Correspondence to: Stephan Kellenberger, Institut de Pharmacologie et de Toxicologie, Bugnon 27, Université de Lausanne, CH-1005 Lausanne, Switzerland. Fax:41-21-692-5355 E-mail:stephan.kellenberger{at}ipharm.unil.ch.
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Abstract |
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The epithelial Na+ channel (ENaC), located in the apical membrane of tight epithelia, allows vectorial Na+ absorption. The amiloride-sensitive ENaC is highly selective for Na+ and Li+ ions. There is growing evidence that the short stretch of amino acid residues (preM2) preceding the putative second transmembrane domain M2 forms the outer channel pore with the amiloride binding site and the narrow ion-selective region of the pore. We have shown previously that mutations of the S589 residue in the preM2 segment change the ion selectivity, making the channel permeant to K+ ions. To understand the molecular basis of this important change in ionic selectivity, we have substituted
S589 with amino acids of different sizes and physicochemical properties. Here, we show that the molecular cutoff of the channel pore for inorganic and organic cations increases with the size of the amino acid residue at position
589, indicating that
S589 mutations enlarge the pore at the selectivity filter. Mutants with an increased permeability to large cations show a decrease in the ENaC unitary conductance of small cations such as Na+ and Li+. These findings demonstrate the critical role of the pore size at the
S589 residue for the selectivity properties of ENaC. Our data are consistent with the main chain carbonyl oxygens of the
S589 residues lining the channel pore at the selectivity filter with their side chain pointing away from the pore lumen. We propose that the
S589 side chain is oriented toward the subunitsubunit interface and that substitution of
S589 by larger residues increases the pore diameter by adding extra volume at the subunitsubunit interface.
Key Words: ion channel, molecular sieving, pore, Xenopus oocyte, epithelial Na+ channel
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INTRODUCTION |
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The epithelial Na+ channel (ENaC)* is expressed in the apical membrane of epithelial cells of the distal nephron, the colon, and the lung, where it mediates vectorial transepithelial Na+ absorption. The Na+ ions enter the cell through ENaC at the apical membrane and are transported out of the cell by the Na+/K+ ATPase at the basolateral membrane. In the distal nephron, aldosterone and vasopressin regulate ENaC activity, serving to maintain Na+ balance, extracellular volume, and blood pressure (
ENaC belongs to the ENaC/degenerin (DEG) family of ion channels. Members of this family are present in nematodes, flies, snails, and mammals, where they are involved in Na+ transport, neurotransmission, mechanotransduction, and nociception (, one ß, and one
homologous subunits arranged around the central channel pore (
(S583), ß (G525), or
subunit (G537) that decrease channel affinity for amiloride by two to three orders of magnitude (
G587 and homologous residues in ß and
subunits (ßG529 and
S541; Fig 1), four residues downstream of the amiloride binding site affect channel conductance for Na+ and Li+ ions by changing the channel affinity for these permeant ions. These findings suggest that at this site the pore is narrow and the ions interact tightly with the Gly and Ser residues lining the pore (
S589 and the homologous residue in
ENaC result in channels that are permeable to cations larger than Na+ and Li+ such as K+, Rb+, and Cs+ (
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To gain further information on the role of the residue S589 in maintaining the channel pore structure necessary for ion discrimination, we have substituted
S589 with amino acids of different volumes. We have analyzed channel selectivity properties of the
S589 mutants for inorganic and organic cations of varying diameter and shape. We found that the K+ permeability as well as the molecular cutoff of the channel permeability for large cations increases with the size of the amino acid residue at position
S589. This is consistent with an increase of the pore diameter at the selectivity filter. The consequences of this enlargement of the pore are an increase in channel permeation to larger cations, and at the same time, a decrease in the unitary conductance of these mutant channels to small cations such as Na+ and Li+. The observation that mutant channels with large side chains of residue
589 form a wide pore indicates that the side chain of the residue at position 589 points away from the ion permeation pathway. We propose that it points toward the interface between the subunits lining the pore, and that substitutions of
S589 with large amino acid residues increase the diameter of the narrowest part of the channel pore by adding extra volume to the subunitsubunit interface. The largest amino acid substitutions cause structural changes that are incompatible with channel expression at the cell surface.
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MATERIALS AND METHODS |
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Site-directed Mutagenesis, Expression in Xenopus laevis Oocytes and Electrophysiological Analysis
Site-directed mutagenesis was performed on rat ENaC cDNA as described previously (, ß,
subunit were synthesized in vitro. Healthy stage V and VI Xenopus oocytes were pressure-injected with 100 nl of a solution containing equal amounts of
ß
ENaC subunits at a total concentration of 100 ng/µl. For simplicity, mutants are named by the mutated subunit only, although all three subunits (
, ß, and
) always were coexpressed.
Electrophysiological measurements were taken at 1648 h after injection. Macroscopic amiloride-sensitive currents, defined as the difference between ionic currents obtained in the presence and absence of 100 µM amiloride (Sigma-Aldrich) in the bath were recorded using the two-electrode voltage-clamp technique. All macroscopic currents shown are amiloride-sensitive currents as defined above. Currents were recorded with an amplifier (model TEV-200; Dagan Corp.) equipped with two bath electrodes. The standard bath solution contained 110 mM NaCl, 1.8 mM CaCl2, and 10 mM HEPES-NaOH, pH 7.35. For selectivity measurements, Na+ was replaced with Li+, K+, Rb+, Cs+, or the organic cations at the same concentration. Pulses for current-voltage curves were applied, and data were acquired using a PC-based data acquisition system (Pulse; HEKA Electronic). Single-channel currents were measured in the outside-out configuration of the patch-clamp technique essentially as described previously (
Binding Experiments
The FLAG reporter octapeptide that had been introduced in ß and subunits is recognized by the anti-FLAG M2 (M2Ab) mouse mAb (Sigma-Aldrich). M2Ab was iodinated as described by
counting containing 250 µl of the same solution. The samples were counted, and nonspecific binding was determined from parallel assays of noninjected oocytes.
Immunoprecipitation
Oocytes were injected with FLAG-tagged and untagged subunits, as specified. After overnight incubation of the injected oocytes, microsomal membranes were obtained as described previously (
Immunoprecipitations were performed in Triton X-100 buffer overnight at 4°C with the anti-FLAG M2 antibody (M2Ab) and protein GSepharose. After SDS-PAGE, polypeptides were transferred for immunostaining onto nitrocellulose membranes (Schleicher & Schuell) and immunoblotted using antirat ENaC antibody (
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RESULTS |
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Amino Acid Substitutions of Ser 589 in ENaC
We have substituted the amino acid S589 with residues of different sizes and physicochemical properties. The mutant
subunits were coexpressed with wild-type (wt) ß
ENaC subunits in Xenopus oocytes. Ionic currents through wt and mutant channels were completely blocked by 100 µM amiloride. The K+ over Na+ selectivity of the
S589 mutants was determined by the amiloride-sensitive current ratio (IK/INa) obtained at -100 mV in the presence of external Na+ (120 mM) and after Na+ substitution by K+ ions, as shown in Table 1. Increasing the size of the substituting amino acid side chain at position
589 increased the channel permeability to K+, as shown by the IK/INa ratio. The
S589H substitution mutation that represents a 60% increase in the residue's volume renders the channel nonselective between K+ and Na+. Changes in the K+ over Na+ selectivity were further evidenced from measurements of reversal potentials of the currents of
S589 mutants in the presence of extracellular Na+ or K+ solution. Fig 2 shows the current-voltage relationship of amiloride-sensitive currents in the presence of extracellular Na+ and K+ of ENaC with substitutions of
S589. INa and IK were normalized in each experiment to INa at -100 mV. The current-voltage relationship with extracellular Na+ solution is similar in wt and the
S589A,
S589C, and
S589N ENaC mutants. However, no inward K+ current could be measured in ENaC wt even at potentials more negative than -100 mV. IK was low in
S589A, intermediate in
S589C and almost equal to INa in
S589N. The K+/Na+ permeability ratio calculated from the difference of the reversal potential in extracellular K+ and Na+ solution, respectively, is 0.01 for wt, 0.02 for
S589A, 0.24 for
S589C, and 0.56 for
S589N (
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The S589 mutations tend to decrease INa with increasing size of the substituting amino acid, and for substitutions with residues larger than His (
118 Å3), no amiloride-sensitive current could be detected (Table 1). To determine whether the absence of INa observed with expression of the large
S589 substitution mutants is due to nonpermeant channels at the cell surface or to alterations in the biosynthesis of these mutants, we have compared the surface expression of selected
S589 mutant channels with ENaC wt. Wild-type and mutant ENaC channels were tagged with FLAG epitopes in the extracellular domain, and binding of the iodinated anti-FLAG antibody to intact oocytes was measured (
subunits (
ßF
F) increased surface binding of anti-FLAG mAb to 8.4 ± 1.9-fold over noninjected oocytes. Coexpression of
S589 mutants with flagged ß and
subunits increased the mAb binding 6.0 ± 1.6-fold over noninjected oocytes for
S589A and 8.6 ± 4.5-fold with
S589C (n = 1248 oocytes). No significant binding was detected for the nonfunctional mutants
S589V,
S589L, and
S589W (e.g., the ratio was 1.1 ± 0.4 for
S589V, 1.6 ± 0.6 for
S589L, and 0.9 ± 0.3 for
S589W, n = 1218 oocytes), indicating the absence of channels at the cell surface.
The absence of cell-surface expression of S589V,
S589L, and
S589W mutants is not due to an impaired translation of the mutant subunit. After solubilization from oocytes expressing wt
ß
or the mutant
S589 subunits with wt ß
ENaC, wt and mutant
subunits could be detected on Western blots using an antirat
ENaC antibody (
subunits to assemble with ß subunits was tested by coimmunoprecipitation experiments in oocytes coexpressing the wt or mutant
subunits with ß subunits that carry a FLAG epitope, i.e.,
ßF
,
S589VßF
,
S589LßF
,
S589WßF
, and as a negative control, ßF
(
ENaC antibody. An
ENaC-specific band was detected with
ßF
and
S589V/L/WßF
but not ßF
(Fig 3 B), indicating that the mutant subunits
S589V,
S589L, and
S589W retain their ability to assemble with ß subunits. Thus, mutant
subunits with large amino acid substitutions at position
589 retain some ability to assemble with the ß subunit but do not reach the cell surface.
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Permeability of ENaC Mutants to Inorganic Cations
We have initially hypothesized that the increase in channel permeability to K+ of the S589 mutants was due to changes in the pore diameter (
S589G,
S589Q,
S589N, and
S589H, the ones with the highest permeability to K+ ions also show the highest conductance for Rb+ and Cs+. For all the mutants tested, the permeability sequence follows the size of the permeant ions, i.e., Na+
K+ > Rb+ > Cs+ (Table 2). These results confirm the observation for amino acid substitutions of smaller sizes at position
S589, i.e.,
S589A,
S589C, and
S589D (
S589 mutations with larger side chain residues increase in pore diameter at the selectivity filter. For K+, Rb+, and Cs+ ions that are similar in size (Pauling diam, 2.73.4 Å), the permeability in
S589 mutants is inversely correlated with the size of the ion. This is demonstrated in Fig 4 B, where the relationship between the relative permeability of the cation and its diameter is fitted by a simple equation that describes permeation based purely on molecular sieving (
S589 mutants (Fig 4 B), indicating that mechanisms other than geometrical and frictional effects are critical for Na+ permeability. The fact that Na+ permeability is lower than expected for its diameter in the mutants
S589N and
S589H suggests that the selectivity filter becomes less favorable for permeation of Na+ ions when its diameter becomes larger. Such an effect could also contribute to the lower macroscopic INa expressed by the
S589 mutants with large amino acid substitutions (Table 1).
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To test the possibility that the larger pore diameter makes it more difficult for small ions such as Na+ and Li+ to permeate the channel, we have performed single-channel recordings of different S589 substitution mutants. Patch-clamp recordings of the functional
S589 mutants showed that the unitary conductance for Li+ and Na+ decreased with the increasing size of the substituent amino acid (Fig 5 and Table 1). For instance, the single-channel Li+ conductance was 9.0 pS for wt, 7.8 pS for
S589G, 1.5 pS for
S589C, and 1.9 pS for
S589Q, and <1 pS for the mutants
S589N and
S589H where single-channel openings could not be resolved. Thus, it appears that increasing the pore diameter at the selectivity filter with
S589 substitutions allows larger cations to permeate the channel to the prejudice of smaller ions such as Na+ or Li+.
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Permeability of ENaC Mutants to Organic Cations
Organic cations such as ammonium and its methyl derivatives methyl-, dimethyl-, and trimethylammonium (MA, DMA, and TriMA) or guanidine have been used to estimate the minimum diameter of the pore of channels such as voltage-gated Na+, K+, and Ca2+ channels (S589 mutants, the amiloride-sensitive current carried by organic cations was measured at -100 mV and normalized to INa. Fig 6 A shows the current-voltage relationship of the amiloride-sensitive current carried by Na+ or NH4+ ions in oocytes expressing either ENaC wt or the
S589D mutant. Both, ENaC wt and the
S589 mutant show clear inward Na+ currents (Fig 6 A, closed symbols). The
S589D Na+ current shows a strong inward rectification, which is due to the fact that the expression level of the mutant compared with the wt was low in this experiment and intracellular Na+ concentration was much lower in the mutant compared with the wt (
S589D (Fig 6 A, open circles). All
S589 mutants are permeant to NH4+, as shown in Fig 6 B. The permeability ratios of the
S589 mutants for K+ or NH4+ ions are comparable, and as for K+ ions, the channel permeability to NH4+ increases with the size of the residue at position
S589 (Table 1). Regarding ammonium derivatives, the smaller substitution mutants (
S589G/A/C/D) are not permeable to any of the ammonium derivatives.
S589N is only permeant to the smallest derivative, MA, and
S589Q and
S589H show significant but low permeability to all three derivatives tested (MA, DMA, and TriMA; Fig 6 B).
S589C, D, N, Q, and H are permeable to guanidine.
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The permeability data obtained with organic and inorganic cations from all functional S589 mutants are summarized in Fig 7. In this representation, the ions are aligned according to their increasing size from left to right (Fig 7 legend) and the mutants are shown with increasing volume of the substituting amino acid from front to back. Fig 7 illustrates two aspects of organic and inorganic cation permeability of
S589 mutants. First, substitution of
S589 by large amino acid residues increases the relative permeability of large inorganic and organic cations, i.e., increasing the size of the amino acid at position
589 increases the pore diameter. Second, large cations have generally a lower permeability than small cations (Table 2). NH4+ and guanidine carry higher currents than expected from their size. For the functional mutants with substituting residues larger than Ser, there is a significant correlation between the increase in volume of the amino acid and the relative permeability to K+ and NH4+. Only for the
S589Q mutant, the K+ and NH4+ permeability relative to Na+ is lower than expected from its size. However, the
S589Q mutant still remains highly permeant to large cations such as K+ and NH4+, which is consistent with the general conclusion that substitution of
S589 by large amino acids increases the pore diameter at the selectivity filer. The particularity of the
S589Q mutant indicates that the size of the residue at position
589 is not the only determinant of the pore diameter at the selectivity filter. Regarding the second observation addressed here, we found, in most mutants, a relative permeability for NH4+ and guanidine that was higher than expected from their size. NH4+ is somewhat flexible due to its ability to form hydrogen bonds (see DISCUSSION). Guanidine is of a similar size as TriMA, but is a planar molecule in contrast to the more spherical shape of ammonium derivatives.
S589C, D, N, Q, and H are permeable to guanidine. The highest guanidine permeability ratio was obtained for
S589H (Iguanidine/INa = 0.54 ± 0.03, n =10; Fig 6 B). The higher guanidine permeability relative to ammonium derivatives in the
S589C, D, N, and H mutants suggests that the pore at the selectivity filter of these mutants is not completely symmetrical but has the shape of a slotlike rectangle.
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In addition to mutations of S589, mutations of ßG529 to Ser, Cys, and Asp (but not mutations to Ala and Arg) make ENaC permeable to K+. The IK/INa ratio was
0.2 for ßG529D and ßG529S and 0.06 for ßG529C (
S589 mutations in which these ßG529 mutations change the ionic selectivity by enlarging the pore. The low permeability to large cations indicates that the ßG529 mutations enlarge the pore by less than the
S589 mutations.
Coexpression of S589N with ßG529S and wt
yielded a channel with reduced but still detectable current expression with an amiloride-sensitive Na+ current at -100 mV of 0.1 ± 0.05 µA. The current ratio IK/INa was 1.46 ± 0.23 (n = 4), showing a slightly higher selectivity to K+ ions than the single substitution mutant
S589N. Thus, the effects of the
S589 and ßG529 mutations on channel permeability to K+ ions are additive, as expected for
and ß subunits lining the channel pore and contributing to the selectivity filter.
Contributions of the Second Transmembrane Segment M2 and the Intracellular COOH Terminus to Ionic Selectivity
The increase in relative channel permeability to large cations in S589 mutants indicates that
S589 is part of the selectivity filter. Adjacent residues not directly facing the pore lumen might also contribute to the ionic selectivity of the channel by holding the selectivity filter in place and at the correct diameter. In addition it is possible that other amino acids along the ion permeation pathway may contribute to ion selectivity. We have replaced systematically all residues from L591 to M610 in the putative M2 segment of the
subunit with Cys residues to investigate the role of the second membrane-spanning segment M2 in ion selectivity. We have tested the accessibility of these engineered Cys residues to extracellularly applied sulfhydryl reagents. The hydrophilic sulfhydryl reagent MTSEA attaches covalently and selectively a charged group to Cys residues. If a substituted Cys residue lies on the water-accessible surface of the external pore, it should react with MTSEA, which would affect ionic current. The ratio of the INa after a 2-min extracellular application of 2.5 mM MTSEA relative to the initial INa was 0.77 ± 0.33 for ENaC wt and was not significantly different for the mutants (unpublished data). This suggests that the Cys residues in the M2 segment of
ENaC are not accessible to extracellular MTSEA, or that their modification does not change channel function, in contrast to residues in the preM2 segment of the ENaC subunits (
subunits, all mutants apart from
E598C produced functional channels. However, mutation
E598A was functional and was not different from wt with regard to ion selectivity and amiloride block. The mutants
L591C to
M610C exhibit a IK/INa in the range of 0.000.03 compared with 0.01 ± 0.00 of ENaC wt, indicating that the M2 segment of
ENaC does not contribute significantly to the ionic selectivity of the channel (Table 1).
It was recently reported that truncation of the COOH terminus of rat ENaC at residue R613 changed the Li+ single-channel conductance and the Li+/K+ selectivity as determined from macroscopic currents (
R613Xß
ENaC expressed in Xenopus oocytes. The unitary conductance, measured in outside-out patches was 4.7 ± 0.2 pS for Na+ and 8.0 ± 0.4 pS for Li+ (n = 5 patches each), directly compared with 4.6 ± 0.2 pS (Na+) and 8.8 ± 0.4 pS (Li+; n = 2 patches each) for ENaC wt. The
R613Xß
mutant remained totally impermeant to K+ ions, as shown by the macroscopic current ratio IK/INa at -100 mV of zero as for ENaC wt. Thus, we have no indication that residues within the intracellular COOH terminus or M2 determine ion selectivity or unitary conductance. Therefore, we conclude that the selectivity filter is restricted to
G587
S589 and the analogous residues in ß and
subunits.
Amiloride Sensitivity
Amiloride is a pore blocker and interacts with the permeating ions. We have addressed the possibility that in addition to changing ion selectivity S589 mutations might also affect channel block by amiloride, since amiloride binds in the preM2 segment in the proximity of the selectivity filter (Fig 1). We have analyzed the block by amiloride of currents generated by all
S589 mutants. In most mutants, amiloride block was not different from wt, except for
S589N, which marginally increased the IC50 and
S589H, which increased the IC50 for amiloride block by a factor of 16. With Na+ as the main extracellular cation, the IC50 for amiloride block was 0.44 ± 0.05 and 2.80 ± 0.65 µM for
S589N and
S589H, respectively, compared with 0.18 ± 0.08 µM for ENaC wt (n = 616). The important structural changes of the selectivity filter induced by the
S589H mutation that enlarges the channel pore allowing large cations to pass may extend to the nearby amiloride binding site and also impair channel block. We measured amiloride block of the NH4+ current for two mutants,
S589D and
S589N. The IC50 values for amiloride block of the NH4+ current were 0.10 ± 0.02 and 0.19 ± 0.06 µM for
S589D and
S589N, respectively (n = 67 each), indicating that amiloride blocks NH4+ currents with similar affinity as currents carried by Na+. The Cys substitution mutations in the M2 segment have no effect on amiloride block with an IC50 for the mutants
L591C to
M610C ranging from 0.06 to 0.33 µM (unpublished data).
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DISCUSSION |
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It was initially found that mutations of two residues, S589 and ßG529, change Na+/K+ selectivity and make ENaC permeable to K+ and to a lesser extent to Rb+ and Cs+ (
G587C at the position homologous to ßG529 (
S542C at the position homologous to
S589 (
S589 and ßG529 mutations are due to an enlargement of the pore at the selectivity filter. Substitutions of
S589 by a variety of amino acids of different volume and subsequent analysis of the permeability of these mutant channels to different organic and inorganic cations of varying sizes show that the larger the substituting amino acid at position
589, the easier it becomes for large organic and inorganic cations to permeate the channel. Enlargement of the pore at the selectivity filter not only allows large cations to permeate ENaC mutants, but also decreases channel permeability to small cations such as Na+ or Li+ ions. Thus, the pore size at the
S589 residue is critical for the selectivity properties of ENaC
Ion Selectivity in wt and Mutant ENaC
Ionic selectivity of ENaC wt allows Na+ and smaller cations such as Li+ and H+ to permeate the pore, whereas large cations such as K+, Rb+, and Cs+ are excluded (S583 and the corresponding residues ßG525 and
G537), but do not pass the selectivity filter. Thus, the outer pore of ENaC acts as a molecular sieve to discriminate among inorganic cations.
What are the consequences of enlarging the channel pore at the selectivity filter on the ion permeation properties of ENaC? Enlargement of the channel pore at the selectivity filter due to substitutions of S589 by bulkier residues allows larger cations to pass through the selectivity filter (
S589 mutants, the permeability to K+, Rb+, and Cs+ still depends on the relative size of the ion and of the pore as supported by the fit to the molecular sieving model (Fig 4 B). However, enlargement of the pore is also associated with a decrease in permeability to small ions such as Na+ and Li+. We observed that the permeability to Na+ relative to K+ ions of the
S589H and
S589N mutants is lower than expected for the size of Na+ ions from the fit to the hydrodynamic model (Fig 4 B). But more importantly, we demonstrated a reduction in the single-channel conductance for Li+ and Na+ ions in
S589 ENaC mutants that is inversely related to the increase in channel permeability to K+, Rb+, and Cs+ ions. These two observations indicate that the higher the permeability of the
S589 mutant becomes to larger cations such as K+, Rb+, or Cs+, the more difficult it is for small ions such as Na+ and Li+ to permeate the channel. Thus, the geometry of the ENaC pore at the selectivity filter is critical for the relative permeability to Na+ over K+ and larger ions. A similar but more direct conclusion came from the solution of the 3-D structure of the K+ channel KcsA. All K+ channels show a selectivity sequence of K+
Rb+ > Cs+, whereas permeability for the smallest alkali metal cations Na+ and Li+ is immeasurably low. In the KcsA channel, the high selectivity for K+ over smaller ions (Li+ and Na+) is based on the tight interaction of the permeating K+ ion with the carbonyl oxygens of the backbone of the GYG sequence that lines the selectivity filter (
S589 mutants, accommodation of a Na+ ion in the selectivity filter likely becomes energetically less favorable because of a lower interaction energy with the pore-lining residues, resulting in the observed decrease in unitary conductance.
Permeability to Organic Cations
NH4+ and its methyl derivatives, MA, DMA, and TriMA, all have the same basic geometry and differ only by the substitution of methyl groups for hydrogen atoms. Examples of channel proteins that select this series of cations entirely by molecular sieving are the nicotinic acetylcholine receptor (S589 ENaC mutants to NH4+ and its methyl derivatives did not show a graded decrease in permeability with increasing size of the ion (Fig 6 and Fig 7 and Table 2). All
S589 mutants except for
S589G and
S589A have a high permeability to NH4+ and all of these mutants are not, or only slightly, permeable to the methyl derivatives of ammonium. This suggests that factors such as the shape of the ion and the interaction between the ion and the pore-lining residues codetermine ionic permeability in ENaC
S589 mutants. The magnitude of the current carried by NH4+ (INH4) is in many
S589 mutants similar to IK despite the fact that NH4+ is larger than K+, Rb+, and Cs+ ions (diam = 3.6 Å;
S589 mutants suggests that NH4+ indeed does form hydrogen bonds in the ENaC pore. Due to this flexibility, NH4+ can adapt to different pore conformations, resulting in a higher permeability in
S589N or
S589H for NH4+ compared with Na+ or K+ ions. NH4+ can, in principle, form hydrogen bonds either with carbonyl oxygens of the peptide backbone of the residue at position
589 or in the case of the mutants
S589D,
S589Q, and
S589H with the oxygen of the side chain. High permeability to NH4+ was not only observed in the substitution mutants containing oxygens in the
589 side chain, but also in mutants without oxygens in the side chain at positions
S589 and ßG529 (
S589C/H mutants as well as ßG529C/S mutants). To explain the high NH4+ permeability of the latter mutants, the carbonyl oxygens have to be involved in hydrogen bonds with NH4+, supporting the hypothesis that, as for the KcsA channel, the carbonyl residues of
S589 line the channel pore at the selectivity filter.
An Estimate of the Size of the ENaC Pore
An estimate of the minimum diameter of the wt and mutant ENaC selectivity filter can be obtained from the largest permeant and the smallest nonpermeant ion. It is assumed that ions permeating highly selective channels are completely dehydrated or carry at most one water molecule with them in the narrowest part of the pore (S589A and
S589G, which are permeant to K+ but not to Rb+, is estimated to be between 2.7 and 3.0 Å, and that of
S589C (permeant to Rb+ but not to Cs+) is between 3.0 and 3.4 Å. The fits to the relationship between the alkali cation permeability and the ion diameter in
S589 mutants that are permeant to Cs+ (Fig 4 B) predict a pore radius in these mutants of the range of 3.5 (
S589D) to 4.4 Å (
S589H).
The organic cations that we have tested are not perfect spheres as the alkali metal cations. Judged from their minimum diameter, i.e., the smallest possible diameter of a circular pore through which the molecule would pass, all organic cations tested are larger than Cs+ (S589C mutant which is not permeable to Cs+ (3.4 Å) and the fact that guanidine has a higher permeability than NH4+ derivatives in the
S589N, Q and H mutants indicate that the pore of mutant ENaC rather forms a slotlike rectangle. Voltage-gated Na+ channels are permeable to NH4+ (INH4/INa =
0.2), to guanidine and to some of its derivatives but not to methyl derivatives of ammonium (
S589 mutants appears to be closer to that of voltage-gated Na+ than K+ channels.
Model of the ENaC Pore
There is good evidence that the preM2 segments of ENaC subunits line the outer part of the channel pore. The preM2 segments contain the binding site for the pore blocker amiloride, S583 in and homologous residues in ß and
ENaC (
5 Å;
587 and corresponding positions in ß and
subunits have dramatic effects on single channel conductance and ENaC affinity for Na+ and Li+ ions, indicating that these residues tightly interact with the permeating ions. The residue
S589 that determines the channel permeability cutoff is in the continuation of the amiloride binding site (position
S583) and the Na+/Li+ binding site (position
G587). The 583589 sequence might represent a ß sheet structure that precedes the putative transmembrane spanning M2 helix and lines the outer ion channel pore. It is quite understandable that introducing large residues such as His at position
589 induce steric changes in the pore with consequences on channel block by amiloride. All other functional
S589 mutants preserved the high affinity of ENaC wt for amiloride block, indicating that the selectivity filter does not overlap with the amiloride binding site.
How do substitutions of S589 by large residues increase the diameter of the pore and facilitate the passage of large organic cations such as ammonium or guanidine? This effect on the pore size is only possible if the side chain of residue
S589 points away from the pore lumen. Thus, most likely the carbonyl oxygens of the peptide backbone face the pore lumen to accommodate permeating cations. This orientation of the carbonyl oxygens is also suggested by the high permeability of NH4+ in
S589 mutants. This orientation of the polypeptide is similar to the KcsA channel in which the carbonyl oxygens are exposed to the pore lumen and the side chains of the amino acids point away from the pore. The side chain of
S589 and of the homologous Ser residues in ß and
subunits may point toward the interface between the subunits. Fig 8 illustrates possible steric changes that may occur when
S589 is replaced by larger residues. This figure shows schematically a cross-section of the channel pore at residue
S589 in wt ENaC (Fig 8, left) and the
S589N mutant (Fig 8, right). The carbonyl oxygens of the polypeptide backbone, shown as hatched circles, face the pore lumen. In our model, the side chains of the residues at position
589 and the homologous positions in ß and
ENaC, identified by the dark border, are oriented toward the subunit interface. Increasing the size of the residue at position
589 pushes the backbone of the ß and
subunits away from the pore lumen, leading to an enlargement of the pore diameter (Fig 8, right). Due to the
-ß-
-
subunit arrangement around the channel pore, large amino acid substitutions at the
-ß and
-
subunit interface may result in changes in the pore diameter predominantly in the direction of one axis (
S589 mutants. We have shown that larger substituting residues of
S589 lead to a wider pore at the selectivity filter and that the enlargement depends on the size of the residue (Table 1). The only exception from this rule is the
S589Q mutant that shows a lower permeability to large cations such as K+ and NH4+ than expected from its size, although this mutant is still highly permeant to K+ and NH4+. This indicates that the size of the residue at position
589 is not the only determinant of the pore diameter. Other factors such as interactions between
S589 and adjacent residues may also control the diameter of the channel pore at the selectivity filter. These factors are not considered in our model. Substitution of
S589 by smaller residues such as Gly and Ala resulted in an increased K+ permeability. This observation suggests that other structures in the selectivity filter prevent the pore from collapsing when
S589 is replaced with smaller residues.
|
Mutations at position 529 of the ß subunit resulted in a smaller pore enlargement compared with S589 mutations. This can be explained by the fact that there is one ß subunit in an ENaC tetramer compared with two
subunits (
S589 (Fig 1).
In this context, it is interesting to note that the substitution of S589 by amino acids with a van der Waals volume
118 Å3 is not compatible with channel function at the cell surface (Table 1). Given the steric effects of the
S589 mutations on the pore geometry it is possible that substitution by large amino acids prevents correct folding and assembly of subunits in the ER. Such changes in the ENaC biosynthetic process would direct the channel to degradation by a quality control in the ER. Mutation of the Ser homologous to
S589 has been shown to result in nonfunctional channels in other ENaC/DEG family members, DEG-1 (
ENaC, S562, to leu was found in a patient with pseudohypoaldosteronism type 1, which is consistent with loss of channel function (
We use here a model of the channel pore that is based on the tetrameric stoichiometry of ENaC (
It is not clear what the structures are that interact with the external channel pore to maintain the selectivity filter at the proper diameter and position. It is conceivable that mutations within these neighboring structures also affect channel ionic selectivity. The predicted transmembrane segment M2 could be part of this scaffold, or it might form the continuation of the pore. Our mutagenesis screen shows that M2 is not involved in ion discrimination. This transmembrane domain of the ENaC subunit is not accessible to extracellular sulfhydryl reagents. We extended our mutational analysis to the cytoplasmic COOH terminus of the subunit because truncation of this region was recently claimed to influence ionic selectivity and single-channel conductance (
COOH terminus truncation has no effect on the permeation properties of the channel. Together, these observations indicate that the ion-selective region of ENaC is restricted to a short sequence of three residues in the preM2 segment that represents the narrowest part of the external channel pore.
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Footnotes |
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* Abbreviations used in this paper: DEG, degenerin; DMA, dimethylammonium; ENaC, epithelial Na+ channel; ILi, amiloride-sensitive Li+ current; INa, amiloride-sensitive Na+ current; INH4, amiloride-sensitive NH4+ current; M2, second transmembrane domain; M2Ab, anti-FLAG M2 mouse mAb; pre-M2, segment NH2-terminal of M2; MA, methylammonium; MTSEA, aminoethyl methanethiosulfate; TriMA, trimethylammonium; wt, wild type.
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Acknowledgements |
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We thank J.-D. Horisberger and P. Greasely for critical reading of the manuscript.
This work was supported by a grant from the Swiss National Foundation for Scientific Research (to L. Schild, No. 3100-059217.99).
Submitted: 10 May 2001
Revised: 19 October 2001
Accepted: 22 October 2001
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References |
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