Nonindependent K+ Movement through the Pore in IRK1 Potassium Channels

We measured unidirectional K⁺ in- and efflux through an inward rectifier K channel (IRK1) expressed in Xenopus oocytes. The ratio of these unidirectional fluxes differed significantly from expectations based on independent ion movement. In an extracellular solution with a K⁺ concentration of 25 mM, the data were described by a Ussing flux-ratio exponent, n′, of ∼2.2 and was constant over a voltage range from −50 to −25 mV. This result indicates that the pore of IRK1 channels may be simultaneously occupied by at least three ions. The IRK1 n′ value of 2.2 is significantly smaller than the value of 3.5 obtained for Shaker K channels under identical conditions. To determine if other permeation properties that reflect multi-ion behavior differed between these two channel types, we measured the conductance (at 0 mV) of single IRK1 channels as a function of symmetrical K⁺ concentration. The conductance could be fit by a saturating hyperbola with a half-saturation K⁺ activity of 40 mM, substantially less than the reported value of 300 mM for Shaker K channels. We investigated the ability of simple permeation models based on absolute reaction rate theory to simulate IRK1 current–voltage, conductance, and flux-ratio data. Certain classes of four-barrier, three-site permeation models are inconsistent with the data, but models with high lateral barriers and a deep central well were able to account for the flux-ratio and single channel data. We conclude that while the pore in IRK1 and Shaker channels share important similarities, including K⁺ selectivity and multi-ion occupancy, they differ in other properties, including the sensitivity of pore conductance to K⁺ concentration, and may differ in the number of K⁺ ions that can simultaneously occupy the pore: IRK1 channels may contain three ions, but the pore in Shaker channels can accommodate four or more ions.     

Clustered Distribution of Calcium Sensitivities: An Indication of Hetero-tetrameric Gating Components in Ca2+-activated K+ Channels Reconstituted from Avian Nasal Gland Cells

High-conductance, Ca²⁺-activated K⁺ channels from the basolateral membrane of rabbit distal colon epithelial cells were reconstituted into planar phospholipid bilayers to examine the effect of Mg²⁺ on the single-channel properties. Mg²⁺ decreases channel current and conductance in a concentration-dependent manner from both the cytoplasmic and the extracellular side of the channel. In contrast to other K⁺ channels, Mg²⁺ does not cause rectification of current through colonic Ca²⁺-activated K⁺ channels. In addition, cytoplasmic Mg²⁺ decreases the reversal potential of the channel. The Mg²⁺-induced decrease in channel conductance is relieved by high K⁺ concentrations, indicating competitive interaction between K⁺ and Mg²⁺. The monovalent organic cation choline also decreases channel conductance and reversal potential, suggesting that the effect is unspecific. The inhibition of channel current by Mg²⁺ and choline most likely is a result of electrostatic screening of negative charges located superficially in the channel entrance. But in addition to charge, other properties appear to be necessary for channel inhibition, as Na⁺ and Ba²⁺ are no (or only weak) inhibitors. Mg²⁺ and possibly other cations may play a role in the regulation of current through these channels. Received: 25 August 1995/Revised: 16 November 1995     

Ca2+-activated K+ permeability in human erythrocytes: Modulation of single-channel events

Elevated levels of intracellular Ca²⁺ activate a K⁺-selective permeability in the membrane of human erythrocytes. Currents through single channels were analysed in excised inside-out membrane patches. The effects of several ions that are known to inhibit K⁺ fluxes are described with respect to the single-channel events. The results suggest that the blocking ions can partly move into the channels (but cannot penetrate) and interact with other ions inside the pore. The reduction of single-channel conductance by Cs⁺, tetraethylammonium and Ba²⁺ and of single-channel activity by quinine and Ba²⁺ is referred to different rates of access to the channel. The concentration- and voltage-dependent inhibition by ions with measurable permeability (Na⁺ and Rb⁺) can be explained by their lower permeability, with single-file movement and ionic interactions inside the pore.     

Three Types of Single Voltage-Dependent Potassium Channels in the Sarcolemma of Frog Skeletal Muscle

Patch-clamp experiments in the sarcolemma of frog skeletal muscle evidenced the presence of three types of voltage-dependent single-channel K⁺ currents. According to their unitary conductance at a membrane voltage of +40 mV, we classified them as 16-, 13-, and 7-pS K⁺ channels. The 16-pS K⁺ channels are active close to a membrane voltage of −80 mV and they do not become inactivated during voltage pulses of 100 ms. Within 10 min after beginning the recording, these channels developed rundown with an exponential time course. The 13-pS K⁺ channels are active near −60 mV; upon a 100-ms depolarization, they exhibited inactivation with an approximate exponential time course. The 7-pS K⁺ channels were recorded at voltages positive to 0 mV. In patches containing all three types of K⁺ channels, the ensemble average currents resemble the kinetic properties of the macroscopic delayed rectifier K⁺ currents recorded in skeletal muscle and other tissues. In conclusion, the biophysical properties of unitary K⁺ currents suggest that these single-channel K⁺ currents may underlie the macroscopic delayed K⁺ currents in frog skeletal muscle fibers. In addition, since the 16- and 13-pS channels were more frequently recorded, both are the main contributors to the delayed K⁺ currents.     

Selectivity Changes during Activation of Mutant Shaker Potassium Channels

Mutations of the pore-region residue T442 in Shaker channels result in large effects on channel kinetics. We studied mutations at this position in the backgrounds of NH₂-terminal–truncated Shaker H4 and a Shaker -NGK2 chimeric channel having high conductance (Lopez, G.A., Y.N. Jan, and L.Y. Jan. 1994. Nature (Lond.). 367: 179–182). While mutations of T442 to C, D, H, V, or Y resulted in undetectable expression in Xenopus oocytes, S and G mutants yielded functional channels having deactivation time constants and channel open times two to three orders of magnitude longer than those of the parental channel. Activation time courses at depolarized potentials were unaffected by the mutations, as were first-latency distributions in the T442S chimeric channel. The mutant channels show two subconductance levels, 37 and 70% of full conductance. From single-channel analysis, we concluded that channels always pass through the larger subconductance state on the way to and from the open state. The smaller subconductance state is traversed in ∼40% of activation time courses. These states apparently represent kinetic intermediates in channel gating having voltage-dependent transitions with apparent charge movements of ∼1.6 e₀. The fully open T442S chimeric channel has the conductance sequence Rb⁺ > NH₄ ⁺ > K⁺. The opposite conductance sequence, K⁺ > NH₄ ⁺ > Rb⁺, is observed in each of the subconductance states, with the smaller subconductance state discriminating most strongly against Rb⁺.     

Ca2+-activated K+ channels in the apical membrane ofNecturus choroid plexus

Summary The properties of Ca²⁺-activated K⁺ channels in the apical membrane of theNecturus choroid plexus were studied using single-channel recording techniques in the cell-attached and excised-patch configurations. Channels with large unitary conductances clustered around 150 and 220 pS were most commonly observed. These channels exhibited a high selectivity for K⁺ over Na⁺ and K⁺ over Cs⁺. They were blocked by high cytoplasmic Na⁺ concentrations (110mm). Channel activity increased with depolarizing membrane potentials, and with increasing cytoplasmic Ca²⁺ concentrations. Increasing Ca²⁺ from 5 to 500nm, increased open probability by an order of magnitude, without changing single-channel conductance. Open probability increased up to 10-fold with a 20-mV depolarization when Ca²⁺ was 500nm. Lowering intracellular pH one unit, decreased open probability by more than two orders of magnitude, but pH did not affect single-channel conductance. Cytoplasmic Ba²⁺ reduced both channel-open probability and conductance. The sites for the action of Ba²⁺ are located at a distance more than halfway through the applied electric field from the inside of the membrane. Values of 0.013 and 117mm were calculated as the apparent Ba²⁺ dissociation constants (K _d (0 mV) for the effects on probability and conductance, respectively. TEA⁺ (tetraethylammonium) reduced single-channel current. Applied to the cytoplasmic side, it acted on a site 20% of the distance through the membrane, with aK _d (0 mV)=5.6mm. A second site, with a higher affinity,K _d (0 mV)=0.23mm, may account for the near total block of chanel conductance by 2mm TEA⁺ applied to the outside of the membrane. It is concluded that the channels inNecturus choroid plexus exhibit many of the properties of maxi Ca²⁺-activated K⁺ channels found in other tissues.     

Pore dimensions and the role of occupancy in unitary conductance of Shaker K channels

K channels mediate the selective passage of K⁺ across the plasma membrane by means of intimate interactions with ions at the pore selectivity filter located near the external face. Despite high conservation of the selectivity filter, the K⁺ transport properties of different K channels vary widely, with the unitary conductance spanning a range of over two orders of magnitude. Mutation of Pro475, a residue located at the cytoplasmic entrance of the pore of the small-intermediate conductance K channel Shaker (Pro475Asp (P475D) or Pro475Gln (P475Q)), increases Shaker’s reported ∼20-pS conductance by approximately six- and approximately threefold, respectively, without any detectable effect on its selectivity. These findings suggest that the structural determinants underlying the diversity of K channel conductance are distinct from the selectivity filter, making P475D and P475Q excellent probes to identify key determinants of the K channel unitary conductance. By measuring diffusion-limited unitary outward currents after unilateral addition of 2 M sucrose to the internal solution to increase its viscosity, we estimated a pore internal radius of capture of ∼0.82 Å for all three Shaker variants (wild type, P475D, and P475Q). This estimate is consistent with the internal entrance of the Kv1.2/2.1 structure if the effective radius of hydrated K⁺ is set to ∼4 Å. Unilateral exposure to sucrose allowed us to estimate the internal and external access resistances together with that of the inner pore. We determined that Shaker resistance resides mainly in the inner cavity, whereas only ∼8% resides in the selectivity filter. To reduce the inner resistance, we introduced additional aspartate residues into the internal vestibule to favor ion occupancy. No aspartate addition raised the maximum unitary conductance, measured at saturating [K⁺], beyond that of P475D, suggesting an ∼200-pS conductance ceiling for Shaker. This value is approximately one third of the maximum conductance of the large conductance K (BK) channel (the K channel of highest conductance), reducing the energy gap between their K⁺ transport rates to ∼1 kT. Thus, although Shaker’s pore sustains ion translocation as the BK channel’s does, higher energetic costs of ion stabilization or higher friction with the ion’s rigid hydration cage in its narrower aqueous cavity may entail higher resistance.     

Two Distinct K+ Channels in Lamprey (Lampetra fluviatilis) Erythrocyte Membrane Characterized by Single Channel Patch Clamp

Two channels, distinguished by using single-channel patch-clamp, carry out potassium transport across the red cell membrane of lamprey erythrocytes. A small-conductance, inwardly rectifying K⁺-selective channel was observed in both isotonic and hypotonic solutions (osmolarity decreased by 50%). The single-channel conductance was 26 ± 3 pS in isotonic (132 mm K⁺) solutions and 24 ± 2 pS in hypotonic (63 mm K⁺) solutions. No outward conductance was found for this channel, and the channel activity was completely inhibited by barium. Cell swelling activated another inwardly rectifying K⁺ channel with a larger inward conductance of 65 pS and outward conductance of 15 pS in the on-cell configuration. In this channel, rectification was due to the block of outward currents by Mg²⁺ and Ca²⁺ ions, since when both ions were removed from the cytosolic side in inside-out patches the conductance of the channel was nearly ohmic. In contrast to the small-conductance channel, the swelling-activated channel was observed also in the presence of barium in the pipette. Neither type of channel was dependent on the presence of Ca²⁺ ions on the cytosolic side for activity. Received: 18 July 1997/Revised: 30 January 1998     

Ionic Selectivity and Permeation Properties of Human PIEZO1 Channels

Members of the eukaryotic PIEZO family (the human orthologs are noted hPIEZO1 and hPIEZO2) form cation-selective mechanically-gated channels. We characterized the selectivity of human PIEZO1 (hPIEZO1) for alkali ions: K⁺, Na⁺, Cs⁺ and Li⁺; organic cations: TMA and TEA, and divalents: Ba²⁺, Ca²⁺, Mg²⁺ and Mn²⁺. All monovalent ions permeated the channel. At a membrane potential of -100 mV, Cs⁺, Na⁺ and K⁺ had chord conductances in the range of 35–55 pS with the exception of Li⁺, which had a significantly lower conductance of ~ 23 pS. The divalents decreased the single-channel permeability of K⁺, presumably because the divalents permeated slowly and occupied the open channel for a significant fraction of the time. In cell-attached mode, 90 mM extracellular divalents had a conductance for inward currents carried by the divalents of: 25 pS for Ba²⁺ and 15 pS for Ca²⁺ at -80 mV and 10 pS for Mg²⁺ at -50 mV. The organic cations, TMA and TEA, permeated slowly and attenuated K⁺ currents much like the divalents. As expected, the channel K⁺ conductance increased with K⁺ concentration saturating at ~ 45 pS and the K_D of K⁺ for the channel was 32 mM. Pure divalent ion currents were of lower amplitude than those with alkali ions and the channel opening rate was lower in the presence of divalents than in the presence of monovalents. Exposing cells to the actin disrupting reagent cytochalasin D increased the frequency of openings in cell-attached patches probably by reducing mechanoprotection.     

Single-Channel Activities of the Human Epithelial Ca2+ Transport Proteins CaT1 and CaT2

The human epithelial channels, CaT1 and CaT2, were expressed in oocytes, and their single-channel characteristics were compared. In the presence of Na⁺ and K⁺ as charge carriers in the pipette solutions, channel activities were observed only when the the extracellular sides of the patches were exposed to nominally Ca²⁺- and Mg²⁺-free solutions. In patches of both CaT1- and CaT2-expressing oocytes, multiple channel openings were observed, but the current levels were higher in CaT2-expressing oocytes, particularly at more negative voltages. With K⁺ as a charge carrier in patches of CaT1-expressing oocytes, the channel activity was low at −10 to −60 mV, but increased dramatically at more negative potentials. This voltage dependence was observed in the presence of both Na⁺ and K⁺. The channel activity with Na⁺, however, was higher at all potentials. Differences between the voltage dependencies for the two cations were also observed in CaT2-expressing oocytes, but the channel activities were higher than those in CaT1-expressing oocytes, particularly in the presence of Na⁺. We also found that low concentrations of extracellular Mg²⁺ (5–50 μm) elicited a strong inhibitory action on the CaT channels. Activation of the CaT1 and CaT2 channels by hyperpolarization and other factors may promote increased Ca²⁺ entry that participates in stimulation of intestinal absorption and renal reabsorption and/or other Ca²⁺ transport mechanisms in epithelial cells. Received: 8 March 2001/Revised: 24 July 2001     

Macroscopic Na+ Currents in the “Nonconducting” Shaker Potassium Channel Mutant W434F

C-type inactivation in Shaker potassium channels inhibits K⁺ permeation. The associated structural changes appear to involve the outer region of the pore. Recently, we have shown that C-type inactivation involves a change in the selectivity of the Shaker channel, such that C-type inactivated channels show maintained voltage-sensitive activation and deactivation of Na⁺ and Li⁺ currents in K⁺-free solutions, although they show no measurable ionic currents in physiological solutions. In addition, it appears that the effective block of ion conduction produced by the mutation W434F in the pore region may be associated with permanent C-type inactivation of W434F channels. These conclusions predict that permanently C-type inactivated W434F channels would also show Na⁺ and Li⁺ currents (in K⁺-free solutions) with kinetics similar to those seen in C-type-inactivated Shaker channels. This paper confirms that prediction and demonstrates that activation and deactivation parameters for this mutant can be obtained from macroscopic ionic current measurements. We also show that the prolonged Na⁺ tail currents typical of C-type inactivated channels involve an equivalent prolongation of the return of gating charge, thus demonstrating that the kinetics of gating charge return in W434F channels can be markedly altered by changes in ionic conditions.     

Extracellular Ca2+ controls outward rectification by apical cation channels in toad urinary bladder: Patch-clamp and whole-bladder studies

Summary Outward rectifying. cation channels were observed in the epithelial cells of the urinary bladder of the toad.Bufo marinus. As studied in isolated cells using the patch-clamp technique, the channel has an average conductance of 24 and 157 pS for pipette potentials between 0 and +60 mV and –60 to –100 mV, respectively, when the major cation in both bath and pipette solutions is K⁺. The conductance of the cannel decreasen with increasing dehydration energy of the permeant monovalent cation in the oder Rb⁺=K⁺>Na⁺>Li⁺. Reversal potentials near zero under biionic conditions imply that the permeabilities for all four of these cations are smiliar. The channel is sensitive to quinidine sulfate but not to amiloride. It shares several pharmacological and biophysical properties with an outwardly-rectifying, vasopressin-sensitive pical K⁺ conductive pathway described previously for the toad urinary bladder. We demonstrate, in both single-channel and whole-bladder studies, that the outward rectification is a consequence of interaction of the chanel with extracellular divalent cations, particularly Ca²⁺, which blocks inward but not outward current. Various divalent cations impart different degrees of outward rectification to the conductive pathway. Concentrations of Mg²⁺ and Ca²⁺ required for halfmaximal effect are 3×10^–4 and 10^–4 m, resopectively. For Co²⁺ the values are 10^–6 m at +50 mV and a 10^–4 m at +200 mV. The mechanism of blockade by divalent cations is not established, but does not seem to involve a voltage-dependent interaction in which the blocker penetrates the transmembrane electric field. In the absence of divalent cations in the mucosal solution, the magnitudes of inward current carried by Rb⁺, K⁺, Na⁺ and Li⁺ through the apical K⁺ pathway at any transepithelial voltage, are in the same order as in the single-channel studies. We propose that the cation channel observed by us in isolated epithelial cells is the single-channel correlate of the vasopressin-sensitive apical K⁺ conductive pathway in the toad urinary bladder and is also related to the oxytocin- and divalent cation-sensitive apical condictivity observed in frog skin and urinary bladder.     

Lack of Negatively Charged Residues at the External Mouth of Kir2.2 Channels Enable the Voltage-Dependent Block by External Mg2+

Kir channels display voltage-dependent block by cytosolic cations such as Mg²⁺ and polyamines that causes inward rectification. In fact, cations can regulate K channel activity from both the extracellular and intracellular sides. Previous studies have provided insight into the up-regulation of Kir channel activity by extracellular K⁺ concentration. In contrast, extracellular Mg²⁺ has been found to reduce the amplitude of the single-channel current at milimolar concentrations. However, little is known about the molecular mechanism of Kir channel blockade by external Mg²⁺ and the relationship between the Mg²⁺ blockade and activity potentiation by permeant K⁺ ions. In this study, we applied an interactive approach between theory and experiment. Electrophysiological recordings on Kir2.2 and its mutants were performed by heterologous expression in Xenopus laevis oocytes. Our results confirmed that extracellular Mg²⁺ could reduce heterologously expressed WT Kir2.2 currents in a voltage dependent manner. The kinetics of inhibition and recovery of Mg²⁺ exhibit a 3∼4s time constant. Molecular dynamics simulation results revealed a Mg²⁺ binding site located at the extracellular mouth of Kir2.2 that showed voltage-dependent Mg²⁺ binding. The mutants, G119D, Q126E and H128D, increased the number of permeant K⁺ ions and reduced the voltage-dependent blockade of Kir2.2 by extracellular Mg²⁺.     

Variable affinity of the (Na+ + K+)-dependent adenosine triphosphatase for potassium: Studies using beryllium inactivation

Inactivation of the (Na⁺ + K⁺)-dependent ATPase by 50 μm BeCl₂ occurred during brief incubations in the presence of both Mg²⁺ and K⁺. Inactivation followed, initially, a first-order time course, with rate constants sensitive to the concentration of K⁺ (other components held constant). From these data dissociation constants can be calculated for K⁺ binding to sites controlling inactivation. Comparisons of relative affinities for K⁺ analogs (T1⁺ and NH₄⁺), and of sensitivity to reagents altering K⁺ activation (phlorizin and dimethylsulfoxide) indicate that the same K⁺ sites operate for both Be²⁺ inactivation and enzyme activation. With 3 mm MgCl₂ the dissociation constant, K_D, for K⁺ was 1.4 mm, but decreased 20-fold on addition of both Na⁺ and CTP. Alone, Na⁺ increased the apparent K_D for K⁺, either by direct competition or indirectly from its own site, with a K_D of 7 mm. The data suggest a model for K⁺ transport with K⁺ sites on the outer membrane surface that increase in affinity after formation of the phosphorylated enzyme intermediate, sufficiently to bind K⁺ in a high Na⁺ environment. Translocation may occur by an “oscillating pore” mechanism discharging K⁺ at the inner surface, while leaving demonstrable sites of moderate affinity at the outer end of the pore (which preclude attempts to document low-affinity discharge sites).     

Mg2+ and ATP effects on K+ activation of the Ca2+-transport ATpase of cardiac sarcoplasmic reticulum

ATP and the divalent cations Mg²⁺ and Ca²⁺ regulated K⁺ stimulation of the Ca²⁺-transport ATPase of cardiac sarcoplasmic reticulum vesicles. Millimolar concentrations of total ATP increased the K⁺-stimulated ATPase activity of the Ca²⁺ pump by two mechanisms. First, ATP chelated free Mg²⁺ and, at low ionized Mg²⁺ concentrations, K⁺ was shown to be a potent activator of ATP hydrolysis. In the absence of K⁺ ionized Mg²⁺ activated the enzyme half-maximally at approximately 1 mM, whereas in the presence of K⁺ the concentration of ionized Mg²⁺ required for half-maximal activation was reduced at least 20-fold. Second MgATP apparently interacted directly with the enzyme at a low affinity nucleotide site to facilitate K⁺-stimulation. With a saturating concentration of ionized Mg²⁺, stimulation by K⁺ was 2-fold, but only when the MgATP concentration was greater than 2 mM. Hill plots showed that K⁺ increased the concentration of MgATP required for half-maximal enzymic activation approx. 3-fold.Activation of K⁺-stimulated ATPase activity by Ca²⁺ was maximal at anionized Ca²⁺ concentration of approx. 1 μM. At very high concentrations of either Ca²⁺ or Mg²⁺, basal Ca²⁺-dependent ATPase activity persisted, but the enzymic response to K⁺ was completely inhibited. The results provide further evidence that the Ca²⁺-transport ATPase of cardiac sarcoplasmic reticulum has distinct sites for monovalent cations, which in turn interact allosterically with other regulatory sites on the enzyme.     

Effect of phospholipid surface charge on the conductance and gating of a Ca2+-activated K+ channel in planar lipid bilayers

Summary A Ca-activated, K-selective channel from plasma membrane of rat skeletal muscle was studied in artificial lipid bilayers formed from either phosphatidylethanolamine (PE) or phosphatidylserine (PS). In PE, the single-channel conductance exhibited a complex dependence on symmetrical K⁺ concentration that could not be described by simple Michaelis-Menten saturation. At low K⁺ concentrations the channel conductance was higher in PS membranes, but approached the same conductance observed in PE above 0.4m KCl. At the same Ca²⁺ concentration and voltage, the probability of channel opening was significantly greater in PS than PE. The differences in the conduction and gating, observed in the two lipids, can be explained by the negative surface charge of PS compared to the neutral PE membrane. Model calculations of the expected concentrations of K⁺ and Ca²⁺ at various distances from a PS membrane surface, using Gouy-Chapman-Stern theory, suggest that the K⁺-conduction and Ca²⁺-activation sites sense a similar fraction of the surface potential, equivalent to the local electrostatic potential at a distance of 9 Å from the surface.     

Studies of (Na+ + K+)-sensitive ATPase activity in pig lymphocytes. Effects of concanavalin A

(Na⁺ + K⁺)-ATPase activity is demonstrated in plasma membranes from pig mesenteric lymph nodes. After dodecyl sulfate treatment plasma membranes have an 18-fold higher (Na⁺ + K⁺)-ATPase activity, while their ouabain-insensitive Mg²⁺-ATPase is markedly lowered. A solubilized (Na⁺ + K⁺)-ATPase fraction, obtained by Lubrol WX treatment of the membranes, has very high specific activity (21μmol P_i/h per mg protein). Concanavalin A has no effect on these partially purified (Na⁺ + K⁺)-ATPase, while it inhibits (40%) this activity in less purified fractions which still contain Mg²⁺-ATPase activity.     

A site accessible to extracellular TEA+ and K+ influences intracellular Mg2+ block of cloned potassium channels

The members of the RCK family of cloned voltage-dependent K⁺ channels are quite homologous in primary structure, but they are highly diverse in functional properties. RCK4 channels differ from RCK1 and RCK2 channels in inactivation and permeation properties, the sensitivity to external TEA, and to current modulation by external K⁺ ions. Here we show several other interesting differences: While RCK1 and RCK2 are blocked in a voltage and concentration dependent manner by internal Mg²⁺ ions, RCK4 is only weakly blocked at very high potentials. The single-channel current-voltage relations of RCK4 are rather linear while RCK2 exhibits an inwardly rectifying single-channel current in symmetrical K⁺ solutions. The deactivation of the channels, measured by tail current protocols, is faster in RCK4 by a factor of two compared with RCK2. In a search for the structural motif responsible for these differences, point mutants creating homology between RCK2 and RCK4 in the pore region were tested. The single-point mutant K533Y in the background of RCK4 conferred the properties of Mg²⁺ block, tail current kinetics, and inward ion permeation of RCK2 to RCK4. This mutant was previously shown to be responsible for the alterations in external TEA sensitivity and channel regulation by external K⁺ ions. Thus, this residue is expected to be located at the external side of the pore entrance. The data are consistent with the idea that the mutation alters the channel occupancy by K⁺ and thereby indirectly affects internal Mg²⁺ block and channel closing.Abbreviations TEA tetraethylammonium - EGTA Ethylene glycol-bis (-aminoethyl ether) N,N,N,N-tetraacetic acid - 2S3B model 2-site 3-barrier model Correspondence to: S. H. Heinemann     

Open-channel block of Na+ channels by intracellular Mg2+

1. Macroscopic and single-channel currents through several types of cloned rat brain Na⁺ channels, expressed in Xenopus oocytes, were measured using the patch-clamp technique. 2. For all cloned channel types and for endogenous Na⁺ channels in chromaffin cells, intracellular Mg²⁺ blocks outward currents in a voltage-dependent manner similar to that in rat brain type II Na⁺ channel (Pusch et al. 1989). 3. A sodium-channel mutant (cZ-2) with long single-channel open times was used to examine the voltage-dependent reduction of single-channel outward current amplitudes by intracellular Mg²⁺. This reduction could be described by a simple blocking mechanism with half-maximal blockage at 0 mV in 1.8 mM intracellular Mg²⁺ and a voltage-dependence of e-fold per 39 mV (in 125 mM [Na] _i ); this corresponds to a binding-site at an electrical distance of 0.32 from the inside of the membrane. 4. At low Mg²⁺ concentrations and high voltages, the open-channel current variance is significantly elevated with respect to zero [Mg] _i . This indicates that Mg²⁺ acts as a fast blocker rather than gradually decreasing current, e.g. by screening of surface charges. Analysis of the open-channel variance yielded estimates of the block and unblock rate constants, which are of the order of 2 · 10⁸ M^–1 s^–1 and 3.6 · 10⁵ s^–1 at 0 mV for the mutant cZ-2. 5. A quantitative analysis of tail-currents of wild-type 11 channels showed that the apparent affinity for intracellular Mg²⁺ strongly depends on [Na] _i . This effect could be explained in terms of a multi-ion pore model. 6. Simulated action potentials, calculated on the basis of the Hodgkin-Huxley theory, are significantly reduced in their amplitude and delayed in their onset by postulating Mg²⁺ block at physiological levels of [Mg] _i .abbreviations [Na]_i intracellular Na⁺ concentration - [K] _i intracellular K⁺ concentration - [Mg] _i intracellular Mg²⁺ concentration - HEPES N-2-hydroxylethyl piperazine-N-2-ethanesulfonic acid - EGTA ethyleneglycol-bis-[\-amino-ethyl ether] N,N-tetra acetic acid - TEA tetraethylammonium     

Single-channel basis for conductance increase induced by isoflurane in Shaker H4 IR K(+) channels

Volatileanesthetics modulate the function of various K⁺ channels.We previously reported that isoflurane induces an increase inmacroscopic currents and a slowing down of current deactivation ofShaker H4 IR K⁺ channels. To understand thesingle-channel basis of these effects, we performed nonstationary noiseanalysis of macroscopic currents and analysis of single channels inpatches from Xenopus oocytes expressing Shaker H4IR. Isoflurane (1.2% and 2.5%) induced concentration-dependent, partially reversible increases in macroscopic currents and in the timecourse of tail currents. Noise analysis of currents (70 mV) revealed anincrease in unitary current (~17%) and maximum open probability(~20%). Single-channel conductance was larger (~20%), and openingevents were more stable, in isoflurane. Tail-current slow timeconstants increased by 41% and 136% in 1.2% and 2.5% isoflurane,respectively. Our results show that, in a manner consistent withstabilization of the open state, isoflurane increased the macroscopicconductance of Shaker H4 IR K⁺ channels byincreasing the single-channel conductance and the open probability.