Ion-channels reconstituted into lipid bilayer from human sperm plasma membrane

Ion environment and ionic fluxes through membrane are thought to be important in the spermatozoa's maturation, capacitation, and the initiating process of gamete interaction. In this work, the membrane proteins isolated from human sperm plasma membrane were reconstituted into planar lipid bilayers via fusion, and the ion channels activities were observed under voltage clamp mode. In cis 200 // trans 100 mM KCl solution, a TEA-sensitive cation-selective channel with a unit conductance of 40 pS was recorded. In a gradient of 200//100 mM NaCl solutions, a Na⁺-selective channel with a unit conductance of 26 pS was recorded. In both cases, reversal potential was about −18 mV, which is close to the predicated value of a perfect Nernst K⁺ or Na⁺ electrode. In 50//10 mM CaCl₂ solution, a cation channel activity with a unit conductance of 40 pS and reversal potential of about −20 mV was usually observed. In 200//100 mM NMDG(N-methyl-D-glucamine)-Cl solution, where the cation ions were substituted with NMDG, a 30-pS anion-selective channel activity was also detected. The variety in the types of ion channels observed in human spermatozoa plasma membrane suggests that ion channels may play a range of different roles in sperm physiology and gamete interaction. Mol. Reprod. Dev. 50:354–360, 1998. © 1998 Wiley-Liss, Inc.     

Isolation and purification of human blood plasma proteins able to form potassium channels in artificial bilayer lipid membrane

A protein fraction able to induce K⁺-selective transport across a bilayer lipid membrane was isolated from human blood plasma with the use of the detergent- and proteolytic enzyme-free method developed in our laboratory. After addition of the studied sample to the artificial membrane in the presence of 100 mM KCl, a discrete current change was observed. No channel activity was recorded in the presence of calcium and sodium ions. Channel-forming activity of the fraction was observed only in the presence of K⁺. Using a threefold gradient of KCl in the presence of studied proteins, a potassium-selective potential balanced by voltage of ?29 mV was registered. This value is very close to the theoretical Nernst potential in this case. This means that the examined ion channel is cation-selective. According to the data obtained with MS-MALDI-TOF/TOF and NCBI database, three protein components were identified in the isolated sample.     

Voltage-activated ionic channels and conductances in embryonic chick osteoblast cultures

Summary Patch-clamp measurements were made on osteoblast-like cells isolated from embryonic chick calvaria. Cell-attachedpatch measurements revealed two types of high conductance (100–250 pS) channels, which rapidly activated upon 50–100 mV depolarization. One type showed sustained and the other transient activation over a 10-sec period of depolarization. The single-channel conductances of these channel types were about 100 or 250 pS, depending on whether the pipettes were filled with a low K⁺ (3mm) or high K⁺ (143mm) saline, respectively. The different reversal potentials under these conditions were consistent with at least K⁺ conduction. Whole-cell measurements revealed the existence of two types of outward rectifying conductances. The first type conducts K⁺ ions and activates within 20–200 msec (depending on the stimulus) upon depolarizing voltage steps from <–60 mV to >–30 mV. It inactivates almost completely with a time constant of 2–3 sec. Recovery from inactivation is biphasic with an initial rapid phase (1–2 sec) followed by a slow phase (>20 sec). The second whole-cell conductance activates at positive membrane potentials of >+50 mV. It also rapidly turns on upon depolarizing voltage steps. Activation may partly disappear at the higher voltages. Its single channels of 140 pS conductance were identified in the whole cell and did conduct K⁺ ions but were not highly Cl^– or Na⁺ selective. The results show that osteoblasts may express various types of voltage controlled ionic channels. We predict a role for such channels in mineral metabolism of bone tissue and its control by osteoblasts.     

The effects of stretch activation on ionic selectivity of the TREK-2 K2P K+ channel

The TREK-2 (KCNK10) K2P potassium channel can be regulated by variety of polymodal stimuli including pressure. In a recent study, we demonstrated that this mechanosensitive K⁺ channel responds to changes in membrane tension by undergoing a major structural change from its ‘down’ state to the more expanded ‘up’ state conformation. These changes are mostly restricted to the lower part of the protein within the bilayer, but are allosterically coupled to the primary gating mechanism located within the selectivity filter. However, any such structural changes within the filter also have the potential to alter ionic selectivity and there are reports that some K2Ps, including TREK channels, exhibit a dynamic ionic selectivity. In this addendum to our previous study we have therefore examined whether the selectivity of TREK-2 is altered by stretch activation. Our results reveal that the filter remains stable and highly selective for K⁺ over Na⁺ during stretch activation, and that permeability to a range of other cations (Rb⁺, Cs⁺ and NH₄⁺) also does not change. The asymmetric structural changes that occur during stretch activation therefore allow the channel to respond to changes in membrane tension without a loss of K⁺ selectivity.     

Phe-Met-Arg-Phe-amide Activates a Novel Voltage-dependent K+ Current through a Lipoxygenase Pathway in Molluscan Neurones

The neuropeptide Phe-Met-Arg-Phe-amide (FMRFa) dose dependently (ED₅₀ = 23 nM) activated a K⁺ current in the peptidergic caudodorsal neurones that regulate egg laying in the mollusc Lymnaea stagnalis. Under standard conditions ([K⁺]_o = 1.7 mM), only outward current responses occurred. In high K⁺ salines ([K⁺]_o = 20 or 57 mM), current reversal occurred close to the theoretical reversal potential for K⁺. In both salines, no responses were measured below −120 mV. Between −120 mV and the K⁺ reversal potential, currents were inward with maximal amplitudes at ∼−60 mV. Thus, U-shaped current–voltage relations were obtained, implying that the response is voltage dependent. The conductance depended both on membrane potential and extracellular K⁺ concentration. The voltage sensitivity was characterized by an e-fold change in conductance per ∼14 mV at all [K⁺]_o. Since this result was also obtained in nearly symmetrical K⁺ conditions, it is concluded that channel gating is voltage dependent. In addition, outward rectification occurs in asymmetric K⁺ concentrations. Onset kinetics of the response were slow (rise time ∼650 ms at −40 mV). However, when FMRFa was applied while holding the cell at −120 mV, to prevent activation of the current but allow activation of the signal transduction pathway, a subsequent step to −40 mV revealed a much more rapid current onset. Thus, onset kinetics are largely determined by steps preceding channel activation. With FMRFa applied at −120 mV, the time constant of activation during the subsequent test pulse decreased from ∼36 ms at −60 mV to ∼13 ms at −30 mV, confirming that channel opening is voltage dependent. The current inactivated voltage dependently. The rate and degree of inactivation progressively increased from −120 to −50 mV. The current is blocked by internal tetraethylammonium and by bath- applied 4-aminopyridine, tetraethylammonium, Ba²⁺, and, partially, Cd²⁺ and Cs⁺. The response to FMRFa was affected by intracellular GTPγS. The response was inhibited by blockers of phospholipase A₂ and lipoxygenases, but not by a cyclo-oxygenase blocker. Bath-applied arachidonic acid induced a slow outward current and occluded the response to FMRFa. These results suggest that the FMRFa receptor couples via a G-protein to the lipoxygenase pathway of arachidonic acid metabolism. The biophysical and pharmacological properties of this transmitter operated, but voltage-dependent K⁺ current distinguish it from other receptor-driven K⁺ currents such as the S-current- and G-protein-dependent inward rectifiers.     

Inward and outward currents of native and cloned K(ATP) channels (Kir6.2/SUR1) share single-channel kinetic properties

BackgroundThe ATP-sensitive K⁺ (K(ATP)) channel is found in a variety of tissues extending from the heart and vascular smooth muscles to the endocrine pancreas and brain. Common to all K(ATP) channels is the pore-forming subunit Kir6.x, a member of the family of small inwardly rectifying K⁺ channels, and the regulatory subunit sulfonylurea receptor (SURx). In insulin secreting β-cells in the endocrine part of the pancreas, where the channel is best studied, the K(ATP) channel consists of Kir6.2 and SUR1. Under physiological conditions, the K(ATP) channel current flow is outward at membrane potentials more positive than the K⁺ equilibrium potential around ?80 mV. However, K(ATP) channel kinetics have been extensively investigated for inward currents and the single-channel kinetic model is based on this type of recording, whereas only a limited amount of work has focused on outward current kinetics.MethodsWe have estimated the kinetic properties of both native and cloned K(ATP) channels under varying ionic gradients and membrane potentials using the patch-clamp technique.ResultsAnalyses of outward currents in K(ATP) and cloned Kir6.2ΔC26 channels, alone or co-expressed with SUR1, show openings that are not grouped in bursts as seen for inward currents. Burst duration for inward current corresponds well to open time for outward current.ConclusionsOutward K(ATP) channel currents are not grouped in bursts regardless of membrane potential, and channel open time for outward currents corresponds to burst duration for inward currents.     

Ca2+ activation and pH dependence of a maxi K+ channel from rabbit distal colon epithelium

To determine if their properties are consistent with a role in regulation of transepithelial transport, Ca²⁺-activated K⁺ channels from the basolateral plasma membrane of the surface cells in the distal colon have been characterized by single channel analysis after fusion of vesicles with planar lipid bilayers. A Ca²⁺-activated K⁺ channel with a single channel conductance of 275 pS was predominant. The sensitivity to Ca²⁺ was strongly dependent on the membrane potential and on the pH. At a neutral pH, the K _0.5 for Ca²⁺ was raised from 20nm at a potential of 0 mV to 300nm at –40 mV. A decrease in pH at the cytoplasmic face of the K⁺ channel reduced the Ca²⁺ sensitivity dramatically. A loss of the high sensitivity to Ca²⁺ was also observed after incubation with MgCl₂, possibly a result of dephosphorylation of the channels by endogenous phosphatases. Modification of the channel protein may thus explain the variation in Ca²⁺ sensitivity between studies on K⁺ channels from the same tissue. High affinity inhibition (K _0.5=10nm) by charybdotoxin of the Ca²⁺-activated K⁺ channel from the extracellular face could be lifted by an outward flux of K⁺ through the channel. However, at the ion gradients and potentials found in the intact epithelium, charybdotoxin should be a useful tool for examination of the role of maxi K⁺ channels. The high sensitivity for Ca²⁺ and the properties of the activator site are in agreement with an important regulatory role for the high conductance K⁺ channel in the epithelial cells.Dr. E. Moczydlowsky, Yale University School of Medicine, New Haven, CT, and Dr. Per Stampe, Brandeis University, Waltham, MA, are thanked for introduction to the bilayer technique. Tove Soland is thanked for excellent technical assistance. This work was supported by the Novo Nordisk Foundation, the Carlsberg Foundation, the Danish Medical Research Council, and the Austrian Research Council.     

Molecular dynamics simulations of asymmetric NaCl and KCl solutions separated by phosphatidylcholine bilayers: potential drops and structural changes induced by strong Na+-lipid interactions and finite size effects

Differences of ionic concentrations across lipid bilayers are some of the primary energetic driving forces for cellular electrophysiology. While macroscopic models of asymmetric ionic solutions are well-developed, their connection to ion, water, and lipid interactions at the atomic scale are much more poorly understood. In this study, we used molecular dynamics to examine a system of two chambers of equal ionic strength, but differing amounts of NaCl and KCl, separated by a lipid bilayer. Our expectation was that the net electrostatic potential difference between the two chambers should be small or zero. Contrary to our expectation, a large potential difference (−70 mV) slowly evolved across the two water chambers over the course of our 172-ns simulation. This potential primarily originated from strong Na⁺ binding to the carbonyls of the phosphatidylcholine lipids. This ion adsorption also led to significant structural and mechanical changes in the lipid bilayer. We discuss this surprising result in the context of indirect experimental evidence for Na⁺ interaction with bilayers as well as potential caveats in current biomembrane simulation methodology, including force-field parameters and finite size effects.     

ATP-sensitive K+ channel opener acts as a potent Cl− channel inhibitor in vascular smooth muscle cells

We describe the activation of a K⁺ current and inhibition of a Cl^– current by a cyanoguanidine activator of ATP-sensitive K⁺ channels (K_ATP) in the smooth muscle cell line A10. The efficacy of U83757, an analogue of pinacidil, as an activator of K_ATP was confirmed in single channel experiments on isolated ventricular myocytes. The effects of U83757 were examined in the clonal smooth muscle cell line A10 using voltage-sensitive dyes and digital fluorescent imaging techniques. Exposure of A10 cells to U83757 (10 nm to 1 m) produced a rapid membrane hyperpolarization as monitored by the membrane potential-sensitive dye bis-oxonol ([diBAC₄(3)], 5 m). The U83757induced hyperpolarization was antagonized by glyburide and tetrapropylammonium (TPrA) but not by tetraethlylammonium (TEA) or charybdotoxin (ChTX). The molecular basis of the observed hyperpolarization was studied in whole-cell, voltage-clamp experiments. Exposure of voltage-clamped cells to U83757 (300 nm to 300 m) produced a hyperpolarizing shift in the zero current potential; however, the hyperpolarizing shift in reversal potential was associated with either an increase or decrease in membrane conductance. In solutions where E _k=–82 mV and E _Cl=0 mV, the reversal potential of the U83757-sensitive current was approximately –70 mV in those experiments where an increase in membrane conductance was observed. In experiments in which a decrease in conductance was observed, the reversal potential of the U83757-sensitive current was approximately 0 mV, suggesting that U83757 might be acting as a Cl^– channel blocker as well as a K⁺ channel opener. In experiments in which Cl^– current activation was specifically brought about by cellular swelling and performed in solutions where Cl^– was the major permeant ion, U83757 (300 nm to 300 m) produced a dose-dependent current inhibition. Taken together these results (i) demonstrate the presence of a K⁺-selective current which is sensitive to K_ATP channel openers in A10 cells and (ii) indicate that the hyperpolarizing effects of K⁺ channel openers in vascular smooth muscle may be due to both the inhibition of Cl^– currents as well as the activation of a K⁺-selective current.This work was supported in part by the following grants: PHS P01 DK44840 and GM36823 (D.J.N.). J.C.M. is an Established Investigator of the American Heart Association.     

Novel actions of ryanodine and analogues—Perturbers of potassium channels

The effects of ryanodine, 9,21-didehydroryanodine and 9,21-didehydroryanodol on two types of K⁺ channel (a maxi, Ca²⁺-activated, 170 pS channel (BK channel) and an inward rectifier, stretch-sensitive channel of 35 pS conductance (IK channel) found in the plasma membrane of locust skeletal muscle have been investigated. 10^–9M-10^–5M ryanodine irreversibly induced a dose-dependent reduction of the reversal potential (V_rev) of the currents of both channels, i.e. from 60 mV in the absence of the alkaloid to 15 mV for 10^–5M ryanodine, measured under physiologically normal K⁺ and Na⁺ gradients. In both cases the change in the ionic selectivity was Ca²⁺-independent. 9,21-didehydroryanodine and 9,21-didehyroryanodol also reduced V_rev, but only to 35 mV during application of 10^–5M of these compounds. Additionally, 9,21-didehydroryanodine reversibly diminished the conductances of the two K⁺ channels. To test the hypothesis that ryanoids increase Na⁺ permeability by enlarging the K⁺ channels, the channels were probed with quaternary ammonium ions during ryanoid application. When applied to the cytoplasmic face of inside-out patches exised from locust muscle membrane, TEA blocked the K⁺ channels in a voltage-dependent fashion. The dissociation constant (K_d(0)) for TEA block of the IK channel was reduced from 44 mM to 1 mM by 10^–7 M ryanodine, but the voltage-dependence of the block was unaffected. Qualitatively similar data were obtained for the BK channel. Ryanodine had no effect on the K_d for cytoplasmically-applied TMA. However, the voltage-dependence for TMA block was increased for both K⁺ channels, from 0.47 to 0.8 with 10^–6M ryanodine. The effects of ryanodine on TEA and TMA block support the hypothesis that ryanodine enlarges the K⁺ channels so as to facilitate permeation of partially hydrated Na⁺ ions.     

Dynamics, Energetics, and Selectivity of the Low-K KcsA Channel Structure

Potassium channels are a diverse family of integral membrane proteins through which K⁺ can pass selectively. There is ongoing debate about the nature of conformational changes associated with the opening/closing and conductive/nonconductive states of potassium channels. The channels partly exert their function by varying their conductance through a mechanism known as C-type inactivation. Shortly after the activation of K⁺ channels, their selectivity filter stops conducting ions at a rate that depends on various stimuli. The molecular mechanism of C-type inactivation has not been fully understood yet. However, the X-ray structure of the KcsA channel obtained in the presence of low K⁺ concentration is thought to be representative of a K⁺ channel in the C-type inactivated state. Here, extensive, fully atomistic molecular dynamics and free-energy simulations of the low-K⁺ KcsA structure in an explicit lipid bilayer are performed to evaluate the stability of this structure and the selectivity of its binding sites. We find that the low-K⁺ KcsA structure is stable on the timescale of the molecular dynamics simulations performed, and that ions preferably remain in S1 and S4. In the absence of ions, the selectivity filter evolves toward an asymmetric architecture, as already observed in other computations of the high-K⁺ structure of KcsA and KirBac. The low-K⁺ KcsA structure is not permeable by Na⁺, K⁺, or Rb⁺, and the selectivity of its binding sites is different from that of the high-K⁺ structure.     

Cyanine dye fluorescence used to measure membrane potential changes due to the assembly of complement proteins C5b-9

Summary The fluorescent potentiometric indicator diS–C₃-(5) has been used to investigate changes in membrane potential due to assembly of the C5b-9 membrane attack complex of the complement system. EAC1-7 human red blood cells and resealed erythrocyte ghosts—bearing membrane-assembled C5b67 complexes—were generated by immune activation in C8-deficient human serum. Studies performed with these cellular intermediates revealed that the membrane potential of EAC1-7 red cells and ghosts is unchanged from control red cells (–7 mV) and ghosts (0 mV), respectively. Addition of complement proteins C8 and C9 to EAC1-7 red cells results in a dose-dependent depolarization of membrane potential which precedes hemolysis. This prelytic depolarization of membrane potential—and the consequent onset of hemolysis—is accelerated by raising external [K⁺], suggesting that the diffusional equilibration of transmembrane cation gradients is rate limiting to the cytolytic event. In the case of EAC1-7 resealed ghosts suspended at either high external [K⁺] or [Na⁺], no change in membrane potential (from 0 mV) could be detected after C8/C9 additions. When the membrane potential of the EAC1-7 ghost was displaced from 0 mV by selectively increasing the K⁺ conductance with valinomycin, a dose-dependent depolarization of the membrane was observed upon addition of C8 and C9. In these experiments, lytic breakdown of the ghost membranes was <5%. Conclusions derived from this study include: (i) measured prelytic depolarization of the red cell Donnan potential directly confirms the colloid-osmotic theory of immune cytolysis. (ii) The diffusional transmenbrane equilibration of Na⁺ and K⁺ through the C5b-9 pore results in a dose-dependent depolarization of the membrane potential (E _m ) which appears to be rate-limiting to cytolytic rupture of the target erythrocyte. (iii) Enhanced immune hemolysis observed in high K⁺ media cannot be attributed to cation-selective conductance across the C5b-9 pore, and is probably related to the nearequilibrium condition of potassium-containing red cells when suspended at high external K⁺. These experiments demonstrate that carbocyanine dye fluorescent indicators can be used to monitor electrochemical changes arising from immune damage to the plasma membrane under both cytolytic and noncytolytic conditions. Potential application of this method to the detection of sublytic pathophysiological changes in the plasma membrane of complement-damaged cells are discussed.     

The effect of surface charge density on valinomycin-K+ complex formation in model membranes

The model membrane approach was used to investigate the surface charge effect on the ion-antibiotic complexation process. Mixed monolayers of valinomycin and lipids were spread on subphases containing K⁺ or Na⁺. The surface charge density was modified by spreading ionizable valinomycin analogs on aqueous subphases of different pH or by changing the nature of the lipid (neutral, negatively charged) in the mixed film. Surface pressure and surface potential measurements demonstrated that a neutral lipid (phosphatidylcholine) or positively charged valinomycin analogs didn't enhance the antibiotic complexing capacity. However, a maximal complexation is reached for a critical lipid concentration in the valinomycin-phosphatidylserine mixed film. The role of the surface charge on the valinomycin complexing properties was examined in terms of the Gouy-Chapman theory. As a consequence of the negative charge of the lipid monolayer, the K⁺ concentration near the surface is larger than the bulk concentration, by a Boltzmann factor. A good agreement was observed between the experimental results and the theoretical predictions. Conductance measurements of asymmetric bilayers containing a neutral lipid (egg lecithin) on one side and a negatively charged lipid (phosphatidylserine) on the other, confirm the role of the surface charge. Indeed, addition of K⁺ to the neutral side of the bilayer containing valinomycin had no effect on the conductance whereas addition of K⁺ to the charged side of the bilayer caused a 80-fold conductance increase.     

Current-voltage relationships of a sodium-sensitive potassium channel in the tonoplast ofChara corallina

Summary The membrane of mechanically prepared vesicles ofChara corallina has been investigated by patch-clamp techniques. This membrane consists of tonoplast as demonstrated by the measurement of ATP-driven currents directed into the vesicles as well as by the ATP-dependent accumulation of neutral red. Addition of 1mm ATP to the bath medium induced a membrane current of about 3.2 mA·m^–2 creating a voltage across the tonoplast of about –7 mV (cytoplasmic side negative). On excised tonoplast patches, currents through single K⁺-selective channels have been investigated under various ionic conditions. The open-channel currents saturate at large voltage displacements from the equilibrium voltage for K⁺ with limiting currents of about +15 and –30 pA, respectively, as measured in symmetric 250mm KCl solutions. The channel is virtually impermeable to Na⁺ and Cl^–. However, addition of Na⁺ decreases the K⁺ currents. TheI–V relationships of the open channel as measured at various K⁺ concentrations with or without Na⁺ added are described by a 6-state model, the 12 parameters of which are determined to fit the experimental data.     

Selectivity of the Ca2+-activated and Light-dependent K+ Channels for Monovalent Cations

The ionic selectivity of the Ca²⁺-activated K⁺ channel of Aplysia neurons and of the light-dependent K⁺ channel of Pecten photoreceptors to metal and organic cations was studied. The selectivity sequence determined from reversal potential measurements is T1⁺ K⁺ > Rb⁺ > NH⁺₄ > Cs⁺ > Na⁺, Li⁺ and is identical to the sequence determined previously for voltage-dependent K⁺ channels in a variety of tissues. Our results suggest that some physical aspect of the K⁺ channel is conserved in phyllogenetically different tissues and cells.     

Satellite glial cells In Situ within mammalian prevertebral ganglia express K+ channels active at rest potential

Patch-clamp experiments were performed on satellite glial cells wrapped around sympathetic neurons in the rabbit coeliac ganglion. With the cleaning method used, the glial cells could be kept in place and were directly accessible to the patch-clamp pipettes. Whole-cell recordings showed that glial cells had almost ohmic properties. Their resting potential (–79.1±1.2 mV) was found to be very nearly the same as the K⁺ reversal potential and 20 mV more negative than that of the neurons they encapsulated. Unitary currents from ionic channels present in the glial membrane were recorded in the cell-attached configuration with pipettes filled with various amounts of K⁺, Na⁺ and gluconate. Only K⁺-selective channels with slight inwardly rectifying properties (in the presence of 150 mM [K⁺]₀) were detected. These channels were active (P ₀=0.7–0.8) at the cell resting potential. The channel conductance, but not its opening probability, was dependent on the [K⁺] in the pipette. Cl^–-selective channels (outwardly rectifying and large conductance channels) were detected in excised patches.The properties of the K⁺ channels (increased inward current with [K⁺] and detectable outward current at low [K⁺]) are well suited for siphoning the K⁺ released by active neurons.     

Calcium-independent K+-selective channel from chromaffin granule membranes

Summary Intact adrenal chromaffin granules and purified granule membrane ghosts were allowed to fuse with acidic phospholipid planar bilayer membranes in the presence of Ca²⁺ (1 mm). From both preparations, we were able to detect a large conductance potassium channel (ca. 160 pS in symmetrical 400 mm K⁺), which was highly selective for K⁺ over Na⁺ (P _k/P _Na = 11) as estimated from the reversal potential of the channel current. Channel activity was unaffected by charybdotoxin, a blocker of the [Ca²⁺] activated K⁺ channel of large conductance. Furthermore, this channel proved quite different from the previously described channels from other types of secretory vesicle preparations, not only in its selectivity and conductance, but also in its insensitivity to both calcium and potential across the bilayer. We conclude that the chromaffin granule membrane contains a K⁺-selective channel with large conductance. We suggest that the role of this channel may include ion movement during granule assembly or recycling, and do not rule out events leading to exocytosis.     

Altered ion channel conductance and ionic selectivity induced by large imposed membrane potential pulse.

The effects of large magnitude transmembrane potential pulses on voltage-gated Na and K channel behavior in frog skeletal muscle membrane were studied using a modified double vaseline-gap voltage clamp. The effects of electroconformational damage to ionic channels were separated from damage to lipid bilayer (electroporation). A 4 ms transmembrane potential pulse of -600 mV resulted in a reduction of both Na and K channel conductivities. The supraphysiologic pulses also reduced ionic selectivity of the K channels against Na+ ions, resulting in a depolarization of the membrane resting potential. However, TTX and TEA binding effects were unaltered. The kinetics of spontaneous reversal of the electroconformational damage of channel proteins was found to be dependent on the magnitude of imposed membrane potential pulse. These results suggest that muscle and nerve dysfunction after electrical shock may be in part caused by electroconformational damage to voltage-gated ion channels.     

Ion Permeabilities in Mouse Sperm Reveal an External Trigger for SLO3-Dependent Hyperpolarization

Unlike most cells of the body which function in an ionic environment controlled within narrow limits, spermatozoa must function in a less controlled external environment. In order to better understand how sperm control their membrane potential in different ionic conditions, we measured mouse sperm membrane potentials under a variety of conditions and at different external K⁺ concentrations, both before and after capacitation. Experiments were undertaken using both wild-type, and mutant mouse sperm from the knock-out strain of the sperm-specific, pH-sensitive, SLO3 K⁺ channel. Membrane voltage data were fit to the Goldman-Hodgkin-Katz equation. Our study revealed a significant membrane permeability to both K⁺ and Cl⁻ before capacitation, as well as Na⁺. The permeability to both K⁺ and Cl⁻ has the effect of preventing large changes in membrane potential when the extracellular concentration of either ion is changed. Such a mechanism may protect against undesired shifts in membrane potential in changing ionic environments. We found that a significant portion of resting membrane potassium permeability in wild-type sperm was contributed by SLO3 K⁺ channels. We also found that further activation of SLO3 channels was the essential mechanism producing membrane hyperpolarization under two separate conditions, 1) elevation of external pH prior to capacitation and 2) capacitating conditions. Both conditions produced a significant membrane hyperpolarization in wild-type which was absent in SLO3 mutant sperm. Hyperpolarization in both conditions may result from activation of SLO3 channels by raising intracellular pH; however, demonstrating that SLO3-dependent hyperpolarization is achieved by an alkaline environment alone shows that SLO3 channel activation might occur independently of other events associated with capacitation. For example sperm may undergo stages of membrane hyperpolarization when reaching alkaline regions of the female genital tract. Significantly, other events associated with sperm capacitation, occur in SLO3 mutant sperm and thus proceed independently of hyperpolarization.     

Single-Channel Analysis of a Delayed Rectifier K+ Channel in Xenopus Myelinated Nerve

Single-channel properties of a delayed rectifier voltage-gated K⁺ channel (I-type) were investigated in peripheral myelinated axons from Xenopus laevis. Channels activated between −60 and −40 mV with a potential of half-maximal activation, E₅₀, at −47.5 mV. Averaged single-channel currents activated with a time delay at all membrane potentials tested. Time to half-maximal activation decreased from 80 to 1.6 msec between −60 and +40 mV. The channel inactivated monoexponentially with a time constant of 10.9 sec at −40 mV. The time constant of deactivation was 126 msec at −80 mV and 16.9 msec at −110 mV. In symmetrical 105 mm K⁺, the single-channel conductance (γ) was 22 and 13 pS at negative and positive membrane potentials, respectively, at 13–15°C. In Na⁺-rich solution with 2.5 mm extracellular K⁺γ was 7 pS and the reversal potential was negative to −80 mV, indicating a high selectivity for K⁺ over Na⁺. γ depended on extracellular K⁺ concentration (K _D = 19.6 mm) and temperature (Q ₁₀= 1.45). External tetraethylammonium (TEA) reduced the apparent single-channel current amplitude at all potentials tested with a half-maximal inhibiting concentration (IC₅₀) of 0.6 mm. Open probability of the channel, but not single-channel current amplitude was decreased by extracellular dendrotoxin (DTX, IC₅₀= 6.8 nm) and mast cell degranulating peptide (MCDP, IC₅₀= 41.9 nm). In Ringer solution the membrane potential of macroscopic I-channel patches was about −65 mV and depolarized under TEA and DTX. It is concluded that besides their activation during action potentials, I-channels may also stabilize the resting membrane potential. Received: 2 June 1995/Revised: 13 October 1995