Residues Lining the Inner Pore Vestibule of Human Muscle Chloride Channels*

Christoph FahlkeDagger §||, Reshma R. DesaiDagger , Niloufar GillaniDagger , and Alfred L. George Jr.Dagger

From the Dagger  Departments of Pharmacology and Medicine, Vanderbilt University School of Medicine, Nashville, Tennessee 37232, § RWTH Aachen, Institute of Physiology, 52057 Aachen, Germany, and  Centro de Estudios Cientificos (CECS), Avenida Prat 514, Valdivia, Chile

Received for publication, August 22, 2000, and in revised form, September 28, 2000



    ABSTRACT
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Chloride channels belonging to the ClC family are ubiquitous and participate in a wide variety of physiological and pathophysiological processes. To define sequence segments in ClC channels that contribute to the formation of their ion conduction pathway, we employed a combination of site-directed mutagenesis, heterologous expression, patch clamp recordings, and chemical modification of the human muscle ClC isoform, hClC-1. We demonstrate that a highly conserved 8-amino acid motif (P3) located in the linker between transmembrane domains D2 and D3 contributes to the formation of a wide pore vestibule facing the cell interior. Similar to a previously defined pore region (P1 region), this segment functionally interacts with the corresponding segment of the contralateral subunit. The use of cysteine-specific reagents of different size revealed marked differences in the diameter of pore-forming regions implying that ClC channels exhibit a pore architecture quite similar to that of certain cation channels, in which a narrow constriction containing major structural determinants of ion selectivity is neighbored by wide vestibules on both sides of the membrane.



    INTRODUCTION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The ClC family of voltage-gated Cl- channels represents the largest known gene family coding for anion channels (1-3). At least nine human isoforms (ClC-1 to ClC-7, ClC-Ka, and ClC-Kb) are expressed in various tissues and play important roles in the function of various organs. Mutations in the genes coding for three ClC isoforms cause inherited human diseases. CLCN1 represents the genetic locus for myotonia congenita (4, 5), a muscle disease characterized by stiffness upon sudden forceful movement. Mutations in CLCN5 cause Dent's disease, an inherited renal disorder associated with hypercalciuria, nephrolithiasis, and low molecular weight proteinuria (6). Genetic alterations of CLCNKB are responsible for type III Bartter's syndrome, a salt-wasting renal tubular disorder causing hypovolemia, hyponatremia, and hypotension (7).

Heterologous expression of many cloned ClC isoforms have revealed highly anion-selective ion channels, and it is therefore reasonable to predict that evolutionarily conserved structures confer anion selectivity to their ion conduction pathways. Elucidating the molecular mechanisms responsible for ion selectivity and conduction in ClC channels is key to understanding the function and dysfunction of this important family of ion channels. Moreover, primary sequence information about the ionic pore represents the first step for a rationally designing compounds to block or open these ion channels that play important roles in human diseases.

We recently probed the ion conduction pathway of human ClC-1 in the presence of several different permeant anions (8), and we demonstrated an unusual ion selectivity mechanism that depends upon differential ion binding to discriminate among anions (8, 9). Human ClC-1 (hClC-1)1 exhibits at least two functionally distinct ion binding sites within the pore (8, 10), both preferring large and polyatomic anions over chloride. The tighter binding of these anions reduces their turnover, resulting in lower permeability and conductivity, thus making chloride the most permeant anion (8, 9). This selectivity mechanism requires that binding sites within the hClC-1 pore exhibit only a low affinity for permeating anions to allow a measurable ion flow per unit of time. In agreement with this prediction, an evaluation of the blocking action of iodide in hClC-1 revealed dissociation constants in the millimolar range (8, 10). Because iodide binds more tightly than chloride, this value represents a lower limit for the chloride dissociation constant and demonstrates that ClC-type channels bind anions with affinities that are more than an order of magnitude lower than the values with which potassium (11) and calcium channels (12) interact with their respective permeant ions. This result suggests that anions probably do not make intimate contact with pore-lining residues during permeation through the hClC-1 pore.

The peculiar nature of anion selectivity in ClC channels poses a particular problem for approaches using a combination of site-directed mutagenesis and cellular electrophysiology to identify pore residues. Allosteric and other long range effects of point mutations can have considerable influence on the interaction between channel and permeant anion and thus on selectivity and single channel amplitude. An effect of a single amino exchange on ion conduction properties is therefore not sufficient to establish that a region contributes to the formation of the ion conduction pathway, and indeed point mutations at various locations within the ClC channel sequence affect anion selectivity (13-17). It is therefore necessary to use additional experimental tests to identify pore-forming regions of ClC channels.

We have previously employed a combination of several methods to identify two regions within hClC-1 that line a portion of the ion conduction pathway and represent major structural determinants of ion selectivity. A highly conserved 8-amino acid sequence present in every known eukaryotic ClC channel (GKXGPXXH) lines the most narrow part of the ClC pore. The P1 region is a major determinant of the binding affinities for anions (15) and is responsible for the high anion to cation selectivity of hClC-1 (18). Within the fifth transmembrane domain (D5), we have identified another highly conserved amino acid region, GVLFSI in hClC-1 (designated as P2), that together with P1 lines the narrow part of the of pore (18). In the present study, we extend our investigation to another highly conserved segment, the linker region between transmembrane domain 2 (D2) and 3 (D3). This segment was previously demonstrated to have a single residue that can influence single channel conductance of ClC-0 (16), but a systematic evaluation of this region was lacking. We now provide further evidence that this segment is important for ion selectivity, and we provide evidence that this region contributes to the formation of a wide inner pore vestibule.


    MATERIALS AND METHODS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Mutagenesis and Construction of Heterodimers-- Site-specific mutants were constructed using recombinant polymerase chain mutagenesis. Monomeric constructs were assembled in the expression construct pRc/CMV-hClC-1, and dimers were constructed as described previously (19). We then sequenced in both constructs regions modified by polymerase chain reaction completely to exclude polymerase errors. At least two independent recombinants were examined functionally for each mutant or dimer. Transient transfection of tsA201 was performed as described previously (15, 19).

Electrophysiology-- Standard whole-cell, inside-out, or outside-out patch clamp recordings (20) were performed using an Axopatch 200A amplifier (Axon Instruments, Foster City, CA). Pipettes were pulled from borosilicate glass and had resistances of 0.8-2.2 MOmega . More than 80% of the series resistance was compensated by an analog procedure. The calculated voltage error due to series resistance was always <5 mV. Currents were filtered with an internal 4-pole Bessel filter with 1 kHz (-3 dB) and digitized with sampling rates of 5 kHz using a Digidata AD/DA converter (Axon Instruments, Foster City, CA). Cells were clamped to 0 mV for at least 5 s between two test sweeps. The compositions of the solutions were as follows: extracellular solution (in mM), NaCl (140), KCl (4), CaCl2 (2), MgCl2 (1), HEPES (5), pH 7.4; intracellular (in mM), NaCl (130), MgCl2 (2), EGTA (5), HEPES (10), pH 7.4. Anion permeability ratios were determined as described previously (15). Data were analyzed by a combination of pClamp (Axon Instruments, Foster City, CA) and SigmaPlot (Jandel Scientific, San Rafael, CA) programs. All data are shown as means ± S.E. from at least three different experiments.

Modification with MTS Reagents-- 2-Aminoethyl-methanethiosulfonate, methylethiosulfonate-ethyltrimethylammonium (MTSET), and -ethylsulfonate (MTSES) were obtained from Toronto Research Chemicals (New York, Ontario, Canada). Stock solutions (0.1 M) were prepared in distilled water, stored at -20 °C, and diluted into the bath solution immediately before use. Cells/patches were held at 0 mV and stimulated every 5 s to voltage steps to +75 mV followed by -105 mV. Typically, 20 cycles were employed to assess control values (Icontrol). Then MTS-reagents were applied to cells/patches by moving the cell/patch into the stream of a silane-treated macropipette filled with MTS-containing solution. After 3 min or after reaching a steady-state current amplitude, cells/patches were moved out of the stream to visualize reversible effects and to measure the current amplitude after irreversible modification (Imodified). The relative current reduction was measured as 1 - Imodified/Icontrol. The time course of modification was fit with a single exponential giving the time constant of modification. The pseudo-first order rate constant was calculated as the inverse of the modification time constant. Dividing by the concentration of the MTS reagents provided the second order rate constants. The charge selectivity of the access pathway for MTS reagents was calculated by dividing the second order reaction rates for MTSES by the rate for MTSET (kMTSES/kMTSET) and normalizing this value to the relative reactivity of the two reagents with thiols in aqueous solution 0.08 (21). For experiments testing the effect of SCN- on MTS modification, 50 mM NaCl were substituted by equimolar amounts of NaSCN.


    RESULTS
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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

D2-D3 Linker Lines the Inner Mouth of the hClC-1 Pore-- All known ClC channels exhibit a conserved sequence motif between transmembrane domains D2 and D3 that has the sequence GSGIPEMK in hClC-1 (Fig. 1). Earlier experiments demonstrated that an amino acid exchange within this region (S123T) changes the single channel amplitude and the conductivity sequence of ClC-0 (16). The high degree of sequence conservation together with the observed effect of a single point mutation on ClC-0 conduction properties makes this segment (P3) a candidate pore-forming region. To investigate further the role of P3 in formation of the ion conduction pathway, we constructed single cysteine substitutions for each residue in the region and evaluated these mutants using the patch clamp technique and chemical modification with cysteine-specific methanethiosulfonate (MTS) reagents.



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Fig. 1.   Evolutionary conservation of the GSGXXXXK motif in P3.

Fig. 2 illustrates representative macroscopic current recordings from each of the 8 single cysteine mutants, obtained using either whole-cell (Fig. 2A) or excised inside-out recordings from transiently transfected tsA201 cells (Fig. 2, B-H). All mutants were functional in transiently transfected tsA201 cells exhibiting large whole-cell current levels with maximum outward current amplitudes of several nA. With the exception of G188C, all mutants expressed at levels high enough to permit recording of large amplitude macroscopic currents in excised patches. Except for slight alterations in the voltage dependence of activation and the time course of deactivation (data not shown), all displayed gating properties very similar to wild-type (WT) hClC-1 (22). In addition, all mutants exhibited an inwardly rectifying instantaneous current-voltage relationship that is characteristic of hClC-1. We conclude that cysteine substitutions within P3 do not disturb the general functional behavior of hClC-1, and this provides evidence that the mutations do not cause major structural rearrangements in the channel.



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Fig. 2.   The effect of cysteine substitution within the P3 region. Current recordings from mutant hClC-1 channels. For each construct, voltage steps between -165 mV and +75 mV in 60-mV steps were applied from a holding potential of 0 mV. Each test pulse is followed by a fixed -105-mV pulse. Whole-cell recordings are shown for G188C (A); and excised inside-out patches were used for S189C (B), G190C (C), I191C (D), P192C (E), E193C (F), M194C (G), and K195C (H).

To test for alterations of the relative anion permeability sequence, reversal potentials were determined from cells internally perfused with standard internal solution and bathed in external solutions in which 140 mM NaCl was substituted with equimolar sodium salts of Br-, I-, NO3-, SCN-. Permeability ratios were then calculated using the Goldman-Hodgkin-Katz equation (15, 18) (Table I). Mutations of P3 residues affect the relative anion permeability ratios. These effects are most dramatic for mutations G188C and S189C, whereas cysteine substitutions at other locations only affect the relative thiocyanate to chloride permeability ratio. Replacement of lysine 195 has only minor effects on anion selectivity suggesting that this positively charged side chain does not play a major role in hClC-1 selectivity.


                              
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Table I
Permeability ratios and ion selectivity sequences for WT hClC-1 and mutants

Regions that contribute to the formation of an ion channel conduction pathway contain residues that are in contact with the aqueous environment. To test whether substituted cysteines within P3 project their side chains into an aqueous cavity, we examined the mutants for reactivity to hydrophilic cysteine-specific MTS reagents (18, 23). For these experiments, patches/cells were held at 0 mV and stimulated every 5 s with a pulse consisting of a voltage step to +75 mV followed by a -105-mV step. After 20 steps in standard solution, the patch/cell was moved into a stream of a solution containing the MTS reagent at the given concentration. The time course of the instantaneous as well as of the late current amplitudes for the +75-mV and the -105-mV step were determined by plotting the amplitudes versus the time since the beginning of the MTS application. Three minutes later or after reaching a steady-state current amplitude, patches/cells were moved out of the stream to visualize reversible effects. For WT hClC-1 channels, there is no change of any of these current amplitudes, neither by internally nor externally applied MTS reagents (Fig. 3A) (18). Similarly, external application of MTSES or MTSET does not have functional effects on any of the eight cysteine-substituted channels, and this is compatible with the predicted intracellular location of P3.



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Fig. 3.   Substituted cysteine accessibility experiments. A, relative current change for substituted cysteine between S189C and K195C following application of intracellular MTSES (open bars) or MTSET (solid bars). For G188C, G190C, and I191C the relative changes of the instantaneous current amplitude at -105 mV are shown; for the remaining mutants the relative current amplitude changes at the +75 mV step. B, reaction rates for modification of these cysteines by MTSES or MTSET. C, relative anion selectivity of the access pathway for MTS reagents to four different substituted cysteines. All data were obtained from excised inside-out (for application of MTS reagents to the intracellular membrane side) or outside-out (for application of MTS-reagents to the extracellular membrane side) patch clamp recordings.

For internal application, MTS modification could be observed for S189C, G190C, I191C, P192C, E193C, and K195C. Two types of functional alterations could be observed in these experiments. For mutants G190C and I191C, a time-dependent decrease of instantaneous as well as of the late current amplitudes at +75 and -105 mV occurred after application of MTS components. The relative changes at the different voltages are similar, and this implies that there are no MTS-induced changes of voltage-dependent gating, but rather the observed decrease of the current amplitude is caused by interaction of the reagents with the ion conduction pathway. For P192C, MTSES and MTSET have opposite effects on the channel function. MTSES causes a decrease of all measured current amplitudes, similarly to the results obtained with G190C and I191C. In contrast, after application of MTSET the instantaneous current amplitude at +75 mV increased, without comparable changes of the late current amplitude at the same potential. Whereas the instantaneous amplitude at -105 mV remained almost unchanged, a change of the deactivation time course was observed at this potential (Fig. 6A). These changes indicate a shift of the activation curve of P192C to more negative potentials after channel modification by MTSET. For mutant S189C, we also observed time-dependent shifts of the voltage dependence of activation that cause an increase of the current amplitude at certain potentials. For E193C, there was a time-dependent decrease of the late current amplitude at +75 mV and the current amplitudes at -105 mV (Fig. 6C), but the instantaneous current amplitude at +75 mV was unchanged. These observations again imply that voltage-dependent gating steps are modified by the reaction with MTS reagents.

In all cases, the effects of MTSES or MTSET were not reversed after moving the pipette in a solution without MTS reagents but only after addition of the reducing agent dithiothreitol. This demonstrates that the substituted thiol side chains react covalently with the hydrophilic MTS reagents and shows that these residues are in contact with the cytoplasmic aqueous medium. G188C did not express with sufficient current density to allow macroscopic recordings from excised patches. Moreover, in experiments with whole-cell recordings without modifying agents, we observed in all cells after the initial establishment of the whole-cell configuration a slow increase of the current amplitude (i.e. a run-up phenomenon). This feature prevents the accurate interpretation of experiments performed with MTS reagents in the pipette solution. We were therefore unable to determine the accessibility of Cys-188.

The reaction of an MTS reagent with a thiol side chain of a channel protein occurs in two consecutive steps. The MTS reagent first has to diffuse from the aqueous solution to the side chain and afterward react with it in a second step. The rates with which these two reactions occur cannot be determined independently, but the experimentally determined reaction rates often give information about the rate-limiting step in the cascade. For four substituted cysteines (G190C to E193C), we obtained second-order rate constants for modification with MTSES and MTSET (Fig. 3B). Rate constants for all reactions are well below the values observed for the modification of thiols in aqueous solution (21), and this observation suggests that reagent access from the aqueous solution is the rate-limiting step. The apparent reaction rates can thus be used to judge whether the reagent diffuses through an anion-selective or unselective entry pathway. Because MTSES (anionic) and MTSET (cationic) have similar molecular diameters, differences in reaction rates of a given cysteine mutant with these two reagents are most likely caused by an electrostatic interaction, with regions of the channel protein determining the selectivity of the pore entrance as well as with the negatively charged thiolate form of the substituted cysteine with which the MTS compound reacts (21). To obtain the anion to cation selectivity of the access pathway, one has to correct for the latter component. For this reason, the measured rate constant ratio (kMTSES/kMTSET) is normalized to the relative reactivity of the two reagents in aqueous solution (21), and this calculation yields the relative anion to cation selectivity of the access pathway. For the tested substituted thiols within P3, we obtain values between 9.4 and 120 (Fig. 3C). These results demonstrate that parts of P3 are in contact with the aqueous phase and that the access pathway to thiol side chains within this region is anion-selective.

To test whether P3 contributes to the formation of an anion-binding site, we performed chemical modification experiments in the absence and presence of thiocyanate ions (SCN-). If accessible side chains within P3 are in contact with permeating anions, one would expect that the reaction of MTS reagents with substituted cysteines will be impaired under experimental conditions that favor occupation of the particular binding site within the pore by anions. Several anions bind more tightly than chloride to sites within the ClC-1 ionic pore (8, 10) and effectively block chloride currents. We studied the effect of partial substitution of Cl- with SCN- on the reaction of substituted cysteines within P3 using the positively charged MTSET. If SCN- binds close to the substituted cysteine, MTSET might be unable to react if the thiol side chain is shielded by bound SCN- nearby. A decrease of either the degree of current reduction or the second-order reaction rate constants would indicate that P3 contributes to an anion-binding site. If MTSET reacts with a residue located elsewhere within the pore, electrostatic interactions of its positive charge with the bound anion are expected to boost the access of MTS reagents and will produce opposite results.

For these experiments, we studied Cys-190 and Cys-193. Fig. 4 shows results for these two P3 cysteines as well as Cys-231 in P1. Several lines of evidence indicate that Lys-231 in P1 makes direct contact with permeating anions (18), and Cys-231 was therefore used as a control. Partial substitution of chloride by SCN- completely abolishes the effects of Cys-231 modification suggesting that SCN- protects this thiol group. For the thiol side chains substituted within P3, the effect of SCN- was clearly distinct. Cys-190 as well as Cys-193 were modified in the presence of SCN-. For Cys-190, the extent of current reduction and the reaction rate during MTS treatment was significantly (p < 0.01) decreased. In contrast, for E193C, neither the reaction rates nor the degree of current reduction was altered in the presence of SCN.



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Fig. 4.   Effect of partial intra- or extracellular chloride substitution with thiocyanate. A, time course of modification of K231C hClC-1 channels by 50 µM MTSET as determined by whole-cell recordings with standard intracellular solution. The time dependence of the maximum current amplitude is shown for two different cells, one in standard external solution () and the other in a solution containing (in mM) 50 NaSCN, 90 NaCl, 4 KCl,2 CaCl2, 1 MgCl2, 5 HEPES, pH 7.4 (open circle ). Current maxima are normalized to control values obtained before MTSET application. B, relative current change for substituted cysteine G190C, E193C, and K231C by MTSET in standard solutions (hatched bars) and in solutions in which 50 mM NaCl were substituted with 50 mM NaSCN. The data were obtained with whole-cell recordings (K231C) or excised inside-out recordings (G190C and E193C). C, reaction rates for modification of these cysteines under the conditions in B.

SCN- as a weak nucleophile could react with MTS reagents, reduce their concentration, and thus cause a decreased apparent reaction rate. Although we cannot exclude that any of the applied MTS reagents reacted with SCN-, the marked difference of the SCN- effect on the MTS reaction with different substituted cysteines demonstrates that this is not the major action of this anion. SCN- completely abolishes the reaction of MTS with K231C; it reduces the reaction with G190C and leaves the reaction with E193C unchanged. We conclude that Lys-231 directly contributes to the formation of an anion-binding site and that Gly-190 is located near an anion-binding site, but obviously anions do not bind as so close to this side chain that the MTSET compounds cannot reach the thiol group. Our results do not support the notion that Glu-193 plays a role in anion binding within the ClC pore.

Functional Interaction of P3 Regions-- By using chemical modification of homo- and heterodimeric cysteine-substituted channels, we have recently provided evidence that accessible side chains within P1 of both subunits of a single channel interact with each other in a way that would be expected if they jointly form a single vestibule (24). To test whether such an interaction also takes place between the two P3 regions, we employed a similar experimental strategy.

We engineered tandem constructs (19) to express a homogenous population of heterodimeric single cysteine-substituted channels. Fig. 5, A---C, illustrates representative current recordings from heterodimeric WT-G190C channels under standard conditions (Fig. 5A), during modification by MTSES (Fig. 5B) and afterward (Fig. 5C). After reaching steady-state conditions following MTSES modification, a substantial current component carried by WT-G190C remains (Fig. 5C). By contrast, modification of the double cysteine-substituted channel causes an almost complete disappearance of the typical hClC-1 gating phenotype (Fig. 5D). This outcome is different from that of experiments with cysteine-substituted channels within the P1 region (24) where chemical modification of homo- and heterodimeric channel causes identical functional changes. At first glance, these results appear to support the idea that each P3 region of a functional hClC-1 dimeric channel forms an independent ion conduction pathway. However, two lines of evidence demonstrate that this is not the case. A comparison of the time course of modification (Fig. 5E) demonstrates that the reaction is significantly slower in the heterodimeric channel than in the homodimeric double cysteine-substituted channel. This result is in clear contrast to the predictions of a double-barreled channel for which the rate constants of modification of a certain cysteine should be unaffected by substitutions in the other protochannel. Whereas for MTSES modification there is a significant component of unmodified current, the unblocked current levels after MTSET modification are indistinguishable for homo- and heterodimeric channel (Fig. 5F). Fig. 5, F and G, summarizes the results obtained from several different cells tested separately with MTSES and MTSET. Second order rate constants are significantly reduced in channels with only one substituted cysteine (Fig. 5G). Similar results were obtained for I191C homo- and WT-I191C heterodimeric channels (data not shown).



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Fig. 5.   MTS modification of homo- and heterodimeric cysteine-substituted hClC-1 channels. A, excised inside-out patch clamp recordings from a cell expressing WT-G190C hClC-1 channels before modification. Voltage steps between -165 and +75 mV in 60-mV steps were applied from a holding potential of 0 mV. Each test pulse is followed by a fixed -105-mV pulse. B, current recordings during modification of the same patch as in A with 2 mM MTSES. The pulse protocol consists of consecutive voltage steps to +75 mV followed by a -105-mV test potential during the modification. C, current recordings from the same patch after modification. Voltage steps are as described in A. D, current recordings during modification of patch from a cell expression G190C homodimeric channels with 2 mM MTSES. Same pulse protocol was used as in B. E, time dependence of the normalized maximum current at -105 mV, obtained from the recordings shown in B (open symbol) and in D (filled symbol). For this graph, the instantaneous current amplitude at -105 mV was taken from each record and plotted versus the time since the beginning of the MTS application. F, second order reaction rates; and G, relative current change for modification of homo- and heterodimeric channels with MTSET and MTSES.

Fig. 6 illustrates the modification of P192C and E193C heterodimeric and homodimeric channels by MTS reagents. In all cases there are different effects on macroscopic currents through heterodimeric versus homodimeric channels. MTS modification of heterodimeric channels is not a simple superposition of the modification of cysteine-tagged pores with a current component by WT pores that are not modified. Similar to the other tested cysteines in the P1 and P3 regions, cysteine modification in one subunit does not cause functional effects that are independent from the other subunit.



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Fig. 6.   Distinct MTS modification of homo- and heterodimeric channels. A, P192C; B, WT-P192C; C, E193C; and D, WT-E193C. Inside-out patch clamp recordings and patches were held at 0 mV and stimulated every 5 s to voltage steps to +75 mV followed by -105 mV. Current responses for different times after MTS applications are superimposed. For A and B, 2 mM MTSET were applied, and for C and D, 50 µM MTSES.

The results obtained for single and double cysteine modification in P3 support the idea that this region in both subunits somehow interacts with the contralateral corresponding region, similar to that observed for the P1 region. Nevertheless, the functional effects of Cys-190 modification with MTSES in a heterodimeric channel are remarkably different from similar results obtained within the P1 region. A possible interpretation of these differences would be that the portion of the conduction pathway formed by P3 is wide enough to accommodate a covalently linked MTSES molecule and still permit ion flux. We tested this possibility by using different cysteine-specific reagents with larger substituents.

Dimensions of the hClC-1 Pore-- Fig. 7 shows the results of chemical modification of four cysteine side chains protruding into the pore of ClC channels by the cysteine-specific reagents, qBBr and MTS-PTrEA. MTS-PTrEA is a cubic molecule with a length of 8 Å, and qBBr exhibits a dimension of more than 6 × 10 × 12Å (25). Two cysteines are accessible to both reagents (K231C, G190C), E193C is only accessible to MTS-PTrEA, and H237C cannot be reached by either compound. As all these side chains are accessible to smaller cysteine-reactive reagents, the most likely possibility is that these large agents cannot bind because of steric hindrances. The dimensions of these agents therefore provide estimates for the proportions of the ionic pore of hClC-1.



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Fig. 7.   Modification of cysteine-substituted hClC-1 channels with MTS-PTrEA and qBBr. A, relative current reduction; and B, second order rate constants.



    DISCUSSION
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

P3 Is a Pore-lining Segment-- By using a combination of site-directed mutagenesis, heterologous expression, and chemical modification, we have demonstrated the following: 1) mutations within the highly conserved P3 region between transmembrane domains D2 and D3 affect anion selectivity of hClC-1; 2) cysteine substitution experiments indicate that this segment is accessible to internally applied hydrophilic MTS reagents; 3) the internal access pathway of MTS reagents to P3 is anion-selective; and 4) SCN- impairs MTS modification of a P3 thiol side chain (Cys-190). These results are all consistent with the idea that P3 forms part of the ion conduction pathway of the hClC-1 pore.

There are qualitative differences of the results obtained with P3 residues and those with P1 or P2 residues (18). For substituted cysteines within P1, the modification of a single cysteine decreases the current amplitude to zero levels, whereas in WT-G190C heterodimeric channels, modified by MTSES, a substantial amount of residual current could be observed. Moreover, whereas occupation of anionic binding sites prevents chemical modification of thiol side chains within P1, for residues belonging to the P3 region either no effect (E193C) or a less pronounced effect (G190C) could be observed. These results suggest that P3 may not contribute to the formation of the narrow part of the hClC-1 pore and most probably is not part of an anionic binding site. A likely explanation for these results may be that P3 forms part of a wide internal vestibule.

Estimating the Dimensions of the ClC Pore-- Studying interactions with high affinity pore blockers has provided many insights into the structure of the ion conduction pathway of many ion channels, most notably for organic compounds (26-28) or peptide blockers (29-31) with voltage-gated potassium channels. There are currently no specific blockers for ClC channels precluding employment of this approach. The use of cysteine-specific reagents has provided an alternative strategy for gaining insights into the dimensions of the ion conduction pathway of ClC channels.

Our earlier experiments with internal and external MTSES and MTSET demonstrated that there is a major constriction between Lys-231 and His-237, most probably the most narrow part of the ClC channel pore, and that this constriction is less than 6 Å (18). In agreement with these findings, experiments with various permeant anions provided evidence that this narrowing has a diameter between 4 and 6 Å (8, 10). The use of MTS-PTrEA and qBBr now reveals that the pore diameter is wider than 10 Å at the level of Lys-231 and G190C and that Glu-193 and His-237 are located in pore regions that are more restricted. From our data, it would appear that ClC channels exhibit the same hourglass pore architecture as other classes of ion channels with a constriction displaying the major selectivity neighbored on both sides with wide vestibules. This architecture effectively reduces the passage of the ion through a low dielectric constant medium and thus significantly diminishes the resistance of the ion conduction pathway (32).

The result with Cys-231 is surprising given that two Cys-231 residues in a homodimeric ClC channel are close enough to form disulfide bridges (24). To account for these disparate observations, we suggest that the pore wall of ClC channels around position 231 is very flexible. Flexibility of ionic pores has been proposed to account for a stepwise dehydration of ions while entering the narrow part of an ion channel or carrier (33, 34), and experiments with oxidizing agents have recently directly demonstrated such an elasticity for the outer mouth of sodium channels (35).

For hClC-1, this interpretation gives a structural basis for two other previous experimental results. An investigation of the blocking action of iodide suggested that there are conformational changes of the ionic pore of hClC-1 (8). A flexible pore region around Lys-231 could account for this finding because of the great functional importance of this residue (18). Moreover, SCN- exerts a puzzling effect on ion conduction through hClC-1. External SCN- blocks chloride currents in the negative and low positive voltage range, but at very positive potentials there is an outwardly rectifying current carried by SCN ions (10). Such a behavior (usually denoted as "punch through" effect) can be explained with a flexible pore (36, 37).

Pore Stoichiometry of ClC Channels-- In 1982, Miller (38) suggested a novel and unique pore architecture for the ClC-0 chloride channel. Based on single channel recordings, he proposed that these channels exhibit two identical and functionally independent protopores ("double-barreled shotgun" model). In the following years, Miller and colleagues provided several lines of evidence supporting this concept (39, 40). Later experiments with heterodimeric ClC-0 channels in which the primary sequence of one subunit was mutated at two specific residues (16, 41) demonstrated that the the unitary conductance as well as the ion selectivity of each subconductance state is determined by only one subunit supporting Miller's original proposal. The results of the work contained in the present paper and those of an earlier study (24) now reveal that two regions that are critical for the ion conduction in hClC-1 exhibit a behavior that reveals a functional interaction between the two subunits. These experiments are inconsistent with the proposed functional independence of the two protopores and appeared to be more consistent with a single conduction pathway than with the original double-barreled shotgun hypothesis. The different outcome of experiments performed with ClC-0 and hClC-1 cannot be explained by isoform-specific differences in pore stoichiometry. As ClC-0 and hClC-1 share high sequence identity, corresponding mutations in both isoforms cause similar functional alterations, and both isoforms display equally spaced subconductance states (38, 42); there is little doubt that ClC-0 and ClC-1 exhibit an identical quaternary structure of the pore.

These two experimental results represent a novel and interesting feature of ClC-type chloride channels. They either exhibit a single pore in which subconductance states occur that are completely independent, and we have at present only suggestions how this can happen (9), or they exhibit two ion conduction pathways that are independent in certain aspects but clearly interact in others. Another possibility is a combination of both, the existence of one or two common vestibules connected by two distinct conduction pathways. A definitive answer to this open question will provide important insights into the function of ClC-type chloride channels.

Conclusion-- We have identified a segment (P3) that contributes to the formation of a wide internal vestibule of ClC channels. Experiments with cysteine-specific reagents of different size revealed that ClC channels exhibit a pore architecture quite similar to cation channels, with a narrow region that is important for anion-cation selectivity in the center and wide vestibules on both sides. These experiments provide novel insights into the architecture and the function of the pore of ClC-type chloride channels.


    ACKNOWLEDGEMENTS

We are grateful to Craig Short for help with DNA sequencing. We thank Dr. Myles Akabas for very helpful information about the possible effects of SCN- on MTS reagents.


    FOOTNOTES

* This work was supported in part by grants from the Muscular Dystrophy Association of the United States (to Ch. F. and A. L. G.), German Research Foundation Grants Fa301/3-1 and Fa301/4-1 (to C. F.), a Beginning Grant-in-aid from the American Heart Association, Southeast Affiliate (to Ch. F), and National Institutes of Health Grant AR44506.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

|| Recipient of a Heisenberg-Stipendium from the German Research Foundation (Grant Fa 301/3-1) for part of this work. To whom correspondence should be addressed: Institut fur Physiologie, RWTH Aachen, Pauwelsstrasse 30, D-52074 Aachen, Germany. Tel.: 49 241 80 888 10; Fax: 49 241 8888 434; E-mail: chfahlke@physiology.rwth-aachen.de.

Published, JBC Papers in Press, October 16, 2000, DOI 10.1074/jbc.M007649200


    ABBREVIATIONS

The abbreviations used are: hClC-1, human ClC-1; MTS, methanethiosulfonate; MTSET, methylethiosulfonate ethyltrimethylammonium; MTSES, methylethiosulfonate ethylsulfonate; WT, wild type.


    REFERENCES
TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES


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