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.     

Lipid surface charge does not influence conductance or calcium block of single sodium channels in planar bilayers.

We have studied the effects of membrane surface charge on Na+ ion permeation and Ca2+ block in single, batrachotoxin-activated Na channels from rat brain, incorporated into planar lipid bilayers. In phospholipid membranes with no net charge (phosphatidylethanolamine, PE), at low divalent cation concentrations (approximately 100 microM Mg2+), the single channel current-voltage relation was linear and the single channel conductance saturated with increasing [Na+] and ionic strength, reaching a maximum (gamma max) of 31.8 pS, with an apparent dissociation constant (K0.5) of 40.5 mM. The data could be approximated by a rectangular hyperbola. In negatively charged bilayers (70% phosphatidylserine, PS; 30% PE) slightly larger conductances were observed at each concentration, but the hyperbolic form of the conductance-concentration relation was retained (gamma max = 32.9 pS and K0.5 = 31.5 mM) without any preferential increase in conductance at lower ionic strengths. Symmetrical application of Ca2+ caused a voltage-dependent block of the single channel current, with the block being greater at negative potentials. For any given voltage and [Na+] this block was identical in neutral and negatively charged membranes. These observations suggest that both the conduction pathway and the site(s) of Ca2+ block of the rat brain Na channel protein are electrostatically isolated from the negatively charged headgroups on the membrane lipids.     

Single-channel currents from acetylcholine receptors in embryonic chick muscle. Kinetic and conductance properties of gaps within bursts

In tissue-cultured chick muscle, bursts of current from single nicotinic ion channels contain a variety of low-conductance gaps. One population has a lifetime of approximately 0.1 ms and an unknown conductance. A second population has a lifetime of 2-10 ms and conductance of zero. The third population has a lifetime of 0.5-1 ms and a mean conductance approximately 2% that of the main conductance state. This subconductance state has an agonist-dependent lifetime, longer for suberyldicholine than for acetylcholine, and is liganded to the same extent as the main conductance state. Subconductance gaps have a linear current-voltage behavior in the range -60 to -140 mV and appear to have the same reversal potential as the main state. The subconductance state is composed of a group of states which interconvert with correlation times longer than 300 microseconds.     

Insulation of the conduction pathway of muscle transverse tubule calcium channels from the surface charge of bilayer phospholipid

Functional calcium channels present in purified skeletal muscle transverse tubules were inserted into planar phospholipid bilayers composed of the neutral lipid phosphatidylethanolamine (PE), the negatively charged lipid phosphatidylserine (PS), and mixtures of both. The lengthening of the mean open time and stabilization of single channel fluctuations under constant holding potentials was accomplished by the use of the agonist Bay K8644. It was found that the barium current carried through the channel saturates as a function of the BaCl2 concentration at a maximum current of 0.6 pA (at a holding potential of 0 mV) and a half-saturation value of 40 mM. Under saturation, the slope conductance of the channel is 20 pS at voltages more negative than -50 mV and 13 pS at a holding potential of 0 mV. At barium concentrations above and below the half-saturation point, the open channel currents were independent of the bilayer mole fraction of PS from XPS = 0 (pure PE) to XPS = 1.0 (pure PS). It is shown that in the absence of barium, the calcium channel transports sodium or potassium ions (P Na/PK = 1.4) at saturating rates higher than those for barium alone. The sodium conductance in pure PE bilayers saturates as a function of NaCl concentration, following a curve that can be described as a rectangular hyperbola with a half-saturation value of 200 mM and a maximum conductance of 68 pS (slope conductance at a holding potential of 0 mV). In pure PS bilayers, the sodium conductance is about twice that measured in PE at concentrations below 100 mM NaCl. The maximum channel conductance at high ionic strength is unaffected by the lipid charge. This effect at low ionic strength was analyzed according to J. Bell and C. Miller (1984. Biophysical Journal. 45:279-287) and interpreted as if the conduction pathway of the calcium channel were separated from the bilayer lipid by approximately 20 A. This distance thereby effectively insulates the ion entry to the channel from the bulk of the bilayer lipid surface charge. Current vs. voltage curves measured in NaCl in pure PE and pure PS show that similarly small surface charge effects are present in both inward and outward currents. This suggests that the same conduction insulation is present at both ends of the calcium channel.     

Membrane phospholipid composition affects function of potassium channels from rabbit colon epithelium

We tested the effects of membrane phospholipids on the functionof high-conductance,Ca²⁺-activatedK⁺ channels from the basolateralcell membrane of rabbit distal colon epithelium by reconstituting thesechannels into planar bilayers consisting of different 1:1 mixtures ofphosphatidylethanolamine (PE), phosphatidylcholine (PC),phosphatidylserine (PS), and phosphatidylinositol (PI). At low ambientK⁺ concentrations single-channelconductance is higher in PE/PS and PE/PI bilayers than in PE/PCbilayers. At high K⁺concentrations this difference in channel conductance is abolished. Introducing the negatively charged SDS into PE/PC bilayersincreases channel conductance, whereas the positively chargeddodecyltrimethylammonium has the opposite effect. All these findingsare consistent with modulation of channel current by the charge of thelipid membrane surrounding the channel. But theK⁺ that permeates the channelsenses only a small fraction of the full membrane surface potential ofthe charged phospholipid bilayers, equivalent to separation of theconduction pathway from the charged phospholipid head groups by 20 Å. This distance appears to insulate the channel entrancefrom the bilayer surface potential, suggesting large dimensions of thechannel-forming protein. In addition, in PE/PC and PE/PI bilayers, butnot in PE/PS bilayers, the open-state probability of the channeldecreases with time ("channel rundown"), indicating thatphospholipid properties other than surface charge are required tomaintain channel fluctuations.

     

Noise analysis of the glutamate-activated current in photoreceptors.

The glutamate-activated current in photoreceptors has been attributed both to a sodium/glutamate transporter and to a glutamate-activated chloride channel. We have further studied the glutamate-activated current in single, isolated photoreceptors from the tiger salamander using noise analysis on whole-cell patch-clamp recordings. In cones, the current is generated by chloride channels with a single-channel conductance of 0.7 pS and an open lifetime of 2.4 ms. The number of channels per cell is in the range of 10,000-20,000. Activation of the channels requires the presence of both glutamate and sodium. The single-channel conductance and the open lifetime of the channel are independent of the external concentration of glutamate and sodium. External glutamate and sodium affect only the opening rate of the channels. D,L-Threo-3-hydroxyaspartate (THA), a glutamate-transport blocker, is shown to be a partial agonist for the channel. The single-channel conductance is the same regardless of whether glutamate or THA is the ligand, but the open lifetime of the channel is only 0.8 ms with THA as ligand. The glutamate-activated current in rods has a similar single-channel conductance (0.74 pS) and open lifetime (3 ms). We propose a kinetic model, consistent with these results, to explain how a transporter can simultaneously act both as a sodium/glutamate-gated chloride channel and a glutamate/sodium cotransporter.     

Correlation analysis of electrical noise in lipid bilayer membranes: kinetics of gramicidin A channels.

If a membrane contains ion-conducting channels which form and disappear in a random fashion, an electric current which is passed through the membrane under constant voltage shows statistical fluctuations. Information on the kinetics of channel formation and on the conductance of the single channel may be obtained by analyzing the electrical noise generated in a membrane containing a great number of channels. For this purpose the autocorrelation function of the current noise is measured at different concentrations of the channel-forming substance. As a test system for the application of this technique we have used lipid bilayer membranes doped with gramicidin A. From the correlation time of the current noise generated by the membrane, the rate constants of formation (k-R) and dissociation (k-D) of the channels could be determined. In addition, the mean square of the current fluctuations yielded the single-channel conductance lambda. The values of k-R, k-D, and lambda obtained from the noise analysis agreed closely with the values determined by relaxation measurments and single-channel experiments.     

Activation of the M2 ion channel of influenza virus: a role for the transmembrane domain histidine residue.

To test the hypothesis that transmembrane domain histidine residue 37 of the M2 ion channel of influenza A virus mediates the low pH-induced activation of the channel, the residue was changed to glycine, glutamate, arginine, or lysine. The wild-type and altered M2 proteins were expressed in oocytes of Xenopus laevis and membrane currents were recorded. The mass of protein expressed in individual oocytes was measured using quantitative immunoblotting and correlated with membrane currents. Oocytes expressing the M2-H37G protein had a voltage-independent conductance with current-voltage relationship similar to that of the wild-type M2 channel. The conductance of the M2-H37G protein was reversibly inhibited by the M2 ion channel blocker amantadine and was only very slightly modulated by changes in pHout over the range pH 5.4 to pH 8.2. Oocytes expressing the M2-H37E protein also had a voltage-independent conductance with a current-voltage relationship similar to that of the wild-type M2 channel. The conductance of the M2-H37E protein was reversibly inhibited by amantadine and was also only very slightly modulated by changes in pHout over the range pH 5.4 to pH 8.2. These slight alterations in conductance of the mutant ion channels on changes in pHout are in striking contrast to the 50-fold change in conductance seen for the wild-type M2 channel over the range pH 4.5 to pH 8.2. The specific activity of the M2-H37G protein was 1.36 +/- 0.37 microA/ng and the specific activity of the M2-H37E protein was 30 +/- 3 microA/ng at pH 6.2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Inhibition of gramicidin channel activity by local anesthetics.

Ondrias et al. ((1986) Stud. Biophys. 115, 17-22) found that dibucaine, butacaine, and tetracaine reduce the conductance of membranes containing multiple (greater than 10(6)) gramicidin channels. Similar experiments with local anesthetics (LA's) added to the bath while gently stirring showed that the inhibition developed slowly over a time course of 5-10 min. We developed a many (10-20) channel membrane technique which demonstrated that when LA's were added to the bath and the membrane was repeatedly broken and reformed, the channel occurrence frequency declined promptly. In standard single-channel membrane experiments at lower gramicidin densities, the mean single channel conductance and lifetime distributions with LA's present in the bath did not differ from the controls. The predominant channel conductance amplitude was lower by 9.1% than those of controls, but channel amplitude distributions were also modified so that the net reduction in overall population channel conductance was only about 2.0%. Channel currents showed no evidence of flicker blocks. The lifetime histograms of control and LA-exposed channel populations were both satisfactorily fit by a single-exponential function with the same mean. Thus, inhibition is due primarily to a reduction in the frequency of occurrence of conducting channels, implying a reduced concentration of active monomers in the membrane.     

The potassium current activated by 2-nicotinamidoethyl nitrate (nicorandil) in single ventricular cells of guinea pigs

Membrane currents through potassium channels activated by nicorandil, which has a potent coronary vasodilating action, have been studied in ventricular cells of guinea pigs by using the single pipette whole-cell clamp technique. In the presence of 0.1 mM nicorandil, the duration of the action potential was shortened from 196 to 145 ms. Nicorandil markedly increased outward currents at potentials positive to the resting potential. When the difference in the currents before and after the application of nicorandil were plotted against the membrane potential, the current-voltage relation reversed close to the potassium equilibrium potential. The difference current during depolarizing pulses showed no time-dependent relaxation. These results indicate that the current evoked by nicorandil is carried by K+ ions and has voltage-independent kinetics. Power-density spectra obtained in the presence of nicorandil were fitted well by a single Lorentzian curve with a corner frequency of 4.4 Hz. The amplitude of the single-channel unit current was estimated from the relation between the variance and the mean current, and was 0.27 +/- 0.1 pA (n = 7) at -35 mV. The estimated slope conductance was 4.6 +/- 1.7 pS. Nicorandil did not affect Ca2+ currents. It is concluded that nicorandil activates a small-conductance K+ channel without affecting the Ca2+ channel.     

Transmembrane peptide NB of influenza B: a simulation, structure, and conductance study

The putative transmembrane segment of the ion channel forming peptide NB from influenza B was synthesized by standard solid-phase peptide synthesis. Insertion into the planar lipid bilayer revealed ion channel activity with conductance levels of 20, 61, 107, and 142 pS in a 0.5 M KCl buffer solution. In addition, levels at -100 mV show conductances of 251 and 413 pS. A linear current-voltage relation reveals a voltage-independent channel formation. In methanol and in vesicles the peptide appears to adopt an alpha-helical-like structure. Computational models of alpha-helix bundles using N = 4, 5, and 6 NB peptides per bundle revealed water-filled pores after 1 ns of MD simulation in a solvated lipid bilayer. Calculated conductance values [using HOLE (Smart et al. (1997) Biophys. J. 72, 1109-1126)] of ca. 20, 60, and 90 pS, respectively, suggested that the multiple conductance levels seen experimentally must correspond to different degrees of oligomerization of the peptide to form channels.     

Helical alpha-synuclein forms highly conductive ion channels

Alpha-synuclein (alphaS) is a cytosolic protein involved in the etiology of Parkinson's disease (PD). Disordered in an aqueous environment, alphaS develops a highly helical conformation when bound to membranes having a negatively charged surface and a large curvature. It exhibits a membrane-permeabilizing activity that has been attributed to oligomeric protofibrillar forms. In this study, monomeric wild-type alphaS and two mutants associated with familial PD, E46K and A53T, formed ion channels with well-defined conductance states in membranes containing 25-50% anionic lipid and 50% phosphatidylethanolamine (PE) in the presence of a trans-negative potential. Another familial mutant, A30P, known to have a lower membrane affinity, did not form ion channels. Ca2+ prevented channel formation when added to membranes before alphaS and decreased channel conductance when added to preformed channels. In contrast to the monomer, membrane permeabilization by oligomeric alphaS was not characterized by formation of discrete channels, a requirement for PE lipid, or a membrane potential. Channel activity, alpha-helical content, thermal stability of membrane-bound alphaS determined by far-UV CD, and lateral mobility of alphaS bound to planar membranes measured by fluorescence correlation spectroscopy were correlated. It was inferred that discrete ion channels with well-defined conductance states were formed in the presence of a membrane potential by one or several molecules of monomeric alphaS in an alpha-helical conformation and that such channels may have a role in the normal function and/or pathophysiology of the protein.     

Single potassium channels in membranes of isolated mesophyll barley vacuoles

Summary Voltage-dependent K channels could be identified in on-cell and excised patch-clamp records on membranes of isolated plant cell vacuoles. The current through a membrane patch is dominated by a channel population with a conductance of about 121 pS in symmetrical 250mm KCl solution. The single channel adopts at least two conducting levels the 121-pS state being most frequently observed. The channel shows outward rectification, representing a cation flux into the vacuoles. The rectification appears to be caused by a vanishing open probability and a short channel lifetime at hyperpolarizing voltages. A selectivity ratio of potassium over sodium of about 6 was derived as an estimate. Occasionally, an additional population of K channels with a single-channel conductance of approximately 18 pS is observed. This channel type exhibits outward rectification as well.     

Reaction of tetraethylammonium with the open and closed conformations of the acetylcholine receptor ionic channel complex

The effect of tetraethylammonium (TEA) bromide on the neurally and iontophoretically evoked endplate current (EPC) of frog sartorius muscle was investigated using voltage-clamp and noise analysis techniques, and its binding to the acetylcholine (ACh) receptor ionic channel complex was determined on the electric organ of Torpedo ocellata. TEA (250-500 microM) produced an initial enhancement followed by a slow decline in the amplitude of the endplate potential and EPC, but caused only depression in the amplitude of the miniature endplate potential and current. In normal ringer's solution, the EPC current-voltage relationship was approximately linear, and the decay phase varied exponentially with membrane potential. Upon addition of 50-100 microM TEA, the current-voltage relationship became markedly nonlinear at hyperpolarized command potentials, and with 250-2000 microM TEA, there was an initial linear segment, an intermediate nonlinear segment, and a region of negative conductance. The onset of nonlinearity was dose-dependent, undergoing a 50 mV shift for a 10-fold increase in TEA concentration. The EPC decay phase was shortened by TEA at hyperpolarized but not depolarized potentials, and remained a single expotential function of time at all concentrations and membrane potentials examined. These actions of TEA were found to be independent of the sequence of polarizations, the length of the conditioning pulse, and the level of the initial holding potential. TEA shifted the power spectrum of ACh noise to higher frequencies and produced a significant depression of single channel conductance. The shortening in the mean channel lifetime agreed closely with the decrease in the EPC decay time constant. At the concentrations tested, TEA did not alter the EPC reversal potential, nor the resting membrane potential, and had little effect on the action potential duration. TEA inhibited the binding of both [3H] ACh (Ki = 200 microM) and [3H]perhydrohistrionicotoxin (Ki = 280 microM) to receptor-rich membranes from the electric organ of Torpedo ocellata, and inhibited the carbamylcholine-activated 22Na+ efflux from these microsacs. It is suggested that TEA reacts with the nicotinic ACh-receptor as well as its ion channel; the voltage-dependent actions are associated with blockade of the ion channel. The results are compatible with a kinetic model in which TEA first binds to the closed conformation of the receptor-ionicchannel complex to produce a voltage-depdndent depression of endplate conductance and sudsequently to its open conformation, giving rise to the shortening in the EPC decay and mean channel lifetime.     

Conductance noise of monazomycin-doped bilayer membranes

Summary The conductance noise of the monazomycin pore has been studied by autocorrelation analysis in multi-pore systems. The autocorrelation function could be described by a superposition of two single exponential functions of different time- and voltage-dependence. The slow voltage-dependent correlation time in the range of seconds is assigned to the formation of nonconducting pore precursors. The fast voltage-independent correlation time in the msec range is related to fluctuations in the number of open pores whereby each pore adopts only two conducting states (open and closed). The corresponding correlation amplitude depends on monazomycin concentration and could be related to the single pore conductance. With increasing voltage, a slight increase of the single pore conductance was obtained which is explained on the basis of an electrostatic barrier within the pore. The pore was found to be virtually unselective for different alkali ions (Li, K, Cs).     

Relation between gramicidin D and valinomycin-induced conductivity of lipid bilayer and cholesterol levels

Kinetics of conductance and current-voltage characteristics (VACH) were studied on the bilayer lipid membranes from egg lecithin and cholesterol modified by gramicidin D and valinomycin. There were found significant changes of ionic channels conductance g, lifetime tau and non-linearity coefficient beta of VACH of modified membranes dependent on cholesterol content. In the region of high cholesterol concentrations, more than 20 mol%, there were observed abrupt changes of the ionic channels parameters: tau increased more than ten times, conductance decreased two times and beta greater than 0 in the whole region of electrolyte concentration.     

Mature and immature synaptosomal membranes have a different lipid composition

Subfractionation of the optic tectum in chick embryos results in the isolation of two fractions enriched in synaptosomes (fraction A and fraction B). In chicks after hatching, this fractionation results in the isolation of a single synaptosomal fraction (fraction B) and of a fraction enriched in myelin membranes devoid of synaptosomes (fraction A). The lipid composition of synaptosomal fractions (A and B) and corresponding synaptosomal plasma membranes has been analyzed and compared to the lipid composition of similar fractions isolated from 2–3 day-old chicks. The phospholipid composition of fraction A in embryos was mainly represented by phosphatidylcholine (PC) and phosphatidylethanolamine (PE). The PE content was significantly lower than that of PC, which accounted for by approximately 50%. Sphingomyelin (SP) and phosphatidylinositol (PI) accounted for by only 6% of the total membrane phopsholipids. Fraction A isolated from the young chicks showed many significant changes. PC accounted for by approximately 40% and PE made up 35%. The amount of phosphatidylserine (PS) and SP increased. These data parallel our previous morphological observations, which showed that fraction A contains immature synaptosomes in embryos but myelin membranes and no synaptosomes in the young chicks. Fraction B has been shown to contain synaptosomes at all stages considered. It possessed in embryos a lipid composition similar to fraction A, except that PC content was higher in young embryos. The analyses on membrane fractions confirmed these results. On the contrary, this fraction showed many significant changes after hatching. The content of PC was significantly reduced, PE/PC ratio was significantly increased as well as ethanolamine plasmalogen (PLE) content. The percentage of PS, PI and SP were increased. The composition of fatty acids of the total fraction of phospholipids was also examined. The results parallel the observations on phospholipid classes.     

Electrical properties and molecular architecture of the channel formed by Escherichia coli hemolysin in planar lipid membranes

A 107 kDa hemolysin from Escherichia coli is able to open pores in lipid membranes. By studying its interaction with planar phospholipid bilayers we have derived some structural information on the organization of the pore. We measured the current-voltage characteristic and the ion selectivity of the channel both in neutral membranes, made of egg phosphatidylcholine (PC) and in negatively charged membranes, made of a 1:1 mixture of PC with phosphatidylserine (PS). Experiments were performed varying both the pH and the salt concentration of the bathing KCl solution. In neutral membranes the pore is ohmic and its conductance increases almost linearly with the salt concentration. The channel is cation-selective at high pH but nearly unselective at low pH. We interpret these results in terms of a minimal model based on classical electro-diffusional theories assuming that the pore is wide and bears a negative charge at its entrances. In membranes containing the acidic lipid the current-voltage curve is non-linear in such a way to suggest that the trans (but not the cis) entrance of the pore is affected by the surface potential of the membrane. Applying our model we find that the trans and cis entrances are located, respectively, about 0.5 nm and more than 5 nm apart from the plane of the membrane. We confirmed the asymmetric disposition of the channel by enzymatic digestion of preformed pores. This was effective only when the enzyme was applied on the cis side.     

Antibacterial peptide pleurocidin forms ion channels in planar lipid bilayers

Pleurocidin, a 25-residue alpha helical cationic peptide, isolated from skin mucous secretions of the winter flounder, displays a strong anti-microbial activity and appears to play a role in innate host defence. This peptide would be responsible for pore formation in the membrane of bacteria leading to lysis and therefore death. In this study, we investigated the behaviour of pleurocidin in different planar lipid bilayers to determine its mechanism of membrane permeabilisation. Macroscopic conductance experiments showed that pleurocidin did not display a pore-forming activity in neutral phosphatidylcholine/phosphatidylethanolamine (PC/PE) lipid bilayers. However, in 7:3:1 PC/PE/phosphatidylserine (PS) lipid bilayers, pleurocidin showed reproducible I/V curves at different peptide concentrations. This activity is confirmed by single-channel experiments since well-defined ion channels were obtained if the lipid mixture was containing an anionic lipid (PS). The ion channel characteristics such as-no voltage dependence, only one unitary conductance, linear relation ship current-voltage-, are not in favour of the membrane permeabilisation according to the barrel model but rather by the toroidal pore formation.     

Formamidinium-induced dimer stabilization and flicker block behavior in homo- and heterodimer channels formed by gramicidin A and N-acetyl gramicidin A.

Compared to the N-formyl gramicidin A (GA), the N-acetyl gramicidin A (NAG) channel has unchanged conductance in 1 M NH4+ (gamma NN/gamma GG = 1, conductance ratio) but reduced conductance in 1 M K+ (gamma NN/gamma GG = 0.6) methylammonium (gamma NN/gamma GG = 0.3), and formamidinium (gamma NN/gamma GG = 0.1) solutions. Except with formamidinium, "flicker blocks" are evident even at low cutoff frequencies. For all cations studied, channel lifetimes of N-acetyl homodimers (NN) are approximately 50-fold shorter than those of the GA homodimer (GG). The novel properties of GA channels in formamidinium solution (supralinear current-voltage relations and dimer stabilization (Seoh and Busath, 1993)) also appear in NN channels. The average single channel lifetime in 1 M formamidinium solution at 100 mV is 6-7-fold longer than in K+ and methylammonium solutions and, like in the GA channel, significantly decreases with increasing membrane potential. Experiments with mixtures of the two peptides, GA and NAG, showed three main conductance peaks. Oriented hybrids were formed utilizing the principle that monomers remain in one leaflet of the bilayer (O'Connell et al., 1990). With GA at the polarized side and NAG at the grounded side, at positive potentials (in which case hybrids were designated GN) and at negative potentials (in which case hybrids were designated NG), channels had the same conductances and channel properties at all potentials studied. Flicker blocks were not evident in the hybrid channels, which suggests that both N-acetyl methyl groups at the junction of the dimer are required to cause flickers. Channel lifetimes in hybrids are only approximately threefold shorter than those of the GG channels, and channel conductances are similar to those of GG rather than NN channels. We suggest that acetyl-acetyl crowding at the dimeric junction in NN channels cause dimer destabilization, flickers, and increased selectivity in N-acetyl gramicidin channels.