From the Institute of Pharmacology and Toxicology, University of Lausanne, CH-1005 Lausanne, Switzerland
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ABSTRACT |
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We have investigated the effect of extracellular proteases on the amiloride-sensitive Na+ current
(INa) in Xenopus oocytes expressing the three subunits ,
, and
of the rat or Xenopus epithelial Na+ channel
(ENaC). Low concentrations of trypsin (2 µg/ml) induced a large increase of INa within a few minutes, an effect
that was fully prevented by soybean trypsin inhibitor, but not by amiloride. A similar effect was observed with chymotrypsin, but not with kallikrein. The trypsin-induced increase of INa was observed with Xenopus and rat ENaC,
and was very large (~20-fold) with the channel obtained by coexpression of the
subunit of Xenopus ENaC with the
and
subunits of rat ENaC. The effect of trypsin was selective for ENaC, as shown by the absence of effect on
the current due to expression of the K+ channel ROMK2. The effect of trypsin was not prevented by intracellular injection of EGTA nor by pretreatment with GTP-
S, suggesting that this effect was not mediated by G proteins.
Measurement of the channel protein expression at the oocyte surface by antibody binding to a FLAG epitope
showed that the effect of trypsin was not accompanied by an increase in the channel protein density, indicating
that proteolysis modified the activity of the channel present at the oocyte surface rather than the cell surface expression. At the single channel level, in the cell-attached mode, more active channels were observed in the patch
when trypsin was present in the pipette, while no change in channel activity could be detected when trypsin was
added to the bath solution around the patch pipette. We conclude that extracellular proteases are able to increase the open probability of the epithelial sodium channel by an effect that does not occur through activation of a G
protein-coupled receptor, but rather through proteolysis of a protein that is either a constitutive part of the channel itself or closely associated with it.
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INTRODUCTION |
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The passage of sodium through the epithelial Na+
channel (ENaC)1 is the rate limiting step in the sodium
reabsorption by the epithelial cells of the distal nephron and colon and in airways (Garty and Palmer, 1997).
It thereby plays a key role in the regulation of the sodium balance, extracellular fluid volume, and blood
pressure by the kidney, and in the controlled fluid reabsorption in the airways. The activity of ENaC has to
be tightly regulated with regard to the whole organism
sodium balance, but also with regards to the epithelial
cell transport capacity so that the homeostasis of the intracellular milieu is preserved. This regulation is under the control of several hormones and intracellular factors by mechanisms that are not yet completely understood (Garty and Palmer, 1997
).
Concerning luminal factors, Garty and Edelman
(1983) observed that trypsin, at a concentration of 1 mg/ml, induced an irreversible inhibition of the sodium transport and this effect could be prevented by
amiloride. They concluded that a component of the
Na+ channel protein could be cleaved by a protease at
a site protectable by amiloride bound to its receptor.
Lewis and Alles (1986)
and Lewis and Clausen (1991)
studied the effects of proteases such as kallikrein,
which is normally present in mammalian urine, on the
Na+ channel of the rabbit urinary bladder. To briefly
summarize their findings, they observed that these proteases altered the highly selective and amiloride-sensitive Na+ channel into a nonselective cation channel,
and further proteolysis rendered this channel unstable
in the membrane so that the proteolyzed channel
could eventually be recovered from the fluid bathing
the apical medium (Zweifach and Lewis, 1988
). These
authors speculated that luminal proteolytic activity
could be a physiological regulator of the epithelial Na+
channel (Lewis and Alles, 1986
).
Orce et al. (1980) made an interesting observation
suggesting, in contrast, that an extracellular protease
was able to activate the electrogenic Na+ transport:
they reported that the trypsin inhibitor aprotinin induced a decrease of the amiloride-sensitive short circuit
current in the toad bladder. In support of an activating
effect of a protease on ENaC, Vallet et al. (1997)
have
recently identified a novel endogenous serine protease
in A6 cells that is able to activate the amiloride-sensitive
Na+ current when coexpressed with ENaC in oocytes.
In addition, they also show that trypsin can activate the
amiloride-sensitive Na+ current in the A6 cell. To try to
understand the mechanism of these effects of proteases, we have studied the effect of serine proteases on
the Na+ current carried by rat (Canessa et al., 1993
,
1994
) or Xenopus (Puoti et al., 1995
) ENaC expressed
in Xenopus oocytes. Trypsin is known to induce a transient activation of a calcium-activated chloride current
in Xenopus oocytes, an effect described by Durieux et al.
(1994)
that is mediated through a G protein-coupled
trypsin receptor naturally present in the oocyte membrane and an IP3-induced release of calcium from intracellular stores. In addition to these known effects, we
observed that low concentrations of trypsin or chymo-trypsin induced an activation of the amiloride-sensitive current carried by ENaC expressed in oocytes. A number of experiments performed to evaluate the role of G
proteins or potential intracellular second messengers
in this regulation yielded negative results. The data
from macroscopic current and single channel experiments rather suggest that the effect of trypsin occurs
through proteolysis of the channel protein itself or of a
closely associated protein.
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METHODS |
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Expression of Rat and Xenopus ENaC in Xenopus Oocytes
In vitro-transcribed cRNA for the ,
, and
subunits of Xenopus
ENaC (XENaC) and rat ENaC (rENaC) were injected into stage V-VI Xenopus oocytes (0.3-1 ng of cRNA of each subunit in a total volume of 50 nl) as described previously (Canessa et al., 1993
, 1994
; Puoti et al., 1995
). Electrophysiological experiments were performed 1-2 d after cRNA injection. In other experiments, 1 ng of human cystic fibrosis transmembrane conductance regulator (CFTR) cRNA (clone generously provided by R. Boucher,
University of North Carolina, Chapel Hill, NC), 1 ng of human
2 adrenergic receptor cRNA (clone generously provided by S. Cotecchia, Institute of Pharmacology, Lausanne, Switzerland), or
0.1 ng rat ROMK2 cRNA (cDNA generously provided by L.G.
Palmer, Cornell University Medical College, New York) were in
vitro transcribed and injected into Xenopus oocytes.
Ion Current Measurement in Whole Ooctyes
Amiloride-sensitive and cAMP-stimulated Cl currents were measured as previously described (Canessa et al., 1993
) using the two-electrode voltage clamp technique by means of a Dagan TEV voltage clamp apparatus (Dagan Corp., Minneapolis, MN), at
room temperature (22-25°C) and at a holding potential of
100
mV in a solution containing (mM) 100 Na gluconate, 0.4 CaCl2,
10 Na HEPES, pH 7.4, 5 BaCl2, and 10 tetraethylammonium chloride. The current signal was filtered at 20 Hz using the internal
filter of the Dagan apparatus and continuously recorded on a paper chart. Low chloride concentration and K+ channel blockers
were used to reduce the background membrane conductance.
ROMK2-induced K+ currents were measured as the inward
current induced by addition of 5 mM K+ at 100 mV under the
conditions described by Zhou et al. (1994)
.
Single Channel Recordings
Before patch-clamp experiments, the oocytes were placed for 3-5
min at room temperature in a hypertonic medium (475 mosM) with the following composition (mM): 200 K aspartate, 20 KCl, 1 MgCl2, 10 EGTA, 10 Na HEPES, pH 7.4. The vitelline membrane could then be manually removed from the cell using fine forceps (Methfessel et al., 1986). The oocytes were then immediately
transferred to the recording chamber.
Both the cell-attached and excised outside-out patch clamp experiments were carried out according to the methods described by Hamill et al. (1981). Patch pipettes were made of borosilicate glass (Corning Glass Works, Corning, NY), pulled in two stages with a PP-83 vertical puller (Narishige, Japan) and fire polished. They had a resistance of 10-20 M
. Single channel currents were recorded with a patch clamp amplifier (LM EPC 7; List Electronics, Darmstadt, Germany), displayed on an oscilloscope (Tektronix, Heerenveen, The Netherlands) and stored on a digital
tape recorder (Biologic, France). By convention, for outside-out
patches the intracellular potential corresponds to the pipette potential (Vpip), and negative (downward) single channel currents
correspond to Li+ flux from the extracellular to the intracellular
side of the membrane; for cell-attached patches the membrane
potential should be close to the actual potential across the membrane patch because the oocyte membrane potential is close to 0 mV under our experimental conditions.
Current signals were filtered at 200 Hz with an eight pole Bessel filter (Frequency Devices Inc., Haverhill, MA) and digitized at 1 kHz using a Labmaster analog-digital interface and Fetchex Software (Axon Instruments, Foster City, CA). The n.Po product (n = number of channel, Po = open probability) was calculated as n.Po = IENaC/i, where IENaC is the current due to ENaC (= total current minus current with no channel open) averaged over a 1-min recording, divided by the unitary current measured as the peak to peak interval in the amplitude histogram.
Chemicals and Enzymes
Amiloride, guanosine 5-O-(3-thiotriphosphate) (GTP-
S), soybean trypsin inhibitor, and trypsin (DPCC-treated trypsin from bovine pancreas, a form of trypsin with low level of chymotrypsin contamination) were obtained from Sigma Chemical Co. (St.
Louis, MO). Porcine kallikrein was obtained from Calbiochem
Corp. (La Jolla, CA) and chymotrypsin (TLCK-treated
-chymo-trypsin, a form of chymotrypsin with a low level of trypsin contamination), was purchased from Fluka (Buchs, Switzerland).
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RESULTS |
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Effect of Trypsin on ENaC Expressed in Xenopus Oocytes
As shown in Fig. 1 a, 2 µg/ml trypsin had a biphasic effect: it induced first a peak of inward current lasting
10-60 s; the amplitude and the duration of this current
was highly variable, sometimes undetectable and sometimes amounting to 2-3 µA. This effect of trypsin has
been described by Durieux et al. (1994). This current
could also be observed in native noninjected oocytes or
oocytes expressing ENaC in the presence of 10 µM
amiloride and was therefore not related to ENaC. In
oocytes expressing
ENaC, trypsin induced in addition a slower increase of a steady inward current, with a
time course of 1-5 min to reach its maximal amplitude (Fig. 1 a). This current was amiloride sensitive.
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The amplitude of the increase of the amiloride-sensitive sodium current (INa) was quite variable, ranging
from a hardly detectable increase to a sixfold increase
in oocytes expressing rat ENaC, and a 2- to more
than 10-fold increase in oocytes expressing Xenopus
ENaC. Heteromeric channels composed of the
subunit of the Xenopus ENaC and the
and
subunits
of rat ENaC expressed a small INa, but in these oocytes
trypsin induced a very large increase of INa, often >20-fold, following the same time course. The mean values
of the baseline INa and of the increase of INa after a 3-5-min exposure to 2 µg/ml trypsin in Xenopus ENaC,
(
X
X
X), in rat ENaC (
r
r
r), and in heteromeric
rat/Xenopus channels,
X
r
r and
r
X
X, are given
in Table I. The response to trypsin was inversely correlated with the initial INa value as shown in Fig. 2, suggesting that trypsin effect was larger in oocytes either expressing a low number of channels or channels with
a low open probability.
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To examine the question of whether the effect of
trypsin was due to its catalytic activity or to some other
mechanism such as binding to a receptor, we measured
the effect of trypsin (2 µg/ml) first in the presence and
then absence of fivefold excess of soybean trypsin inhibitor (10 µg/ml) in oocytes expressing rENaC.
As shown in the example of Fig. 1 b, the presence of trypsin inhibitor completely prevented the effect of
trypsin, while trypsin alone was subsequently able to induce a large increase of INa. In eight measurements, a
3-min exposure to trypsin + trypsin inhibitor resulted
in a slight decrease of INa to 87 ± 13% of its initial value
(no significant difference), while subsequent exposure
to trypsin alone induced an increase of INa to 277 ± 36% of the initial control value (P < 0.001, paired t
test).
The inhibitory effect of trypsin described earlier in
toad or rabbit bladder (Garty and Edelman, 1983;
Lewis and Clausen, 1991
) could be prevented by
amiloride. We tested the effect of amiloride on the
stimulatory effect of trypsin using the following protocol to ensure that no channels were exposed to trypsin
in the absence of amiloride (see example in Fig. 1 c).
After recording the Na+ current in the control solution, amiloride (10 µM) was first added to block the
channel. 30 s later, trypsin (2 µg/ml) was added in the
presence of amiloride for 3 min, and then removed while amiloride was still present. Finally, amiloride was
removed, allowing measurement of the Na+ current. As
shown in Fig. 1 c, the stimulatory effect on INa was not
prevented by amiloride. In a series of comparative measurements, the increase of the amiloride-sensitive current when trypsin was added for 3 min in the absence
of amiloride (8.6 ± 1.6, n = 11) and when trypsin was
added in the presence of 10 µM amiloride (9.8 ± 2.1, n = 9) was similar.
To evaluate the selectivity of the action of trypsin, we
also studied the effect of trypsin on the inward K+ current induced in oocyte by expression of ROMK2, a renal K+ channel that is most probably expressed in the
apical membrane of the cortical collecting tubule principal cells, the same membrane in which ENaC is expressed (Zhou et al., 1994). In 11 oocytes expressing
ROMK2, the inward K+ current amounted to 365 ± 69 nA and was not increased by trypsin (331 ± 66 nA, after
a 3-min exposure to 2 µg/ml trypsin).
Trypsin Concentration-Effect Relationship and Effects of Other Proteolytic Enzymes
Because of the large variability of the response to
trypsin and the large and variable Cl current induced
early after exposure to trypsin, we were not able to establish a relationship between the concentration of trypsin and the initial rate of Na+ current increase.
However, to demonstrate that a maximal effect could
be obtained by a 3-min exposure to a 2-µg/ml trypsin
concentration, we showed that a subsequent 3-min exposure to 50 µg/ml trypsin could not further increase
INa (see Fig. 3 a). In addition, in an attempt to observe
the inhibitory effect described earlier, we measured INa
in oocytes expressing ENaC before and after a 3-min
exposure to 10 µg/ml trypsin, a maneuver that induced the usual increase in INa, and then we incubated
these oocytes for 30 min in a solution containing 1 mg/
ml trypsin and measured INa again in the same oocytes.
This experiment was performed in 18 oocytes expressing Xenopus ENaC and 14 oocytes expressing rat ENaC.
In both cases, we failed to observe a decrease of the
Na+ current (Fig. 3 b).
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The effect of chymotrypsin on INa was roughly similar
to the effect of trypsin. With oocytes expressing Xenopus
ENaC, a 3-min treatment with 2 or 10 µg/ml induced a mean increase of 1.50 ± 0.08-fold (n = 14)
and 2.65 ± 0.36-fold (n = 13), respectively. With rat
ENaC, 2 µg/ml chymotrypsin induced a 2.69 ± 0.33-fold increase in INa (n = 13). Remarkably, chymotrypsin
never induced the early transient peak of current that
was usually observed with trypsin and attributed to a
calcium-activated chloride channel.
We also tested the effect of kallikrein on oocytes expressing Xenopus ENaC. Kallikrein, at a concentration
of 10 µg/ml and for a 5-min exposure, produced no
detectable effect. In fact, INa decrease from 5.9 ± 1.1 to
4.8 ± 1.0 µA, a mean 17% decrease, which corresponds
to the usual slow run down of the ENaC current expressed in oocytes (Awayda et al., 1996). Subsequent
exposure to 2 µg/ml trypsin induced an increase of INa
to 10.2 ± 2.1 µA, showing that the oocytes were indeed
able to react to trypsin as usual.
Effect on the Properties of ENaC
To test for the possibility of an alteration of the channel ionic selectivity after trypsin treatment, we measured the amiloride-sensitive current carried by Na+,
Li+, or K+ before and after activation by trypsin. No significant amiloride-sensitive inward current at 100 mV
could be detected when K+ was the only extracellular
monovalent cation before (0.02 ± 0.02 µA, n = 6) or
after a 5-min trypsin (2 µg/ml) treatment (0.03 ± 0.03 µA, n = 6). The amiloride-sensitive Na+ channel has
been shown to be more conductive for Li+ than for
Na+ both in native tissue (Palmer and Frindt, 1988
)
and as the result of ENaC expression in Xenopus oocyte
(Canessa et al., 1994
). We measured the amiloride-sensitive current in oocytes expressing
XENaC before
and after a 3-min exposure to trypsin. In 15 measurements, the mean Na current was 3.4 ± 1.1 µA before
and increased to 6.9 ± 1.4 µA after trypsin treatment.
The ratio of the amiloride-sensitive current in 100 mM
Na+ vs. 100 mM Li+ was 1.51 ± 0.05 before trypsin, and
decreased slightly to 1.44 ± 0.05 after trypsin (P < 0.005, paired t test). We also measured the inhibitory
constant (KI) of amiloride before and after a 3-min trypsin treatment in oocytes expressing
XENaC in
the presence of 100 mM Na+, at
100 mV, according
to the procedure used earlier (Puoti et al., 1995
), using
concentrations of 0.1, 1.0, 10, and 50 µM amiloride. In
a group of 13 oocytes, INa increased about six times after trypsin treatment (from 1.09 ± 0.56 to 6.49 ± 1.20 µA, P < 0.001), while the amiloride KI did not change
significantly (0.55 ± 0.03 µM before vs. 0.49 ± 0.03 µM
after trypsin).
Role of Intracellular Calcium
As shown by Durieux et al. (1994), the first component
of the response to trypsin, the chloride current, is dependent on a rise of intracellular calcium. To evaluate
the role of intracellular calcium on the INa response to
trypsin, we injected Xenopus oocytes expressing
XENaC and
rENaC with 50 nl of 100 mM EGTA or water (control). As shown in the examples of Fig. 4 and in
accordance with Durieux et al. (1994)
, we found that
this treatment abolished the transient chloride current,
but it did not prevent the increase of the amiloride-sensitive current. In oocytes expressing
XENaC, trypsin
induced a 5.6 ± 1.2-fold increase (n = 9) in INa 10-20 min after EGTA injection, a value similar to the mean
6.3 ± 1.2-fold increase observed in control oocytes injected with water (n = 7) or noninjected oocytes (n = 4). In 10 oocytes expressing the
X
r
r ENaC and injected with EGTA, trypsin induced a mean 14.5 ± 5.4-fold increase, which was not significantly different from the effect observed without EGTA injection.
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Relation with Regulation of ENaC through G Protein
To evaluate the potential role of G protein in the response to trypsin, we followed the amiloride-sensitive
current before and after trypsin treatment in oocytes
injected with GTP-S, a nonspecific activator of all G
proteins. As a positive control, we coexpressed human
CFTR and the human
2 adrenergic receptor and
tested for activation of a chloride current by 1 µM epinephrine. Epinephrine induced a fast increase of the
conductance in oocytes expressing CFTR and the
2
adrenergic receptor (Fig. 5 a). When oocytes were injected with GTP-
S (0.09 nmol = 50 nl of a 1.8-mM GTP-
S solution) 10-30 min before the electrophysiological measurement, the initial conductance of the oocytes expressing CFTR was larger and the response to
epinephrine was abolished (Fig. 5 b), indicating that
GTP-
S injection was efficient to activate G proteins. In contrast, when we studied oocytes expressing Xenopus
ENaC, the baseline amiloride-sensitive current was similar in the GTP-
S-injected and water-injected groups,
and trypsin induced a large increase of the amiloride-sensitive current (Fig. 5 c) similar to that observed in the
control group. The mean values of INa before and after
trypsin and of the oocyte conductance (G) before and
after epinephrine stimulation are shown in Fig. 5 d.
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Effect of Trypsin and Channel Density
To evaluate the effect of trypsin on the number of
channels at the oocyte surface, we used channel mutants in which a FLAG epitope had been added to the
extracellular domain of each subunit, and estimated
the channel density by binding of iodinated anti-FLAG antibody as described earlier (Firsov et al., 1996). Anti-
FLAG antibody binding was measured after a 10-min
exposure to trypsin (5 µg/ml) and in control oocytes
not exposed to trypsin. At the same time, the amiloride-sensitive current was measured in two parallel groups
of oocytes exposed to the same treatment. The results
of specific anti-FLAG binding and the amiloride-sensitive current with or without trypsin treatment (shown
in Fig. 6) indicate that trypsin does not induce a modification of the channel density at the cell surface.
Therefore, the increase in INa is not due to translocation of channels from an intracellular pool to the surface, and so the increase in current must be due either
to an increase in single channel conductance or to a
modification of the open probability.
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Effect of Trypsin at the Single Channel Level
The effects of trypsin on the single channel current
were examined in Xenopus oocytes expressing ENaC using the cell-attached mode and excised patches in the
outside-out configuration. Cell-attached patches were
obtained using pipettes filled with a 100-mM LiCl solution with or without 5 µg/ml trypsin. Under these conditions, typical Xenopus ENaC single channel currents
(8 pS inward current) were observed in 7 of 16 successful patches (44%) in the absence of trypsin and in 8 of
11 successful patches (73%) in the presence of trypsin.
This difference is marginally significant (P < 0.05 by 2
test). Analysis of open probability did not show obvious
differences between the two groups, a fact that is not
surprising considering the very large spontaneous variation in open probability observed with ENaC (Palmer
and Frindt, 1988
, 1996
). To confirm the activation of
the channel by trypsin, we took advantage of the observation, described above, that the heteromer composed
of the
subunit of Xenopus and the
and
subunits of
rat ENaC (
X
r
r) showed a much larger increase after trypsin treatment than either the rat or Xenopus
ENaC. Channels were observed in 8 of 12 successful patches (67%) when the pipette contained trypsin,
but only in 1 of 16 successful patches (6%) without
trypsin (P < 0.001). There was no difference in single
channel conductance between any of these groups. The
increase in active channel density observed in these experiments is consistent with those found in macroscopic current (see Table I).
Another series of experiments was carried out to test the possibility that trypsin could activate the sodium channel indirectly, for instance through the diffusion of a soluble intracellular second messenger. Patches in the cell-attached configuration were obtained with LiCl solution-containing pipettes. The channel activity was recorded for 2-5 min under control conditions, and then 5 µg/ml trypsin was added to the bath solution surrounding the pipette and the oocyte. A representative trace is shown in Fig. 7 a. Although neither the absolute number of channels nor the open probability could be determined accurately, there was no obvious increase in channel activity after perfusion with trypsin. The mean values of the n.Po before and during exposure to trypsin are given in Fig. 7 b. Together with the results obtained with trypsin in the pipette, these results suggest that the effect of trypsin is local (i.e., by action of trypsin on the channel itself or on a closely associated protein) and is not mediated by a soluble intra-cellular second messenger.
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We have also tested the effect of extracellular trypsin in
the excised patch, outside-out configuration, with patches
obtained on oocytes expressing Xenopus ENaC. For
these experiments, the pipette solution had the following composition (mM): 20 KCl, 80 K gluconate, 2 EGTA, 10 Na HEPES, pH 7.4, and the bath solution was
a 100-mM LiCl solution, buffered to pH 7.4 with 10 mM
Na HEPES. Under these circumstances, we could observe inward single channel currents, carried by lithium, at a holding potential Vpip of
100 mV. Most often
after patch excision, there was either no channel activity or a rapidly running down channel activity, but in a few cases a stable channel activity was observed. In four
such cases, the identity of the channel could be first
verified by the effect of low concentration of external
amiloride: 0.2 µM amiloride induced a reversible decrease of n.Po to 45 ± 6% of its initial value (Fig. 8), a
decrease compatible with the KI 0.6 µM observed for
Xenopus ENaC in macroscopic current experiments (Puoti
et al., 1995
). Trypsin (5 µg/ml) added to the extracellular side of the membrane did not induce any increase
of the activity of ENaC (n.Po control 1.7 ± 1.0 vs. n.Po
trypsin 1.2 ± 0.8, n = 4).
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DISCUSSION |
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In contrast to several earlier reports indicating an inactivating effect of proteases on the epithelial sodium
channel (Garty and Edelman, 1983; Lewis and Alles,
1986
; Lewis and Clausen, 1991
), we have observed that
trypsin and chymotrypsin induce a significant activation of the sodium or lithium current carried by ENaC
expressed in Xenopus oocytes. The stimulatory effect of
proteases was obtained with much lower concentrations of trypsin than those used in the experiments reported by Garty and Edelman (1983)
or Lewis et al. (1991). Even using a large concentration of trypsin for
a long time, we failed to observe a decrease of the
amiloride-sensitive Na+ current, suggesting a direct
proteolytic degradation of the channel. The different
experimental model, native tight epithelia versus Xenopus oocytes artificially expressing ENaC, might be the
reason for this discrepancy. In the oocyte, the expressed channel might be in a different conformation
or be missing a protein component distinct from the
,
, and
subunits, a component that might be necessary for the sensitivity to the inhibitory effect of trypsin. Another difference is the species: we used rat and Xenopus ENaC, while the results published by Garty and
Edelman (1983)
and Lewis et al. (1991) were obtained
with Bufo marinus and rabbit tissues; minor sequence
differences might determine the presence or absence of a proteolytic site. This hypothesis is supported by the
observation of Jungwirth et al. (1991)
, who also failed
to observe stimulatory effect of trypsin or kallikrein on
the transepithelial potential of rat distal convoluted tubules.
The observation of a stimulatory effect of trypsin of
the Na+ current mediated by ENaC goes in the same direction as the observation of Orce et al. (1980) showing
that inhibition by aprotinin of a proteolytic activity in
the apical medium from toad urinary bladder led to a
reduced transepithelial sodium transport. The demonstration of the presence of a "kallikreinlike" protease
activity in the apical medium of A6 cells grown on permeable support (Jovov et al., 1990
) could well provide
the physiological equivalent in a native epithelia of
what we have observed with trypsin and Na+ channels
expressed in Xenopus oocytes. This hypothesis has received strong support from the recent identification of
an endogenous serine protease naturally expressed in
A6 cells that is able to activate INa when coexpressed
with ENaC in oocytes and the observation that trypsin
also activates the electrogenic transepithelial Na+ transport in A6 cells provided that the endogenous protease
had first been inhibited (Vallet et al., 1997
). The experiments presented here give some first indications about
the mechanism by which a protease active from the extracellular side of the membrane might activate the
Na+ channel.
The Effect of Trypsin Does Not Occur through G Protein-mediated Increase in cAMP or Intracellular Calcium
Trypsin is known to produce a transitory activation of
calcium-activated chloride current, an effect probably
mediated by the activation of a G protein-coupled
trypsin receptor naturally present at the surface of the
native oocyte, followed by activation of phospholipase
C, and IP3-mediates release calcium from endogenous calcium stores (Durieux et al., 1994). Several observations indicate that the activation of the sodium current
is not due to the same mechanism. First, the chloride
current can be prevented by intracellular calcium buffering, while the increase of the amiloride-sensitive current is not affected by this maneuver. Second, no detectable transient chloride currents were observed after
chymotrypsin treatment, suggesting that this enzyme
was not able to activate the endogenous oocyte trypsin
receptor while it produced a large increase in the Na+
current with both Xenopus and rat ENaC. We therefore
conclude that the ENaC response to proteases is not related to the presence of an oocyte-endogenous trypsin
receptor, but is mediated by a different mechanism
than that responsible for the calcium-activated chloride
current response.
In amphibian and mammalian tight epithelia, the
amiloride-sensitive Na+ transport is stimulated by
cAMP (Schafer and Hawk, 1992; Verrey, 1994
) and this
is the main mechanism by which vasopressin can increase the transepithelial Na+ transport. It was tempting to make the hypothesis that trypsin stimulation of
INa in Xenopus oocytes occurred through the same mechanism, especially considering the similar time
course of the responses (compare for instance our data
with the results obtained by Verrey, 1994
, on A6 cells),
but several observations indicate that this is not the
case. First, INa, due to ENaC expression in Xenopus oocytes, does not appear to be stimulated by an increase of cAMP production (Awayda et al., 1996
). Second, we
could not modify the response to trypsin by a pretreatment with GTP-
S, which is a strong, although indirect,
indication that no G proteins are involved in the response of ENaC to trypsin.
Finally, the observation of the effect of trypsin on single Na+ channel activity, in the "cell-attached" configuration, when trypsin was applied inside, but not outside, the pipette, indicated that the effect of trypsin is a "local" phenomenon; i.e., a mechanism that involves protein(s) that can be present together with the channel within the ~1 µm2 of membrane area included in a patch and probably does not include the diffusion of a soluble second messenger.
All these data taken together indicate clearly that the effect of trypsin on the sodium current carried by ENaC is not mediated by the "classical" pathway of receptor binding, G protein activation, second messenger production, protein kinase activation, or channel phosphorylation.
Hypothetical Mechanism of Action of Trypsin on ENaC
The similar effects of two different serine proteases on the Na+ channel activity suggest that this effect is due to a proteolytic event. The abolishment of the effect of trypsin by soybean trypsin inhibitor is also compatible with this hypothesis. What might be the substrate of this proteolytic action?
The earlier published observations of an inhibitory
effect of trypsin and other proteases on the epithelial
Na+ channel had demonstrated important modifications of the channel properties: change in selectivity
(Lewis and Alles, 1986; Lewis and Clausen, 1991
) or inability to further respond to aldosterone (Garty and
Edelman, 1983
). In addition, the effect of proteases could be prevented by the presence of an amiloride
molecule in its binding site (Garty and Edelman, 1983
;
Schlichter et al., 1986
). All these observations clearly
supported the hypothesis that the channel itself (i.e.,
one of its protein components) was the substrate of the
protease. Unfortunately, the situation is less clear concerning the stimulatory effect of trypsin. Although our
results are all compatible with a direct effect of trypsin on one or several of the ENaC subunits, we could not
find any direct evidence supporting this hypothesis.
The effect of trypsin on the Na+/Li+ selectivity ratio is
compatible with a modification of the selectivity filter
of the channel, to which the "pre-M2" segment of each
subunit seems to contribute (Schild et al., 1997
). However, the observed change, although statistically significant, is of such a small amplitude that we could not
convince ourselves that this observation is a reliable
proof of the direct action of the protease on the channel protein. The absence of modification of the Na+/
K+ selectivity and of the affinity to amiloride does not
support a direct effect. Sodium channel activation by
trypsin could not be blocked or even slowed down by a
concentration of amiloride sufficient to occupy >95%
of the channels. However, our patch clamp data clearly
indicate a local effect. Therefore, the substrate of
trypsin, if it is not the channel protein itself, is probably a closely associated protein.
Although the effect of trypsin could be observed
when applied inside a patch pipette in the cell-attached
mode, no effect of trypsin could be detected in excised
outside-out patches. These observations should be interpreted with care because, due to the "run down"
phenomenon, only a small fraction of Na+ channels remain active in excised patches, and this fraction may
not be representative of the whole channel population;
they nevertheless suggest that, although the proteolytic
action of trypsin is most probably extracellular, the activation process includes some intracellular component
that is disturbed by the patch excision procedure. This
situation is somewhat similar to that observed with the
effect of vasopressin on the Na+ channel density that
could well be observed when the hormone was applied
before a patch was obtained, but not when vasopressin was added after the formation of a seal (Marunaka and
Eaton, 1991). However, in contrast with the well supported hypothesis of channel insertion for the response to vasopressin (Garty and Palmer, 1997
), our
data obtained using FLAG insertion mutants and anti-
FLAG antibody binding do not support a significant
change of surface channel density to explain the large
increase in Na+ current density. Since the single channel conductance was not modified, the effect of trypsin
must be due to an increase of the proportion of open
channels in the total population of channels present at
the cell surface. Our data do not allow us to determine whether this increase results from a change in the open
probability of already active channels or from recruitment out of a pool of completely silent channels. The
large increase that is often observed after trypsin treatment indicates that the overall open probability of all
the channels present at the oocyte surface must be very low. As the mean open probability of active channels
observed in cell-attached patches on oocytes expressing
ENaC is often of the order of 0.5 (Canessa et al., 1994
),
our results suggest that there may be a significant fraction of "silent" channels that are not seen in patch
clamp experiments, but are present at the oocyte surface and can be activated by proteolytic treatment. A
similar conclusion was reached by Firsov et al. (1996)
using quantitative measurements of cell surface channel protein expression. The inverse relationship between the initial INa and the effect of trypsin (see Fig. 2)
could be explained if there was a variable degree of
"spontaneous" activation, possibly by an oocyte-endogenous protease. In oocytes with a low degree of spontaneous activation, trypsin would reveal a large portion of
silent channels while, in oocytes with a high level of
spontaneous activation, trypsin could only activate a
small portion of silent channels.
In summary, trypsin or chymotrypsin can induce a
large activation of the sodium channel obtained by expression of the ,
, and
subunits of the rat or Xenopus ENaC in Xenopus oocytes. This effect is due to an increase of the open probability of channels already
present at the oocyte surface, through a proteolytic action of the enzyme on the channel protein itself or a
closely associated component.
![]() |
FOOTNOTES |
---|
Address correspondence to Jean-Daniel Horisberger, Institute of Pharmacology and Toxicology, University of Lausanne, Bugnon 27, CH-1005 Lausanne, Switzerland. Fax: 41 21 692 53 55; E-mail: jean-daniel.horisberger{at}ipharm.unil.ch
Received for publication 24 July 1997 and accepted in revised form 15 October 1997.
1 Abbreviations used in this paper: CFTR, cystic fibrosis transmembrane conductance regulator; ENaC, epithelial Na+ channel; INa, amiloride-sensitive Na+ current.We are grateful to L. Schild, B. Rossier, and S. Cotecchia for critical reading of the manuscript and for helpful suggestions.
This work was supported by the Human Frontier Science Program, grant RG-0464.
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REFERENCES |
---|
![]() ![]() ![]() ![]() ![]() ![]() ![]() |
---|
1. | Awayda, M.S., I.I. Ismailov, B.K. Berdiev, C.M. Fuller, and D.J. Benos. 1996. Protein kinase regulation of a cloned epithelial Na+ channel. J. Gen. Physiol. 108: 49-65 [Abstract]. |
2. | Canessa, C.M., J.-D. Horisberger, and B.C. Rossier. 1993. Functional cloning of the epithelial sodium channel: relation with genes involved in neurodegeneration. Nature. 361: 467-470 [Medline]. |
3. | Canessa, C.M., L. Schild, G. Buell, B. Thorens, Y. Gautshi, J.-D. Horisberger, and B.C. Rossier. 1994. The amiloride-sensitive epithelial sodium channel is made of three homologous subunits. Nature. 367: 463-467 [Medline]. |
4. |
Durieux, M.E.,
M.N. Salafranca, and
K.R. Lynch.
1994.
Trypsin induces Ca2+-activated Cl![]() |
5. |
Firsov, D.,
L. Schild,
I. Gautschi,
A.M. Merillat,
E. Schneeberger, and
B.C. Rossier.
1996.
Cell surface expression of the epithelial
Na channel and a mutant causing Liddle syndrome![]() |
6. | Garty, H., and I.S. Edelman. 1983. Amiloride-sensitive trypsinization of apical sodium channels. Analysis of hormonal regulation of sodium transport in toad bladder. J. Gen. Physiol. 81: 785-803 [Abstract]. |
7. |
Garty, H., and
L.G. Palmer.
1997.
Epithelial sodium channels![]() |
8. | Hamill, O.P., A. Marty, E. Neher, B. Sakmann, and F.J. Sigworth. 1981. Improved patch-clamp technique for high-resolution current recording from cells and cell-free membrane patches. Pflügers Arch. 391: 85-100 [Medline]. |
9. |
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
|
10. | Jungwirth, A., S. Lewis, and F. Lang. 1991. Kallikrein does not modify the transepithelial potential of rat renal distal convoluted tubules. Nephron. 58: 225-228 [Medline]. |
11. | Lewis, S.A., and W.P. Alles. 1986. Urinary kallikrein: a physiological regulator of epithelial Na absorption. Proc. Natl. Acad. Sci. USA. 83: 5345-5348 [Abstract]. |
12. | Lewis, S.A., and C. Clausen. 1991. Urinary proteases degrade epithelial sodium channels. J. Membr. Biol. 122: 77-88 [Medline]. |
13. |
Marunaka, Y., and
D.C. Eaton.
1991.
Effects of vasopressin and
cAMP on single amiloride-blockable Na channels.
Am. J. Physiol.
260:
C1071-C1084
|
14. | Methfessel, C., V. Witzemann, T. Takahashi, M. Mishina, S. Numa, and B. Sakmann. 1986. Patch clamp measurements on Xenopus laevis oocytes: currents through endogenous channels and implanted acetylcholine receptor and sodium channels. Pflügers Arch. 407: 577-588 [Medline]. |
15. | 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]. |
16. | Palmer, L.G., and G. Frindt. 1988. Conductance and gating of epithelial Na channels from rat cortical collecting tubule. J. Gen. Physiol. 92: 121-138 [Abstract]. |
17. | 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]. |
18. | 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. 38: C188-C197 . |
19. | Schafer, J.A., and C.T. Hawk. 1992. Regulation of Na+ channels in the cortical collecting duct by AVP and mineralocorticoids. Kidney Int. 41: 255-268 [Medline]. |
20. |
Schild, L.,
E. Schneeberger,
I. Gautschi, and
D. Firsov.
1997.
Identification of amino acid residues in the ![]() ![]() ![]() |
21. | Schlichter, L., N. Sidell, and S. Hagiwara. 1986. K channels are expressed early in human T-cell development. Proc. Natl. Acad. Sci. USA. 83: 5623-5629 . |
22. | 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 [Medline]. |
23. | Verrey, F.. 1994. Antidiuretic hormone action in A6 cells: effect on apical Cl and Na conductances and synergism with aldosterone for NaCl reabsorption. J. Membr. Biol. 138: 65-76 [Medline]. |
24. | Zhou, H., S.S. Tate, and L.G. Palmer. 1994. Primary structure and functional properties of an epithelial K channel. Am. J. Physiol. 35: C809-C824 . |
25. | Zweifach, A., and S.A. Lewis. 1988. Characterization of a partially degraded Na+ channel from urinary tract epithelium. J. Membr. Biol. 101: 49-56 [Medline]. |