Study of permeation and blocker binding in TMEM16A calcium-activated chloride channels

We studied the effects of mutations of positively charged amino acid residues in the pore of X. tropicalis TMEM16A calcium-activated chloride channels: K613E, K628E, K630E; R646E and R761E. The activation and deactivation kinetics were not affected, and only K613E showed a lower current density. K628E and R761E affect anion selectivity without affecting Na⁺ permeation, whereas K613E, R646E and the double mutant K613E + R646E affect anion selectivity and permeability to Na⁺. Furthermore, altered blockade by the chloride channel blockers anthracene-9-carboxylic acid (A-9-C), 4, 4''-Diisothiocyano-2,2''-stilbenedisulfonic acid (DIDS) and T16inh-A01 was observed. These results suggest the existence of 2 binding sites for anions within the pore at electrical distances of 0.3 and 0.5. These sites are also relevant for anion permeation and blockade.     

The Interaction of Na+ and K+ in Voltage-gated Potassium Channels : Evidence for Cation Binding Sites of Different Affinity

Voltage-gated potassium (K⁺) channels are multi-ion pores. Recent studies suggest that, similar to calcium channels, competition between ionic species for intrapore binding sites may contribute to ionic selectivity in at least some K⁺ channels. Molecular studies suggest that a putative constricted region of the pore, which is presumably the site of selectivity, may be as short as one ionic diameter in length. Taken together, these results suggest that selectivity may occur at just a single binding site in the pore. We are studying a chimeric K⁺ channel that is highly selective for K⁺ over Na⁺ in physiological solutions, but conducts Na⁺ in the absence of K⁺. Na⁺ and K⁺ currents both display slow (C-type) inactivation, but had markedly different inactivation and deactivation kinetics; Na⁺ currents inactivated more rapidly and deactivated more slowly than K⁺ currents. Currents carried by 160 mM Na⁺ were inhibited by external K⁺ with an apparent IC₅₀ <30 μM. K⁺ also altered both inactivation and deactivation kinetics of Na⁺ currents at these low concentrations. In the complementary experiment, currents carried by 3 mM K⁺ were inhibited by external Na⁺, with an apparent IC₅₀ of ∼100 mM. In contrast to the effects of low [K⁺] on Na⁺ current kinetics, Na⁺ did not affect K⁺ current kinetics, even at concentrations that inhibited K⁺ currents by 40–50%. These data suggest that Na⁺ block of K⁺ currents did not involve displacement of K⁺ from the high affinity site involved in gating kinetics. We present a model that describes the permeation pathway as a single high affinity, cation-selective binding site, flanked by low affinity, nonselective sites. This model quantitatively predicts the anomalous mole fraction behavior observed in two different K⁺ channels, differential K⁺ and Na⁺ conductance, and the concentration dependence of K⁺ block of Na⁺ currents and Na⁺ block of K⁺ currents. Based on our results, we hypothesize that the permeation pathway contains a single high affinity binding site, where selectivity and ionic modulation of gating occur.     

Sodium permeability and sensitivity induced by mutations in the selectivity filter of the KcsA channel towards Kir channels

The bacterial potassium (K⁺) channel KcsA provides an attractive model system to study ion permeation behavior in a selective K⁺-channel. We changed residue at the N-terminal end of the selectivity filter of KcsA (T74V) to its counterpart in inwardly rectifying K⁺-channels (Kir). The tetramer was found to be stable as unmodified KcsA. Under symmetrical and asymmetrical conditions, Na⁺ increased the inward current in the virtual absence of K⁺ however outward currents were nearly abolished which could be recovered upon internal K⁺ addition. Na⁺ also drastically increased the channel open time either in the presence or virtual absence of K⁺. Furthermore, the T74V mutation decreased the internal Ba²⁺ affinity of the channel possibly by binding to a K⁺ site in the pore. In additional experiments, another point mutation V76I in T74V mutant was carried out thus the selectivity filter resembled more the selectivity filter of Kir channels. The mutant tetramer was converted into monomers as determined by conventional gel electrophoresis. However, native like gel electrophoresis, Trp fluorescence and acrylamide quenching experiments indicated that this mutant still formed a tetramer and apparently adopted similar folding properties as unmodified KcsA. Single-channel experiments further demonstrated that the channel was selective for K⁺ over Na⁺ as Na⁺ blocked channel currents. These data suggest that single point mutation T74V alters the selectivity filter and allows simultaneous occupancy and conduction of K⁺ and Na⁺ probably via ion–ion interaction in the pore. In contrast, both mutations (T74V and V76I) in the same molecule seem to reorganize the pore conformation which controls the overall stability of a selective K⁺-channel.     

The external pore loop interacts with S6 and S3-S4 linker in domain 4 to assume an essential role in gating control and anticonvulsant action in the Na+ channel

Carbamazepine, phenytoin, and lamotrigine are widely prescribed anticonvulsants in neurological clinics. These drugs bind to the same receptor site, probably with the diphenyl motif in their structure, to inhibit the Na⁺ channel. However, the location of the drug receptor remains controversial. In this study, we demonstrate close proximity and potential interaction between an external aromatic residue (W1716 in the external pore loop) and an internal aromatic residue (F1764 in the pore-lining part of the sixth transmembrane segment, S6) of domain 4 (D4), both being closely related to anticonvulsant and/or local anesthetic binding to the Na⁺ channel. Double-mutant cycle analysis reveals significant cooperativity between the two phenyl residues for anticonvulsant binding. Concomitant F1764C mutation evidently decreases the susceptibility of W1716C to external Cd²⁺ and membrane-impermeable methanethiosulfonate reagents. Also, the W1716E/F1764R and G1715E/F1764R double mutations significantly alter the selectivity for Na⁺ over K⁺ and markedly shift the activation curve, respectively. W1716 and F1764 therefore very likely form a link connecting the outer and inner compartments of the Na⁺ channel pore (in addition to the selectivity filter). Anticonvulsants and local anesthetics may well traverse this “S6 recess” without trespassing on the selectivity filter. Furthermore, we found that Y1618K, a point mutation in the S3-4 linker (the extracellular extension of D4S4), significantly alters the consequences of carbamazepine binding to the Na⁺ channel. The effect of Y1618K mutation, however, is abolished by concomitant point mutations in the vicinity of Y1618, but not by those in the internally located inactivation machinery, supporting a direct local rather than a long-range allosteric action. Moreover, Y1618 could interact with D4 pore residues W1716 and L1719 to have a profound effect on both channel gating and anticonvulsant action. We conclude that there are direct interactions among the external S3-4 linker, the external pore loop, and the internal S6 segment in D4, making the external pore loop a pivotal point critically coordinating ion permeation, gating, and anticonvulsant binding in the Na⁺ channel.     

The K+ channel in the plasma membrane of rye roots has a multiple ion residency pore

The permeation of K⁺ and Na⁺ through the pore of a K⁺ channel from the plasma membrane of rye roots was studied in planar 1-palmitoyl-2-oleoyl phosphatidylethanolamine bilayers. The pore contains at least two ion-binding sites which can be occupied simultaneously. This was indicated by: (i) biphasic relationships with increasing cation concentration of both channel conductance at the zero-current (reversal) potential of the channel (E _rev) and unitary-current at a specified voltage and (ii) a decline in E _rev in the presence of equimolar Na⁺ (cis):K⁺ (trans) as the cation concentration was increased. To determine the spatial characteristics and energy profiles for K⁺ and Na⁺ permeation, unitary-current/ voltage data for the channel were fitted to a three energy-barrier, two ion-binding site (3B2S) model. The model allowed for simultaneous occupancy of binding sites and ionic repulsion within the pore, as well as surface potential effects. Results suggested that energy peaks and energy wells (ion binding sites) were situated asymmetrically within the electrical distance of the pore, the trans energy-well being closer to the center of the pore than its cis counterpart; that the energy profile for K⁺ permeation differed significantly from that of Na⁺ in having a higher cis energy peak and a deeper cis energy well; that cations repelled each other within the pore and that vestibule surface charge was negligible. The model successfully simulated various aspects of K⁺ and Na⁺ permeation including: (i) the complexities in current rectification over a wide range of contrasting ionic conditions; (ii) the biphasic relationships with increasing cation concentration of both channel conductance at E _rev and unitary-current at a specified voltage; (iii) the decline in E _rev in equimolar Na⁺ (cis):K⁺ (trans) as cation concentrations were increased and (iv) the complex relationships between mole fraction and E _rev at total cation concentrations of 100 and 300 mm.We thank Prof. O. Alvarez (Universidad de Chile, Santiago, Chile) for supplying the computer program AJUSTE and Prof. D. Sanders (University of York, UK), Prof. D. Gradmann and Dr. G. Thiel (University of Göttingen, Germany) for stimulating ideas. This work was supported by the Agricultural and Food Research Council.     

Oleic acid blocks the calcium-activated chloride channel TMEM16A/ANO1

The calcium-activated chloride channel TMEM16A (ANO1) supports the passive movement of chloride ions across membranes and controls critical cell functions. Here we study the block of wild-type and mutant TMEM16A channels expressed in HEK293 cells by oleic acid, a monounsaturated omega-9 fatty acid beneficial for cardiovascular health. We found that oleic acid irreversibly blocks TMEM16A in a dose- and voltage-dependent manner at low intracellular Ca²⁺. We tested whether oleic acid interacted with the TMEM16A pore, varying the permeant anion concentration and mutating pore residues. Lowering the permeating anion concentration in the intracellular side did nothing but the blockade was intensified by increasing the anion concentration in the extracellular side. However, the blockade of the pore mutants E633A and I641A was voltage-independent, and the I641A IC₅₀, a mutant with the inner hydrophobic gate in disarray, increased 16-fold. Furthermore, the uncharged methyl-oleate blocked 20–24% of the wild-type and I641A channels regardless of voltage. Our findings suggest that oleic acid inhibits TMEM16A by an allosteric mechanism after the electric field drives oleic acid's charged moiety inside the pore. Block of TMEM16A might be why oleic acid has a beneficial impact on the cardiovascular system.     

Contribution of residues in second transmembrane domain of ASIC1a protein to ion selectivity

Acid-sensing ion channels (ASICs) are proton-gated cation-selective channels expressed in the peripheral and central nervous systems. The ion permeation pathway of ASIC1a is defined by residues 426–450 in the second transmembrane (TM2) segment. The gate, formed by the intersection of the TM2 segments, localizes near the extracellular boundary of the plasma membrane. We explored the contribution to ion permeation and selectivity of residues in the TM2 segment of ASIC1a. Studies of accessibility with positively charged methanethiosulfonate reagents suggest that the permeation pathway in the open state constricts below the gate, restricting the passage to large ions. Substitution of residues in the intracellular vestibule at positions 437, 438, 443, or 446 significantly increased the permeability to K⁺ versus Na⁺. ASIC1a shows a selectivity sequence for alkali metals of Na⁺>Li⁺>K⁺≫Rb⁺>Cs⁺. Alanine and cysteine substitutions at position 438 increased, to different extents, the relative permeability to Li⁺, K⁺, Rb⁺, and Cs⁺. For these mutants, ion permeation was not a function of the diameter of the nonhydrated ion, suggesting that Gly-438 encompasses an ion coordination site that is essential for ion selectivity. M437C and A443C mutants showed slightly increased permeability to K⁺, Rb⁺, and Cs⁺, suggesting that substitutions at these positions influence ion discrimination by altering molecular sieving. Our results indicate that ion selectivity is accomplished by the contribution of multiple sites in the pore of ASIC1a.     

Functional analysis of human Na~+/K~+-ATPase familial or sporadic hemiplegic migraine mutations expressed in Xenopus oocytes

AIM: Functional characterization of ATP1A2 mutations that are related to familial or sporadic hemiplegic migraine(FHM2, SHM). METHODS: cRNA of human Na+/K+-ATPase α2- and β1-subunits were injected in Xenopus laevis oocytes. FHM2 or SHM mutations of residues located in putative α/β interaction sites or in the α2-subunit's C-terminal region were investigated. Mutants were analyzed by the twoelectrode voltage-clamp(TEVC) technique on Xenopus oocytes. Stationary K+-induced Na+/K+ pump currents were measured, and the voltage dependence of apparent K+ affinity was investigated. Transient currents were recorded as ouabain-sensitive currents in Na+ buffers to analyze kinetics and voltage-dependent presteady state charge translocations. The expression of constructs was verified by preparation of plasma membrane and total membrane fractions of cRNA-injected oocytes. RESULTS: Compared to the wild-type enzyme, the mutants G900R and E902K showed no significant dif-ferences in the voltage dependence of K+-induced currents, and analysis of the transient currents indicated that the extracellular Na+ affinity was not affected. Mutant G855R showed no pump activity detectable by TEVC. Also for L994del and Y1009X, pump currents could not be recorded. Analysis of the plasma and total membrane fractions showed that the expressed proteins were not or only minimally targeted to the plasma membrane. Whereas the mutation K1003E had no impact on K+ interaction, D999H affected the voltage dependence of K+-induced currents. Furthermore, kinetics of the transient currents was altered compared to the wild-type enzyme, and the apparent affinity for extracellular Na+ was reduced. CONCLUSION: The investigated FHM2/SHM mutations influence protein function differently depending on the structural impact of the mutated residue.     

Control of ion selectivity in LeuT: two Na+ binding sites with two different mechanisms

The x-ray structure of LeuT, a bacterial homologue of Na⁺/Cl⁻-dependent neurotransmitter transporters, provides a great opportunity to better understand the molecular basis of monovalent cation selectivity in ion-coupled transporters. LeuT possesses two ion binding sites, NA1 and NA2, which are highly selective for Na⁺. Extensive all-atom free-energy molecular dynamics simulations of LeuT embedded in an explicit membrane are performed at different temperatures and various occupancy states of the binding sites to dissect the molecular mechanism of ion selectivity. The results show that the two binding sites display robust selectivity for Na⁺ over K⁺ or Li⁺, the competing ions of most similar radii. Of particular interest, the mechanism primarily responsible for selectivity for each of the two binding sites appears to be different. In NA1, selectivity for Na⁺ over K⁺ arises predominantly from the strong electrostatic field arising from the negatively charged carboxylate group of the leucine substrate coordinating the ion directly. In NA2, which comprises only neutral ligands, selectivity for Na⁺ is enforced by the local structural restraints arising from the hydrogen-bonding network and the covalent connectivity of the polypeptide chain surrounding the ion according to a “snug-fit” mechanism.     

Ion selectivity of the Kat1 K+ channel pore

Kat1 is a highly selective inward-rectifying K⁺ channel that opens for extended periods under conditions of extreme hyperpolarization. Over 200 point mutants in the pore region of the Kat1 K⁺ channel were generated and examined in the yeast Saccharomyces cerevisiae and Xenopus oocytes to assess the effect of the mutations on ion selectivity. Substitutions at the tyrosine of the signature sequence G-Y-G resulted in the most significant alterations in ion selectivity, consistent with its role in the selectivity filter. However, greater than 80% of the mutations throughout the greater pore region also conferred a defect in selectivity demonstrating that the entire pore of Kat1 contributes to the ion selectivity of this channel. Surprisingly, we identified a novel class of mutant channel that conferred enhanced selectivity of K⁺ over Na⁺. Mutants of this class frequently displayed sensitivity to the competing ion Cs⁺. This finding has led us to speculate that the Kat1 channel pore has evolved to balance not only K⁺/Na⁺ selectivity, but selectivity over Cs⁺, and possibly a wide spectrum of potential competing ions.     

Exploring the Structure of the Voltage-gated Na+ Channel by an Engineered Drug Access Pathway to the Receptor Site for Local Anesthetics

Despite the availability of several crystal structures of bacterial voltage-gated Na⁺ channels, the structure of eukaryotic Na⁺ channels is still undefined. We used predictions from available homology models and crystal structures to modulate an external access pathway for the membrane-impermeant local anesthetic derivative QX-222 into the internal vestibule of the mammalian rNa_V1.4 channel. Potassium channel-based homology models predict amino acid Ile-1575 in domain IV segment 6 to be in close proximity to Lys-1237 of the domain III pore-loop selectivity filter. The mutation K1237E has been shown previously to increase the diameter of the selectivity filter. We found that an access pathway for external QX-222 created by mutations of Ile-1575 was abolished by the additional mutation K1237E, supporting the notion of a close spatial relationship between sites 1237 and 1575. Crystal structures of bacterial voltage-gated Na⁺ channels predict that the side chain of rNa_V1.4 Trp-1531 of the domain IV pore-loop projects into the space between domain IV segment 6 and domain III pore-loop and, therefore, should obstruct the putative external access pathway. Indeed, mutations W1531A and W1531G allowed for exceptionally rapid access of QX-222. In addition, W1531G created a second non-selective ion-conducting pore, bypassing the outer vestibule but probably merging into the internal vestibule, allowing for control by the activation gate. These data suggest a strong structural similarity between bacterial and eukaryotic voltage-gated Na⁺ channels.     

Mutations at Arginine 352 Alter the Pore Architecture of CFTR

Arginine 352 (R352) in the sixth transmembrane domain of the cystic fibrosis transmembrane conductance regulator (CFTR) previously was reported to form an anion/cation selectivity filter and to provide positive charge in the intracellular vestibule. However, mutations at this site have nonspecific effects, such as inducing susceptibility of endogenous cysteines to chemical modification. We hypothesized that R352 stabilizes channel structure and that charge-destroying mutations at this site disrupt pore architecture, with multiple consequences. We tested the effects of mutations at R352 on conductance, anion selectivity and block by the sulfonylurea drug glipizide, using recordings of wild-type and mutant channels. Charge-altering mutations at R352 destabilized the open state and altered both selectivity and block. In contrast, R352K-CFTR was similar to wild-type. Full conductance state amplitude was similar to that of wild-type CFTR in all mutants except R352E, suggesting that R352 does not itself form an anion coordination site. In an attempt to identify an acidic residue that may interact with R352, we found that permeation properties were similarly affected by charge-reversing mutations at D993. Wild-type-like properties were rescued in R352E/D993R-CFTR, suggesting that R352 and D993 in the wild-type channel may interact to stabilize pore architecture. Finally, R352A-CFTR was sensitive to modification by externally applied MTSEA⁺, while wild-type and R352E/D993R-CFTR were not. These data suggest that R352 plays an important structural role in CFTR, perhaps reflecting its involvement in forming a salt bridge with residue D993.     

Hydration valve controlled non-selective conduction of Na and K in the NaK channel

The Na⁺ and K⁺ channels are essential to neural signaling, but our current knowledge at the atomic level is mainly limited to the conducting mechanism of K⁺. Unlike a K⁺ channel having four equivalent K⁺-binding sites in its selectivity filter, a NaK channel has a vestibule in the middle part of its selectivity filter, and can conduct both Na⁺ and K⁺ ions. However, the underlying mechanism for non-selective ion conduction in NaK remains elusive. Here we find four small grottos connecting with the vestibule of the NaK selectivity filter, which form a vestibule-grotto complex perpendicular to the filter pore with a few water molecules within it. It is shown that two or more of the water molecules coming to the vestibule to coordinate the cation are necessary for conducting both Na⁺ and K⁺ ions, while only one water molecule in the vestibule will obstruct ion permeation. Thus, the complex with the aid of interior water movement forms a dynamic hydration valve which is flexible in conveying different cations through the vestibule. Similar exquisite hydration valve mechanisms are expected to be utilized by other non-selective cation channels, and the results should shed new light on the importance of water in neural signaling.     

The twins K and Na in plants

In the earth's crust and in seawater, K⁺ and Na⁺ are by far the most available monovalent inorganic cations. Physico-chemically, K⁺ and Na⁺ are very similar, but K⁺ is widely used by plants whereas Na⁺ can easily reach toxic levels. Indeed, salinity is one of the major and growing threats to agricultural production. In this article, we outline the fundamental bases for the differences between Na⁺ and K⁺. We present the foundation of transporter selectivity and summarize findings on transporters of the HKT type, which are reported to transport Na⁺ and/or Na⁺ and K⁺, and may play a central role in Na⁺ utilization and detoxification in plants. Based on the structural differences in the hydration shells of K⁺ and Na⁺, and by comparison with sodium channels, we present an ad hoc mechanistic model that can account for ion permeation through HKTs.     

Sodium Blocking Induced by a Point Mutation at the C-Terminal End of the Pore Helix of the KAT1 Channel

A plant hyperpolarization-activating K⁺ channel, KAT1, is highly selective for K⁺ over Na⁺ and is little affected by external Na⁺, which is crucial to take up K⁺ effectively in a Na⁺-containing environment. It has been shown that a mutation at the location (Thr256) preceding the selectivity signature sequence dramatically enhanced the sensitivity of the KAT1 channel to external Na⁺. We report here electrophysiological experiments for the mechanism of action of external Na⁺ on KAT1 channels. The Thr256 residue was substituted with either glutamine (Q) or glutamate (E). The wild-type channel was insensitive to external Na⁺. However, the activity of both mutant channels was significantly depressed by Na⁺ with apparent dissociation constants of 6.7 mm and 11.3 mm for T256Q and T256E, respectively. The instantaneous current-voltage relationships revealed distinct blocking mechanisms for these mutants. For T256Q a typical voltage-dependent fast blocking was shown. On the other hand, the blocking for the T256E mutant was voltage-independent at low Na⁺ concentrations and became voltage-dependent at higher concentrations. At extreme hyperpolarization the blocking was relieved significantly. These data strongly suggest that the mutation at the end of the pore helix rearranged the selectivity filter and allows Na⁺ to penetrate into the pore. Received: 16 October 2000/Revised: 20 February 2001     

Energy distribution and ion selectivity of the bacterial potassium channel

The ion selectivity of the bacterial potassium channel K_CSA is explained upon comparing the energy characteristics of the interaction of cations (Li⁺, Na⁺, K⁺) with atoms of the selectivity filter of the protein pore. Quantum-chemical calculations reveal a deeper potential well for potassium ions, which accounts for preferred K⁺ permeation. It is shown that the conventional methods with AMBER, CHARMM, OPLS force fields in standard parametrization as well as partial re-parametrization give incorrect estimates of ion energy distribution in the channel.     

Anion-cation permeability correlates with hydrated counterion size in glycine receptor channels

The functional role of ligand-gated ion channels depends critically on whether they are predominantly permeable to cations or anions. However, these, and other ion channels, are not perfectly selective, allowing some counterions to also permeate. To address the mechanisms by which such counterion permeation occurs, we measured the anion-cation permeabilities of different alkali cations, Li⁺ Na⁺, and Cs⁺, relative to either Cl⁻ or anions in both a wild-type glycine receptor channel (GlyR) and a mutant GlyR with a wider pore diameter. We hypothesized and showed that counterion permeation in anionic channels correlated inversely with an equivalent or effective hydrated size of the cation relative to the channel pore radius, with larger counterion permeabilities being observed in the wider pore channel. We also showed that the anion component of conductance was independent of the nature of the cation. We suggest that anions and counterion cations can permeate through the pore as neutral ion pairs, to allow the cations to overcome the large energy barriers resulting from the positively charged selectivity filter in small GlyR channels, with the permeability of such ion pairs being dependent on the effective hydrated diameter of the ion pair relative to the pore diameter.     

Altered Ionic Selectivity of the Sodium Channel Revealed by Cysteine Mutations within the Pore

To explore the role of pore-lining amino acids in Na⁺ channel ion-selectivity, pore residues were  replaced serially with cysteine in cloned rat skeletal muscle Na⁺ channels. Ionic selectivity was determined by measuring permeability and ionic current ratios of whole-cell currents in Xenopus oocytes. The rSkM1 channels displayed an ionic selectivity sequence Na⁺>Li⁺>NH₄ ⁺>>K⁺>>Cs⁺ and were impermeable to divalent cations.  Replacement of residues in domain IV showed significantly enhanced current and permeability ratios of NH₄ ⁺ and K⁺, and negative shifts in the reversal potentials recorded in the presence of external Na⁺ solutions when compared to cysteine mutants in domains I, II, and III (except K1237C). Mutants in domain IV showed altered selectivity sequences: W1531C (NH₄ ⁺>K⁺>Na⁺≥Li⁺≈Cs⁺), D1532C, and G1533C (Na⁺>Li⁺≥NH₄ ⁺>K⁺>Cs⁺). Conservative replacement of the aromatic residue in domain IV (W1531) with phenylalanine or tyrosine retained Na⁺ selectivity of the channel while the alanine mutant (W1531A) reduced ion selectivity. A single mutation within the third pore forming region (K1237C) dramatically altered the selectivity sequence of the rSkM1 channel (NH₄ ⁺>K⁺>Na⁺≥Li⁺≈Cs⁺) and was permeable to divalent cations having the selectivity sequence Ca²⁺≥Sr²⁺>Mg²⁺>Ba²⁺. Sulfhydryl modification of K1237C, W1531C or D1532C with methanethiosulfonate derivatives that introduce a positively charged ammonium group, large trimethylammonium moiety, or a negatively charged sulfonate group within the pore was ineffective in restoring Na⁺ selectivity to these channels. Selectivity of D1532C mutants could be largely restored by increasing extracellular pH suggesting altering the ionized state at this position influences selectivity. These data suggest that K1237 in domain III and W1531, D1532, and G1533 in domain IV play a critical role in determining the ionic selectivity of the Na⁺ channel.     

An Energy-Barrier Model for the Permeation of Monovalent and Divalent Cations Through the Maxi Cation Channel in the Plasma Membrane of Rye Roots

The depolarization-activated, high-conductance ``maxi' cation channel in the plasma membrane of rye (Secale cereale L.) roots is permeable to a wide variety of monovalent and divalent cations. The permeation of K⁺, Na⁺, Ca²⁺ and Ba²⁺ through the pore could be simulated using a model composed of three energy barriers and two ion binding sites (a 3B2S model), which assumed single-file permeation and the possibility of double cation occupancy. The model had an asymmetrical free energy profile. Differences in permeation between cations were attributed primarily to differences in their free energy profiles in the regions of the pore adjacent to the extracellular solution. In particular, the height of the central free energy peak differed between cations, and cations differed in their affinities for ion binding sites. Significant ion repulsion occurred within the pore, and the mouths of the pore had considerable surface charge. The model adequately described the diverse current vs. voltage (I/V) relationships obtained over a wide variety of experimental conditions. It described the phenomena of non-Michaelian unitary conductance vs. activity relationships for K⁺, Na⁺ and Ca²⁺, differences in selectivity sequences obtained from measurements of conductance and permeability ratios, changes in relative cation permeabilities with solution composition, and the complex effects of Ba²⁺ and Ca²⁺ on K⁺ currents through the channel. The model enabled the prediction of unitary currents and ion fluxes through the maxi cation channel under physiological conditions. It could be used, in combination with data on the kinetics of the channel, as input to electrocoupling models allowing the relationships between membrane voltage, Ca²⁺ influx and Ca²⁺ signaling to be studied theoretically. Received: 29 April 1998/Revised: 20 November 1998