Permeation and Block of the Skeletal Muscle Chloride Channel,ClC-1, by Foreign Anions

A distinctive feature of the voltage-dependent chloride channels ClC-0 (the Torpedo electroplaque chloride channel) and ClC-1 (the major skeletal muscle chloride channel) is that chloride acts as a ligand to its own channel, regulating channel opening and so controlling the permeation of its own species. We have now studied the permeation of a number of foreign anions through ClC-1 using voltage-clamp techniques on Xenopus oocytes and Sf9 cells expressing human (hClC-1) or rat (rClC-1) isoforms, respectively. From their effect on channel gating, the anions presented in this paper can be divided into three groups: impermeant or poorly permeant anions that can not replace Cl⁻ as a channel opener and do not block the channel appreciably (glutamate, gluconate, HCO₃ ⁻, BrO₃ ⁻); impermeant anions that can open the channel and show significant block (methanesulfonate, cyclamate); and permeant anions that replace Cl⁻ at the regulatory binding site but impair Cl⁻ passage through the channel pore (Br⁻, NO₃ ⁻, ClO₃ ⁻, I⁻, ClO₄ ⁻, SCN⁻). The permeability sequence for rClC-1, SCN⁻ ∼ ClO₄ ⁻ > Cl⁻ > Br⁻ > NO₃ ⁻ ∼ ClO₃ ⁻ > I⁻ >> BrO₃ ⁻ > HCO₃ ⁻ >> methanesulfonate ∼ cyclamate ∼ glutamate, was different from the sequence determined for blocking potency and ability to shift the P _open curve, SCN⁻ ∼ ClO₄ ⁻ > I⁻ > NO₃ ⁻ ∼ ClO₃ ⁻ ∼ methanesulfonate > Br⁻ > cyclamate > BrO₃ ⁻ > HCO₃ ⁻ > glutamate, implying that the regulatory binding site that opens the channel is different from the selectivity center and situated closer to the external side. Channel block by foreign anions is voltage dependent and can be entirely accounted for by reduction in single channel conductance. Minimum pore diameter was estimated to be ∼4.5 Å. Anomalous mole-fraction effects found for permeability ratios and conductance in mixtures of Cl⁻ and SCN⁻ or ClO₄ ⁻ suggest a multi-ion pore. Hydrophobic interactions with the wall of the channel pore may explain discrepancies between the measured permeabilities of some anions and their size.     

Permeability of Wild-Type and Mutant Cystic Fibrosis Transmembrane Conductance Regulator Chloride Channels to Polyatomic Anions

Permeability of the cystic fibrosis transmembrane conductance regulator (CFTR) chloride channel to polyatomic anions of known dimensions was studied in stably transfected Chinese hamster ovary cells by using the patch clamp technique. Biionic reversal potentials measured with external polyatomic anions gave the permeability ratio (P_X/P_Cl) sequence NO₃ ⁻ > Cl⁻ > HCO₃ ⁻ > formate > acetate. The same selectivity sequence but somewhat higher permeability ratios were obtained when anions were tested from the cytoplasmic side. Pyruvate, propanoate, methane sulfonate, ethane sulfonate, and gluconate were not measurably permeant (P_X/P_Cl < 0.06) from either side of the membrane. The relationship between permeability ratios from the outside and ionic diameters suggests a minimum functional pore diameter of ∼5.3 Å. Permeability ratios also followed a lyotropic sequence, suggesting that permeability is dependent on ionic hydration energies. Site-directed mutagenesis of two adjacent threonines in TM6 to smaller, less polar alanines led to a significant (24%) increase in single channel conductance and elevated permeability to several large anions, suggesting that these residues do not strongly bind permeating anions, but may contribute to the narrowest part of the pore.     

Gating competence of constitutively open CLC-0 mutants revealed by the interaction with a small organic Inhibitor

Opening of CLC chloride channels is coupled to the translocation of the permeant anion. From the recent structure determination of bacterial CLC proteins in the closed and open configuration, a glutamate residue was hypothesized to form part of the Cl--sensitive gate. The negatively charged side-chain of the glutamate was suggested to occlude the permeation pathway in the closed state, while opening of a single protopore of the double-pore channel would reflect mainly a movement of this side-chain toward the extracellular pore vestibule, with little rearrangement of the rest of the channel. Here we show that mutating this critical residue (Glu166) in the prototype Torpedo CLC-0 to alanine, serine, or lysine leads to constitutively open channels, whereas a mutation to aspartate strongly slowed down opening. Furthermore, we investigated the interaction of the small organic channel blocker p-chlorophenoxy-acetic acid (CPA) with the mutants E166A and E166S. Both mutants were strongly inhibited by CPA at negative voltages with a >200-fold larger affinity than for wild-type CLC-0 (apparent KD at -140 mV approximately 4 micro M). A three-state linear model with an open state, a low-affinity and a high-affinity CPA-bound state can quantitatively describe steady-state and kinetic properties of the CPA block. The parameters of the model and additional mutagenesis suggest that the high-affinity CPA-bound state is similar to the closed configuration of the protopore gate of wild-type CLC-0. In the E166A mutant the glutamate side chain that occludes the permeation pathway is absent. Thus, if gating consists only in movement of this side-chain the mutant E166A should not be able to assume a closed conformation. It may thus be that fast gating in CLC-0 is more complex than anticipated from the bacterial structures.     

Permeant Anions Control Gating of Calcium-dependent Chloride Channels

The effects of external anions (SCN⁻, NO₃⁻, I⁻, Br⁻, F⁻, glutamate, and aspartate) on gating of Ca²⁺-dependent Cl⁻ channels from rat parotid acinar cells were studied using the whole-cell configuration of the patch-clamp technique. Shifts in the reversal potential of the current induced by replacement of external Cl⁻ with foreign anions, gave the following selectivity sequence based on permeability ratios (P_x/P_Cl): SCN⁻>I⁻>NO₃⁻>Br⁻>Cl⁻>F⁻>aspartate>glutamate. Using a continuum electrostatic model we calculated that this lyotropic sequence resulted from the interaction between anions and a polarizable tunnel with an effective dielectric constant of ∼23. Our data revealed that anions with P_x/P_Cl > 1 accelerated activation kinetics in a voltage-independent manner and slowed deactivation kinetics. Moreover, permeant anions enhanced whole-cell conductance (g, an index of the apparent open probability) in a voltage-dependent manner, and shifted leftward the membrane potential-g curves. All of these effects were produced by the anions with an effectiveness that followed the selectivity sequence. To explain the effects of permeant anions on activation kinetics and g_Cl we propose that there are 2 different anion-binding sites in the channel. One site is located outside the electrical field and controls channel activation kinetics, while a second site is located within the pore and controls whole-cell conductance. Thus, interactions of permeant anions with these two sites hinder the closing mechanism and stabilize the channel in the open state.This revised version was published online in August 2005 with a corrected cover date.     

Amphiphilic Blockers Punch through a Mutant CLC-0 Pore

Intracellularly applied amphiphilic molecules, such as p-chlorophenoxy acetate (CPA) and octanoate, block various pore-open mutants of CLC-0. The voltage-dependent block of a particular pore-open mutant, E166G, was found to be multiphasic. In symmetrical 140 mM Cl⁻, the apparent affinity of the blocker in this mutant increased with a negative membrane potential but, paradoxically, decreased when the negative membrane potential was greater than −80 mV, a phenomenon similar to the blocker “punch-through” shown in many blocker studies of cation channels. To provide further evidence of the punch-through of CPA and octanoate, we studied the dissociation rate of the blocker from the pore by measuring the time constant of relief from the block under various voltage and ionic conditions. Consistent with the voltage dependence of the effect on the steady-state current, the rate of CPA dissociation from the E166G pore reached a minimum at −80 mV in symmetrical 140 mM Cl⁻, and the direction of current recovery suggested that the bound CPA in the pore can dissociate into both intracellular and extracellular solutions. Moreover, the CPA dissociation depends upon the Cl⁻ reversal potential with a minimal dissociation rate at a voltage 80 mV more negative than the Cl⁻ reversal potential. That the shift of the CPA-dissociation rate follows the Cl⁻ gradient across the membrane argues that these blockers can indeed punch through the channel pore. Furthermore, a minimal CPA-dissociation rate at a voltage 80 mV more negative than the Cl⁻ reversal potential suggests that the outward blocker movement through the CLC-0 pore is more difficult than the inward movement.     

Mechanism of Ion Permeation in Skeletal Muscle Chloride Channels

Voltage-gated Cl⁻ channels belonging to the ClC family exhibit unique properties of ion permeation and gating. We functionally probed the conduction pathway of a recombinant human skeletal muscle Cl⁻ channel (hClC-1) expressed both in Xenopus oocytes and in a mammalian cell line by investigating block by extracellular or intracellular I⁻ and related anions. Extracellular and intracellular I⁻ exert blocking actions on hClC-1 currents that are both concentration and voltage dependent. Similar actions were observed for a variety of other halide (Br⁻) and polyatomic (SCN⁻, NO₃ ⁻, CH₃SO₃ ⁻) anions. In addition, I⁻ block is accompanied by gating alterations that differ depending on which side of the membrane the blocker is applied. External I⁻ causes a shift in the voltage-dependent probability that channels exist in three definable kinetic states (fast deactivating, slow deactivating, nondeactivating), while internal I⁻ slows deactivation. These different effects on gating properties can be used to distinguish two functional ion binding sites within the hClC-1 pore. We determined K _D values for I⁻ block in three distinct kinetic states and found that binding of I⁻ to hClC-1 is modulated by the gating state of the channel. Furthermore, estimates of electrical distance for I⁻ binding suggest that conformational changes affecting the two ion binding sites occur during gating transitions. These results have implications for understanding mechanisms of ion selectivity in hClC-1, and for defining the intimate relationship between gating and permeation in ClC channels.     

Functionally additive fixed positive and negative charges in the CFTR channel pore control anion binding and conductance

Ion channels use charged amino-acid residues to attract oppositely charged permeant ions into the channel pore. In the cystic fibrosis transmembrane conductance regulator (CFTR) Cl⁻ channel, a number of arginine and lysine residues have been shown to be important for Cl⁻ permeation. Among these, two in close proximity in the pore—Lys⁹⁵ and Arg¹³⁴—are indispensable for anion binding and high Cl⁻ conductance, suggesting that high positive charge density is required for pore function. Here we used mutagenesis and functional characterization to show that a nearby pore-lining negatively charged residue (Glu⁹²) plays a functionally additive role with these two positive charges. While neutralization of this negative charge had little effect on anion binding or Cl⁻ conductance, such neutralization was able to reverse the detrimental effects of removing the positive charge at either Lys⁹⁵ or Arg¹³⁴, as well as the similar effects of introducing a negative charge at a neighboring residue (Ser¹¹⁴¹). Furthermore, neutralization of Glu⁹² greatly increased the susceptibility of the channel to blockage by divalent S₂O₃²⁻ anions, mimicking the effect of introducing additional positive charge in this region; this effect was reversed by concurrent neutralization of either Lys⁹⁵ or Arg¹³⁴. Across a panel of mutant channels that introduced or removed fixed charges at these four positions, we found that many pore properties are dependent on the overall charge or charge density. We propose that the CFTR pore uses a combination of positively and negatively charged residues to optimize the anion binding and Cl⁻ conductance properties of the channel.     

Oxidative Damage in Pea Plants Exposed to Water Deficit or Paraquat

Enhanced Cl⁻ efflux during acidosis in plants is thought to play a role in cytosolic pH (pH_c) homeostasis by short-circuiting the current produced by the electrogenic H⁺ pump, thereby facilitating enhanced H⁺ efflux from the cytosol. Using an intracellular perfusion technique, which enables experimental control of medium composition at the cytosolic surface of the plasma membrane of charophyte algae (Chara corallina), we show that lowered pH_c activates Cl⁻ efflux via two mechanisms. The first is a direct effect of pH_c on Cl⁻ efflux; the second mechanism comprises a pH_c-induced increase in affinity for cytosolic free Ca²⁺ ([Ca²⁺]_c), which also activates Cl⁻ efflux. Cl⁻ efflux was controlled by phosphorylation/dephosphorylation events, which override the responses to both pH_c and [Ca²⁺]_c. Whereas phosphorylation (perfusion with the catalytic subunit of protein kinase A in the presence of ATP) resulted in a complete inhibition of Cl⁻ efflux, dephosphorylation (perfusion with alkaline phosphatase) arrested Cl⁻ efflux at 60% of the maximal level in a manner that was both pH_c and [Ca²⁺]_c independent. These findings imply that plasma membrane anion channels play a central role in pH_c regulation in plants, in addition to their established roles in turgor/volume regulation and signal transduction.     

Modulation of the slow/common gating of CLC channels by intracellular cadmium

Members of the CLC family of Cl⁻ channels and transporters are homodimeric integral membrane proteins. Two gating mechanisms control the opening and closing of Cl⁻ channels in this family: fast gating, which regulates opening and closing of the individual pores in each subunit, and slow (or common) gating, which simultaneously controls gating of both subunits. Here, we found that intracellularly applied Cd²⁺ reduces the current of CLC-0 because of its inhibition on the slow gating. We identified CLC-0 residues C229 and H231, located at the intracellular end of the transmembrane domain near the dimer interface, as the Cd²⁺-coordinating residues. The inhibition of the current of CLC-0 by Cd²⁺ was greatly enhanced by mutation of I225W and V490W at the dimer interface. Biochemical experiments revealed that formation of a disulfide bond within this Cd²⁺-binding site is also affected by mutation of I225W and V490W, indicating that these two mutations alter the structure of the Cd²⁺-binding site. Kinetic studies showed that Cd²⁺ inhibition appears to be state dependent, suggesting that structural rearrangements may occur in the CLC dimer interface during Cd²⁺ modulation. Mutations of I290 and I556 of CLC-1, which correspond to I225 and V490 of CLC-0, respectively, have been shown previously to cause malfunction of CLC-1 Cl⁻ channel by altering the common gating. Our experimental results suggest that mutations of the corresponding residues in CLC-0 change the subunit interaction and alter the slow gating of CLC-0. The effect of these mutations on modulations of slow gating of CLC channels by intracellular Cd²⁺ likely depends on their alteration of subunit interactions.     

Ion permeation and block of the gating pore in the voltage sensor of NaV1.4 channels with hypokalemic periodic paralysis mutations

Hypokalemic periodic paralysis and normokalemic periodic paralysis are caused by mutations of the gating charge–carrying arginine residues in skeletal muscle Na_V1.4 channels, which induce gating pore current through the mutant voltage sensor domains. Inward sodium currents through the gating pore of mutant R666G are only ∼1% of central pore current, but substitution of guanidine for sodium in the extracellular solution increases their size by 13- ± 2-fold. Ethylguanidine is permeant through the R666G gating pore at physiological membrane potentials but blocks the gating pore at hyperpolarized potentials. Guanidine is also highly permeant through the proton-selective gating pore formed by the mutant R666H. Gating pore current conducted by the R666G mutant is blocked by divalent cations such as Ba²⁺ and Zn²⁺ in a voltage-dependent manner. The affinity for voltage-dependent block of gating pore current by Ba²⁺ and Zn²⁺ is increased at more negative holding potentials. The apparent dissociation constant (K_d) values for Zn²⁺ block for test pulses to −160 mV are 650 ± 150 µM, 360 ± 70 µM, and 95.6 ± 11 µM at holding potentials of 0 mV, −80 mV, and −120 mV, respectively. Gating pore current is blocked by trivalent cations, but in a nearly voltage-independent manner, with an apparent K_d for Gd³⁺ of 238 ± 14 µM at −80 mV. To test whether these periodic paralyses might be treated by blocking gating pore current, we screened several aromatic and aliphatic guanidine derivatives and found that 1-(2,4-xylyl)guanidinium can block gating pore current in the millimolar concentration range without affecting normal Na_V1.4 channel function. Together, our results demonstrate unique permeability of guanidine through Na_V1.4 gating pores, define voltage-dependent and voltage-independent block by divalent and trivalent cations, respectively, and provide initial support for the concept that guanidine-based gating pore blockers could be therapeutically useful.     

Intracellular pH Regulation in Cultured Astrocytes from Rat Hippocampus : I. Role of HCO3?

We studied the regulation of intracellular pH (pH_i) in single cultured astrocytes passaged once from the hippocampus of the rat, using the dye 2′,7′-biscarboxyethyl-5,6-carboxyfluorescein (BCECF) to monitor pH_i. Intrinsic buffering power (β_I) was 10.5 mM (pH unit)⁻¹ at pH_i 7.0, and decreased linearly with pH_i; the best-fit line to the data had a slope of −10.0 mM (pH unit)⁻². In the absence of HCO₃ ⁻, pH_i recovery from an acid load was mediated predominantly by a Na-H exchanger because the recovery was inhibited 88% by amiloride and 79% by ethylisopropylamiloride (EIPA) at pH_i 6.05. The ethylisopropylamiloride-sensitive component of acid extrusion fell linearly with pH_i. Acid extrusion was inhibited 68% (pH_i 6.23) by substituting Li⁺ for Na⁺ in the bath solution. Switching from a CO₂/HCO₃ ⁻-free to a CO₂/HCO₃ ⁻-containing bath solution caused mean steady state pH_i to increase from 6.82 to 6.90, due to a Na⁺-driven HCO₃ ⁻ transporter. The HCO₃ ⁻-induced pH_i increase was unaffected by amiloride, but was inhibited 75% (pH_i 6.85) by 400 μM 4,4′-diisothiocyanatostilbene-2,2′-disulfonic acid (DIDS), and 65% (pH_i 6.55–6.75) by pretreating astrocytes for up to ∼6.3 h with 400 μM 4-acetamide-4′-isothiocyanatostilbene-2,2′-disulfonic acid (SITS). The CO₂/HCO₃ ⁻-induced pH_i increase was blocked when external Na⁺ was replaced with N-methyl-d-glucammonium (NMDG⁺). In the presence of HCO₃ ⁻, the Na⁺-driven HCO₃ ⁻ transporter contributed to the pH_i recovery from an acid load. For example, HCO₃ ⁻ shifted the plot of acid-extrusion rate vs. pH_i by 0.15–0.3 pH units in the alkaline direction. Also, with Na-H exchange inhibited by amiloride, HCO₃ ⁻ increased acid extrusion 3.8-fold (pH_i 6.20). When astrocytes were acid loaded in amiloride, with Li⁺ as the major cation, HCO₃ ⁻ failed to elicit a substantial increase in pH_i. Thus, Li⁺ does not appear to substitute well for Na⁺ on the HCO₃ ⁻ transporter. We conclude that an amiloride-sensitive Na-H exchanger and a Na⁺-driven HCO₃ ⁻ transporter are the predominant acid extruders in astrocytes.     

Blocking Pore-open Mutants of CLC-0 by Amphiphilic Blockers

The blockade of CLC-0 chloride channels by p-chlorophenoxy acetate (CPA) has been thought to be state dependent; the conformational change of the channel pore during the “fast gating” alters the CPA binding affinity. Here, we examine the mechanism of CPA blocking in pore-open mutants of CLC-0 in which the residue E166 was replaced by various amino acids. We find that the CPA-blocking affinities depend upon the volume and the hydrophobicity of the side chain of the introduced residue; CPA affinity can vary by three orders of magnitude in these mutants. On the other hand, mutations at the intracellular pore entrance, although affecting the association and dissociation rates of the CPA block, generate only a modest effect on the steady-state blocking affinity. In addition, various amphiphilic compounds, including fatty acids and alkyl sulfonates, can also block the pore-open mutants of CLC-0 through a similar mechanism. The blocking affinity of fatty acids and alkyl sulfonates increases with the length of these amphiphilic blockers, a phenomenon similar to the block of the Shaker K⁺ channel by long-chain quaternary ammonium (QA) ions. These observations lead us to propose that the CPA block of the open pore of CLC-0 is similar to the blockade of voltage-gated K⁺ channels by long-chain QAs or by the inactivation ball peptide: the blocker first uses the hydrophilic end to “dock” at the pore entrance, and the hydrophobic part of the blocker then enters the pore to interact with a more hydrophobic region of the pore. This blocking mechanism appears to be very general because the block does not require a precise structural fit between the blocker and the pore, and the blocking mechanism applies to the cation and anion channels with unrelated pore architectures.     

Multi-Ion Mechanism for Ion Permeation and Block in the Cystic Fibrosis Transmembrane Conductance Regulator Chloride Channel

The mechanism of Cl⁻ ion permeation through single cystic fibrosis transmembrane conductance regulator (CFTR) channels was studied using the channel-blocking ion gluconate. High concentrations of intracellular gluconate ions cause a rapid, voltage-dependent block of CFTR Cl⁻ channels by binding to a site ∼40% of the way through the transmembrane electric field. The affinity of gluconate block was influenced by both intracellular and extracellular Cl⁻ concentration. Increasing extracellular Cl⁻ concentration reduced intracellular gluconate affinity, suggesting that a repulsive interaction occurs between Cl⁻ and gluconate ions within the channel pore, an effect that would require the pore to be capable of holding more than one ion simultaneously. This effect of extracellular Cl⁻ is not shared by extracellular gluconate ions, suggesting that gluconate is unable to enter the pore from the outside. Increasing the intracellular Cl⁻ concentration also reduced the affinity of intracellular gluconate block, consistent with competition between intracellular Cl⁻ and gluconate ions for a common binding site in the pore. Based on this evidence that CFTR is a multi-ion pore, we have analyzed Cl⁻ permeation and gluconate block using discrete-state models with multiple occupancy. Both two- and three-site models were able to reproduce all of the experimental data with similar accuracy, including the dependence of blocker affinity on external Cl⁻ (but not gluconate) ions and the dependence of channel conductance on Cl⁻ concentration. The three-site model was also able to predict block by internal and external thiocyanate (SCN⁻) ions and anomalous mole fraction behavior seen in Cl⁻/SCN⁻ mixtures.     

Monovalent Cation Permeation through the Connexin40 Gap Junction Channel : Cs,Rb, K,Na, Li,TEA, TMA,TBA, and Effects of Anions Br,Cl, F,Acetate, Aspartate,Glutamate, and NO3

The unitary conductances and permeability sequences of the rat connexin40 (rCx40) gap junction channels to seven monovalent cations and anions were studied in rCx40-transfected neuroblastoma 2A (N2A) cell pairs using the dual whole cell recording technique. Chloride salt cation substitutions (115 mM principal salt) resulted in the following junctional maximal single channel current-voltage relationship slope conductances (γ_j in pS): CsCl (153), RbCl (148), KCl (142), NaCl (115), LiCl (86), TMACl (71), TEACl (63). Reversible block of the rCx40 channel was observed with TBA. Potassium anion salt γ_j are: Kglutamate (160), Kacetate (160), Kaspartate (158), KNO₃ (157), KF (148), KCl (142), and KBr (132). Ion selectivity was verified by measuring reversal potentials for current in rCx40 gap junction channels with asymmetric salt solutions in the two electrodes and using the Goldman-Hodgkin-Katz equation to calculate relative permeabilities. The permeabilities relative to Li⁺ are: Cs⁺ (1.38), Rb⁺ (1.32), K⁺ (1.31), Na⁺ (1.16), TMA⁺ (0.53), TEA⁺ (0.45), TBA⁺ (0.03), Cl⁻ (0.19), glutamate⁻ (0.04), and NO₃− (0.14), assuming that the monovalent anions permeate the channel by forming ion pairs with permeant monovalent cations within the pore thereby causing proportionate decreases in the channel conductance. This hypothesis can account for why the predicted increasing conductances with increasing ion mobilities in an essentially aqueous channel were not observed for anions in the rCx40 channel. The rCx40 effective channel radius is estimated to be 6.6 Å from a theoretical fit of the relationship of relative permeability and cation radius.     

Interactions between permeation and gating in the TMEM16B/anoctamin2 calcium-activated chloride channel

At least two members of the TMEM16/anoctamin family, TMEM16A (also known as anoctamin1) and TMEM16B (also known as anoctamin2), encode Ca²⁺-activated Cl⁻ channels (CaCCs), which are found in various cell types and mediate numerous physiological functions. Here, we used whole-cell and excised inside-out patch-clamp to investigate the relationship between anion permeation and gating, two processes typically viewed as independent, in TMEM16B expressed in HEK 293T cells. The permeability ratio sequence determined by substituting Cl⁻ with other anions (P_X/P_Cl) was SCN⁻ > I⁻ > NO₃⁻ > Br⁻ > Cl⁻ > F⁻ > gluconate. When external Cl⁻ was substituted with other anions, TMEM16B activation and deactivation kinetics at 0.5 µM Ca²⁺ were modified according to the sequence of permeability ratios, with anions more permeant than Cl⁻ slowing both activation and deactivation and anions less permeant than Cl⁻ accelerating them. Moreover, replacement of external Cl⁻ with gluconate, or sucrose, shifted the voltage dependence of steady-state activation (G-V relation) to more positive potentials, whereas substitution of extracellular or intracellular Cl⁻ with SCN⁻ shifted G-V to more negative potentials. Dose–response relationships for Ca²⁺ in the presence of different extracellular anions indicated that the apparent affinity for Ca²⁺ at +100 mV increased with increasing permeability ratio. The apparent affinity for Ca²⁺ in the presence of intracellular SCN⁻ also increased compared with that in Cl⁻. Our results provide the first evidence that TMEM16B gating is modulated by permeant anions and provide the basis for future studies aimed at identifying the molecular determinants of TMEM16B ion selectivity and gating.     

Common Gating of Both CLC Transporter Subunits Underlies Voltage-dependent Activation of the 2Cl?/1H+ Exchanger ClC-7/Ostm1

CLC anion transporters form dimers that function either as Cl⁻ channels or as electrogenic Cl⁻/H⁺ exchangers. CLC channels display two different types of “gates,” “protopore” gates that open and close the two pores of a CLC dimer independently of each other and common gates that act on both pores simultaneously. ClC-7/Ostm1 is a lysosomal 2Cl⁻/1H⁺ exchanger that is slowly activated by depolarization. This gating process is drastically accelerated by many CLCN7 mutations underlying human osteopetrosis. Making use of some of these mutants, we now investigate whether slow voltage activation of plasma membrane-targeted ClC-7/Ostm1 involves protopore or common gates. Voltage activation of wild-type ClC-7 subunits was accelerated by co-expressing an excess of ClC-7 subunits carrying an accelerating mutation together with a point mutation rendering these subunits transport-deficient. Conversely, voltage activation of a fast ClC-7 mutant could be slowed by co-expressing an excess of a transport-deficient mutant. These effects did not depend on whether the accelerating mutation localized to the transmembrane part or to cytoplasmic cystathionine-β-synthase (CBS) domains of ClC-7. Combining accelerating mutations in the same subunit did not speed up gating further. No currents were observed when ClC-7 was truncated after the last intramembrane helix. Currents and slow gating were restored when the C terminus was co-expressed by itself or fused to the C terminus of the β-subunit Ostm1. We conclude that common gating underlies the slow voltage activation of ClC-7. It depends on the CBS domain-containing C terminus that does not require covalent binding to the membrane domain of ClC-7.     

The Late Endosomal ClC-6 Mediates Proton/Chloride Countertransport in Heterologous Plasma Membrane Expression

Members of the CLC protein family of Cl⁻ channels and transporters display the remarkable ability to function as either chloride channels or Cl⁻/H⁺ antiporters. Due to the intracellular localization of ClC-6 and ClC-7, it has not yet been possible to study the biophysical properties of these members of the late endosomal/lysosomal CLC branch in heterologous expression. Whereas recent data suggest that ClC-7 functions as an antiporter, transport characteristics of ClC-6 have remained entirely unknown. Here, we report that fusing the green fluorescent protein (GFP) to the N terminus of ClC-6 increased its cell surface expression, allowing us to functionally characterize ClC-6. Compatible with ClC-6 mediating Cl⁻/H⁺ exchange, Xenopus oocytes expressing GFP-tagged ClC-6 alkalinized upon depolarization. This alkalinization was dependent on the presence of extracellular anions and could occur against an electrochemical proton gradient. As observed in other CLC exchangers, ClC-6-mediated H⁺ transport was abolished by mutations in either the “gating” or “proton” glutamate. Overexpression of GFP-tagged ClC-6 in CHO cells elicited small, outwardly rectifying currents with a Cl⁻ > I⁻ conductance sequence. Mutating the gating glutamate of ClC-6 yielded an ohmic anion conductance that was increased by additionally mutating the “anion-coordinating” tyrosine. Additionally changing the chloride-coordinating serine 157 to proline increased the NO₃⁻ conductance of this mutant. Taken together, these data demonstrate for the first time that ClC-6 is a Cl⁻/H⁺ antiporter.     

Anion-Sensitive, H-Pumping ATPase of Oat Roots : Direct Effects of Cl, NO(3), and a Disulfonic Stilbene

To understand the mechanism and molecular properties of the tonoplast-type H⁺-translocating ATPase, we have studied the effect of Cl⁻, NO₃⁻, and 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (DIDS) on the activity of the electrogenic H⁺-ATPase associated with low-density microsomal vesicles from oat roots (Avena sativa cv Lang). The H⁺-pumping ATPase generates a membrane potential (Δψ) and a pH gradient (ΔpH) that make up two interconvertible components of the proton electrochemical gradient (μh⁺). A permeant anion (e.g. Cl⁻), unlike an impermeant anion (e.g. iminodiacetate), dissipated the membrane potential ([¹⁴C]thiocyanate distribution) and stimulated formation of a pH gradient ([¹⁴C]methylamine distribution). However, Cl⁻-stimulated ATPase activity was about 75% caused by a direct stimulation of the ATPase by Cl⁻ independent of the proton electrochemical gradient. Unlike the plasma membrane H⁺-ATPase, the Cl⁻-stimulated ATPase was inhibited by NO₃⁻ (a permeant anion) and by DIDS. In the absence of Cl⁻, NO₃⁻ decreased membrane potential formation and did not stimulate pH gradient formation. The inhibition by NO₃⁻ of Cl⁻-stimulated pH gradient formation and Cl⁻-stimulated ATPase activity was noncompetitive. In the absence of Cl⁻, DIDS inhibited the basal Mg,ATPase activity and membrane potential formation. DIDS also inhibited the Cl⁻-stimulated ATPase activity and pH gradient formation. Direct inhibition of the electrogenic H⁺-ATPase by NO₃⁻ or DIDS suggest that the vanadate-insensitive H⁺-pumping ATPase has anion-sensitive site(s) that regulate the catalytic and vectorial activity. Whether the anion-sensitive H⁺-ATPase has channels that conduct anions is yet to be established.     

Calcium-calmodulin does not alter the anion permeability of the mouse TMEM16A calcium-activated chloride channel

The transmembrane protein TMEM16A forms a Ca²⁺-activated Cl⁻ channel that is permeable to many anions, including SCN⁻, I⁻, Br⁻, Cl⁻, and HCO₃⁻, and has been implicated in various physiological functions. Indeed, controlling anion permeation through the TMEM16A channel pore may be critical in regulating the pH of exocrine fluids such as the pancreatic juice. The anion permeability of the TMEM16A channel pore has recently been reported to be modulated by Ca²⁺-calmodulin (CaCaM), such that the pore of the CaCaM-bound channel shows a reduced ability to discriminate between anions as measured by a shift of the reversal potential under bi-ionic conditions. Here, using a mouse TMEM16A clone that contains the two previously identified putative CaM-binding motifs, we were unable to demonstrate such CaCaM-dependent changes in the bi-ionic potential. We confirmed the activity of CaCaM used in our study by showing CaCaM modulation of the olfactory cyclic nucleotide–gated channel. We suspect that the different bi-ionic potentials that were obtained previously from whole-cell recordings in low and high intracellular [Ca²⁺] may result from different degrees of bi-ionic potential shift secondary to a series resistance problem, an ion accumulation effect, or both.     

Modulation of Voltage-dependent Properties of a Swelling-activated Cl? Current

We used the patch-clamp technique to study the voltage-dependent properties of the swelling-activated Cl⁻ current (I _Cl,swell) in BC₃H1 myoblasts. This Cl⁻ current is outwardly rectifying and exhibits time-dependent inactivation at positive potentials (potential for half-maximal inactivation of +75 mV). Single-channel Cl⁻ currents with similar voltage-dependent characteristics could be measured in outside-out patches pulled from swollen cells. The estimated single-channel slope conductance in the region between +60 and +140 mV was 47 pS. The time course of inactivation was well described by a double exponential function, with a voltage-independent fast time constant (∼60 ms) and a voltage-dependent slow time constant (>200 ms). Recovery from inactivation, which occurred over the physiological voltage range, was also well described by a double exponential function, with a voltage-dependent fast time constant (10–80 ms) and a voltage-dependent slow time constant (>100 ms). The inactivation process was significantly accelerated by reducing the pH, increasing the Mg²⁺ concentration or reducing the Cl⁻ concentration of the extracellular solution. Replacing extracellular Cl⁻ by other permeant anions shifted the inactivation curve in parallel with their relative permeabilities (SCN⁻ > I⁻ > NO₃ ⁻ > Cl⁻ >> gluconate). A leftward shift of the inactivation curve could also be induced by channel blockers. Additionally, the permeant anion and the channel blockers, but not external pH or Mg²⁺, modulated the recovery from inactivation. In conclusion, our results show that the voltage-dependent properties of I _Cl,swell are strongly influenced by external pH , external divalent cations, and by the nature of the permeant anion.