman. 2000. LY-294002-inhibitable PI 3-kinase and regulation of baseline rates of Na⁺ transport in A6 epithelia. Am. J. Physiol. Cell Physiol. 279:C236–C247.[Abstract/Free Full Text]

Planes, C., C. Leyvraz, T. Uchida, M.A. Angelova, G. Vuagniaux, E. Hummler, M.A. Matthay, C. Clerici, and B.C. Rossier. 2005. In vitro and in vivo regulation of transepithelial lung alveolar sodium transport by serine proteases. Am J Physiol Lung Cell Mol Physiol. 288:L1099–L1109.[Abstract/Free Full Text]

Puoti, A., A. May, C.M. Canessa, J.D. Horisberger, L. Schild, and B.C. Rossier. 1995. The highly selective low-conductance epithelial Na channel of Xenopus laevis A6 kidney cells. Am. J. Physiol. 269:C188–C197.[Medline]

Rokaw, M.D., D.J. Benos, P.M. Palevsky, S.A. Cunningham, M.E. West, and J.P. Johnson. 1996. Regulation of a sodium channel-associated G-protein by aldosterone. J. Biol. Chem. 271:4491–4496.[Abstract/Free Full Text]

Rossier, B.C. 2004. The epithelial sodium channel: activation by membrane-bound serine proteases. Proc. Am. Thorac. Soc. 1:4–9.[Abstract/Free Full Text]

Shipway, A., H. Danahay, J.A. Williams, D.C. Tully, B.J. Backes, and J.L. Harris. 2004. Biochemical characterization of prostasin, a channel activating protease. Biochem. Biophys. Res. Commun. 324:953–963.[CrossRef][Medline]

Snyder, P.M. 2000. Liddle's syndrome mutations disrupt cAMP-mediated translocation of the epithelial Na⁺ channel to the cell surface. J. Clin. Invest. 105:45–53.[Medline]

Snyder, P.M. 2002. The epithelial Na⁺ channel: cell surface insertion and retrieval in Na⁺ homeostasis and hypertension. Endocr. Rev. 23:258–275.[Abstract/Free Full Text]

Snyder, P.M., D.B. Bucher, and D.R. Olson. 2000. Gating induces a conformational change in the outer vestibule of ENaC. J. Gen. Physiol. 116:781–790.[Abstract/Free Full Text]

Tang, J., F.J. Abramcheck, W. Van Driessche, and S.I. Helman. 1985. Electrophysiology and noise analysis of K⁺-depolarized epithelia of frog skin. Am. J. Physiol. 249:C421–C429.[Medline]

Tong, Z., B. Illek, V.J. Bhagwandin, G.M. Verghese, and G.H. Caughey. 2004. Prostasin, a membrane-anchored serine peptidase, regulates sodium currents in JME/CF15 cells, a cystic fibrosis airway epithelial cell line. Am. J. Physiol. Lung Cell. Mol. Physiol. 287:L928–L935.[Abstract/Free Full Text]

Vallet, V., A. Chraibi, H.P. Gaeggeler, J.D. Horisberger, and B.C. Rossier. 1997. An epithelial serine protease activates the amiloride-sensitive sodium channel. Nature. 389:607–610.[CrossRef][Medline]

Vallet, V., C. Pfister, J. Loffing, and B.C. Rossier. 2002. Cell-surface expression of the channel activating protease xCAP-1 is required for activation of ENaC in the Xenopus oocyte. J. Am. Soc. Nephrol. 13:588–594.[Abstract/Free Full Text]

Van Driessche, W., and B. Lindemann. 1978. Low-noise amplification of voltage and current fluctuations arising in epithelia. Rev. Sci. Instrum. 49:53–57.[Medline]

Van Driessche, W., and B. Lindemann. 1979. Concentration dependence of currents through single sodium-selective pores in frog skin. Nature. 282:519–520.[CrossRef][Medline]

Vogel, R., and E. Werle. 1970. Handbook of Experimental Pharmacology. Bradykinin, Kallidin, and Kallikrein. Vol. 25. Springer, Berlin. 213–249.

Vuagniaux, G., V. Vallet, N.F. Jaeger, E. Hummler, and B.C. Rossier. 2002. Synergistic activation of ENaC by three membrane-bound channel-activating serine proteases (mCAP1, mCAP2, and mCAP3) and serum- and glucocorticoid-regulated kinase (Sgk1) in Xenopus oocytes. J. Gen. Physiol. 120:191–201.[Abstract/Free Full Text]

Vuagniaux, G., V. Vallet, N.F. Jaeger, C. Pfister, M. Bens, N. Farman, N. Courtois-Coutry, A. Vandewalle, B.C. Rossier, and E. Hummler. 2000. Activation of the amiloride-sensitive epithelial sodium channel by the serine protease mCAP1 expressed in a mouse cortical collecting duct cell line. J. Am. Soc. Nephrol. 11:828–834.[Abstract/Free Full Text]

Weisz, O.A., J.M. Wang, R.S. Edinger, and J.P. Johnson. 2000. Non-coordinate regulation of endogenous epithelial sodium channel (ENaC) subunit expression at the apical membrane of A6 cells in response to various transporting conditions. J. Biol. Chem. 275:39886–39893.[Abstract/Free Full Text]

CiteULike    Complore    Connotea    Del.icio.us    Digg    Facebook    Reddit    Technorati    Twitter    What's this?

This article has been cited by other articles:

				A. Lazrak, I. Nita, D. Subramaniyam, S. Wei, W. Song, H.-L. Ji, S. Janciauskiene, and S. Matalon {alpha}1-Antitrypsin Inhibits Epithelial Na+ Transport In Vitro and In Vivo Am. J. Respir. Cell Mol. Biol., September 1, 2009; 41(3): 261 - 270. [Abstract] [Full Text] [PDF]

				M. B. Butterworth, R. S. Edinger, R. A. Frizzell, and J. P. Johnson Regulation of the epithelial sodium channel by membrane trafficking Am J Physiol Renal Physiol, January 1, 2009; 296(1): F10 - F24. [Abstract] [Full Text] [PDF]

				G. Fejes-Toth, G. Frindt, A. Naray-Fejes-Toth, and L. G. Palmer Epithelial Na+ channel activation and processing in mice lacking SGK1 Am J Physiol Renal Physiol, June 1, 2008; 294(6): F1298 - F1305. [Abstract] [Full Text] [PDF]

				N. Picard, D. Eladari, S. El Moghrabi, C. Planes, S. Bourgeois, P. Houillier, Q. Wang, M. Burnier, G. Deschenes, M. A. Knepper, et al. Defective ENaC Processing and Function in Tissue Kallikrein-deficient Mice J. Biol. Chem., February 22, 2008; 283(8): 4602 - 4611. [Abstract] [Full Text] [PDF]

				A. Adebamiro, Y. Cheng, U. S. Rao, H. Danahay, and R. J. Bridges A Segment of {gamma} ENaC Mediates Elastase Activation of Na+ Transport J. Gen. Physiol., November 26, 2007; 130(6): 611 - 629. [Abstract] [Full Text] [PDF]

				V. Bize and J.-D. Horisberger Sodium self-inhibition of human epithelial sodium channel: selectivity and affinity of the extracellular sodium sensing site Am J Physiol Renal Physiol, October 1, 2007; 293(4): F1137 - F1146. [Abstract] [Full Text] [PDF]

				J. B. Bruns, M. D. Carattino, S. Sheng, A. B. Maarouf, O. A. Weisz, J. M. Pilewski, R. P. Hughey, and T. R. Kleyman Epithelial Na+ Channels Are Fully Activated by Furin- and Prostasin-dependent Release of an Inhibitory Peptide from the {gamma}-Subunit J. Biol. Chem., March 2, 2007; 282(9): 6153 - 6160. [Abstract] [Full Text] [PDF]

				M. M. Myerburg, M. B. Butterworth, E. E. McKenna, K. W. Peters, R. A. Frizzell, T. R. Kleyman, and J. M. Pilewski Airway Surface Liquid Volume Regulates ENaC by Altering the Serine Protease-Protease Inhibitor Balance: A MECHANISM FOR SODIUM HYPERABSORPTION IN CYSTIC FIBROSIS J. Biol. Chem., September 22, 2006; 281(38): 27942 - 27949. [Abstract] [Full Text] [PDF]

				K. K. Knight, D. R. Olson, R. Zhou, and P. M. Snyder Liddle's syndrome mutations increase Na+ transport through dual effects on epithelial Na+ channel surface expression and proteolytic cleavage PNAS, February 21, 2006; 103(8): 2805 - 2808. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF, 487K) PPT slides of all figures Alert me when this article is cited Citation Map Services Email this article Similar articles in this journal Similar articles in PubMed Alert me to new content in the JGP Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via CrossRef Citing Articles via Google Scholar Google Scholar Articles by Adebamiro, A. Articles by Bridges, R. J. Search for Related Content PubMed PubMed Citation Articles by Adebamiro, A. Articles by Bridges, R. J. Social Bookmarking                            What's this?