Toad bladder amiloride-sensitive channels reconstituted into planar lipid bilayers

In the present study we used established methods to obtain apical membrane vesicles from the toad urinary bladder and incorporated these membrane fragments to solvent-free planar lipid bilayer membranes. This resulted in the appearance of a macroscopic conductance highly sensitive to the diuretic amiloride added to the cis side. The blockage is voltage dependent and well described by a model which assumes that the drug binds to sites in the channel lumen. This binding site is localized at about 15% of the electric field across the membrane. The apparent inhibition constant (K(0)) is equal to 0.98 microM. Ca2+, in the micromolar range on the cis side, is a potent blocker of this conductance. The effect of the divalent has a complex voltage dependence and is modulated by pH. At the unitary level we have found two distinct amiloride-blockable channels with conductances of 160 pS (more frequent) and 120 pS. In the absence of the drug the mean open time is around 0.5 sec for both channels and is not dependent on voltage. The channels are cation selective (PNa/PCl = 15) and poorly discriminate between Na+ and K+ (PNa/PK = 2). Amiloride decreases the lifetime in the open state of both channels and also the conductance of the 160-pS channel.     

Potassium channels from the plasma membrane of rye roots characterized following incorporation into planar lipid bilayers

Plasma membrane was purified from roots of rye (Secale cereale L. cv. Rheidol) by aqueous-polymer two-phase partitioning and incorporated into planar bilayers of 1-palmitoyl-2-oleoyl phosphatidylethanolamine by stirring with an osmotic gradient. Since plasmamembrane vesicles were predominantly oriented with their cytoplasmic face internal, when fused to the bilayer the cytoplasmic side of channels faced the trans chamber. In asymmetrical (cis:trans) 280100 mM KCl, five distinct K⁺-selective channels were detected with mean chord-conductances (between +30 and -30 mV; volyages cis with respect to trans) of 500 pS, 194 pS, 49 pS, 21 pS and 10 pS. The frequencies of incorporation of these K⁺ channels into the bilayer were 48, 21, 50, 10 and 9%, in the order given (data from 159 bilayers). Only the 49 pS channel was characterized further in this paper, but the remarkable diversity of K⁺ channels found in this preparation is noteworthy and is the subject of further study. In symmetrical KCl solutions, the 49 pS channel exhibited non-ohmic unitary-current/voltage relationships. The chord-conductance (between +30 and-30 mV) of the channel in symmetrical 100 mM KCl was 39 pS. The unitary current was greater at positive voltages than at corresponding negative voltages and showed considerable rectification with increasing positive and negative voltages. This would represent inward rectification in vivo. Gating of the channel was not voltage-dependent and the channel was open for approx. 80% of the time. Presumably this is not the case in vivo, but we are at present uncertain of the in vivo controls of channel gating. The distribution of channel-open times could be approximated by the sum of two negative exponential functions, yielding two open-state time constants (_o, the apparent mean lifetime of the channel-open state) of 1.0 ms and 5.7 s. The distribution of channel-closed times was best approximated by the sum of three negative exponential functions, yielding time constants (_c, the apparent mean lifetime of the channel-closed state) of 1.1 ms, 51 ms and 11 s. This indicates at least a five-state kinetic model for the activity of the channel. The selectivity of the 49 pS channel, determined from both reversal potentials under biionic conditions (100 mM KCl100 mM cation chloride) and from conductance measurements in symmetrical 100 mM cation chloride, was Rb⁺ K⁺ > Cs⁺ > Na⁺ > Li⁺ > tetraethylammonium (TEA⁺). The 49 pS channel was reversibly inhibited by quinine (1 mM) but TEA⁺ (10 mM), Ba²⁺ (3 mM), Ca²⁺ (1 mM), 4-aminopyridine (1 mM) and charybdotoxin (3 M) were without effect when applied to the extracellular (cis) surface.Abbreviations and Symbols GHK Goldman-Hodgkin-Katz - I/V current/voltage - PEG polyethyleneglycol - P_o probability o f the channel being open - TEA⁺ tetraethylammonium - _c apparent mean lifetime of the channel-closed state - _o apparent mean lifetime of the channel-open state P.J.W. was supported by a grant from the Science and Engineering Research Council Membrane Initiative (GR/F 33971) to Professor E.A.C. MacRobbie and M.T. by the Glaxo Junior Research Fellowship at Churchill College, Cambridge. We thank Dr. D.T. Cooke (AFRC, Long Ashton Research Station, University of Bristol, UK) and Ms. J. Marshall (University of York, UK) for their advice and assistance with the aqueous-polymer two-phase partitioning of plasma membrane from rye roots, Mr. J. Banfield and Miss P. Parmar (University of Cambridge, UK) for technical assistance and Professor E.A.C. MacRobbie, Dr. G. Thiel (University of Cambridge, UK), Dr. M.R. Blatt (Wye College, University of London, UK), Dr. D. Sanders and Dr. E. Johannes (University of York, UK) for helpful discussions.     

Reconstitution of vacuolar ion channels into planar lipid bilayers.

Vacuolar ion channels were characterized after reconstitution into planar lipid bilayers. (1) Channel activity was observed after incorporation of tonoplast-enriched microsomal membranes, purified tonoplast membranes or of solubilized tonoplast proteins. (2) Channels of varying single-channel conductances were detected after reconstitution. In symmetrical 100 mmol l-1 KCl, conductances between 1 and 110 pS were frequently measured; the largest number of independent reconstitution events was seen for single-channel conductances of 16-25 pS (28 experiments), 30-42 pS (26), 49-56 pS (15) and 64-81 pS (15). Channel current usually increased linearly with voltage. (3) In asymmetrical solutions, cation-, non-selective and, for the first time for the tonoplast, anion-selective channels were detected. Ca(2+)-dependent regulation of channel opening was not observed in our reconstitution system. (4) Permeability was also observed for Cl-, NO3-, SO4(2-) and phosphate. (5) After fractionation of tonoplast proteins by size exclusion chromatography, ion channel activity was recovered in specific fractions. (6) Some of these fractions catalyzed sulfate transport after reconstitution into liposomes. The results suggest that different channels are active at the tonoplast membrane at a larger number than has been concluded from previous work.     

Single-channel study of the cGMP-dependent conductance of retinal rods from incorporation of native vesicles into planar lipid bilayers

Summary Unitary currents through cGMP-dependent channels of retinal rods are observed following incorporation into planar lipid bilayers of native vesicles from purified rod outer segment membranes washed free of soluble and peripheral proteins. The influence of the concentration of cGMP, inhibitors (cis-diltiazem, tetracaine and Ag⁺) and divalent cations (Ca²⁺, Mg²⁺, and Co²⁺) on the conductance and open probability of the channel is described, as well as the voltage dependence of these effects. The cGMP dependence suggests the existence of four binding sites for cGMP and reveals that sequential binding of four cGMP molecules corresponds to the opening of four discrete conductance levels. Finally, we provide conclusive evidence that activated G-protein does not directly inactivate the cGMP-dependent channels of bovine retinal rods.     

Microfabricated teflon membranes for low-noise recordings of ion channels in planar lipid bilayers

We present a straightforward, accessible method for the fabrication of micropores with diameters from 2 to 800 micro m in films of amorphous Teflon (Teflon AF). Pores with diameters 相似文献   

Voltage-dependent block by saxitoxin of sodium channels incorporated into planar lipid bilayers.

We have previously studied single, voltage-dependent, saxitoxin-(STX) blockable sodium channels from rat brain in planar lipid bilayers, and found that channel block by STX was voltage-dependent. Here we describe the effect of voltage on the degree of block and on the kinetics of the blocking reaction. From their voltage dependence and kinetics, it was possible to distinguish single-channel current fluctuations due to blocking and unblocking of the channels by STX from those caused by intrinsic channel gating. The use of batrachotoxin (BTX) to inhibit sodium-channel inactivation allowed recordings of stationary fluctuations over extended periods of time. In a range of membrane potentials where the channels were open greater than 98% of the time, STX block was voltage-dependent, provided sufficient time was allowed to reach a steady state. Hyperpolarizing potentials favored block. Both association (blocking) and dissociation (unblocking) rate constants were voltage-dependent. The equilibrium dissociation constants computed from the association and dissociation rate constants for STX block were about the same as those determined from the steady-state fractional reduction in current. The steepness of the voltage dependence was consistent with the divalent toxin sensing 30-40% of the transmembrane potential.     

Direct solubilization of heterologously expressed membrane proteins by incorporation into nanoscale lipid bilayers

One of the biggest challenges in the field of proteomics is obtaining functional membrane proteins solubilized and dispersed into a physiologically relevant environment that maintains the spectrum of in vivo activities. Here we describe a system composed of nanoscale self-assembled particles, termed Nanodiscs, which contain a single phospholipid bilayer stabilized by an encircling membrane scaffold protein (MSP). Using microsomal membranes of baculovirus-infected Spodoptera frugiperda (Sf9) insect cells overexpressing an N-terminally anchored cytochrome P450 monoxygenase (P450), we demonstrate that target membrane proteins can be directly solubilized and incorporated into distinct populations of Nanodiscs, which can be separated by size chromatography. We show that formation of these Nanodiscs from insect cell membranes allows for the compartmentalization into soluble nanostructures that provide a natural membrane bilayer that avoids the aggregation of membrane proteins often encountered in other reconstitution procedures. Lipid composition analysis and substrate binding analysis of size-fractionated Nanodiscs arrayed in microtiter plates further demonstrates that the Nanodisc system effectively disperses the overexpressed membrane protein into monodispersed bilayers containing biochemically defined lipid components and the target protein in its native from suitable for sensitive high-throughput substrate binding analysis.     

Anion channels from rat brain synaptosomal membranes incorporated into planar bilayers

Summary Synaptic membranes from rat brain were incorporated into planar lipid bilayers, and the characteristics of two types of anion-selective channels (type I and type II) were investigated. In asymmetric BaCl₂ buffers (cis, 100mm/trans, 25mm), single channel conductances at –40 mV were 70 pS (type I) and 120 pS (type II). Permeability ratios (P _Na:P _Ba:P _Cl) calculated from the Goldman-Hodgkin-Katz current equation for type I and type II channels were 0.230.041 and 0.050.031, respectively. Both channels exhibited characteristic voltage-dependent bursting activities. Open probability for type I channels had a maximum of 0.7 at about 0 mV and decreased to zero at greater transmembrane potentials of either polarity. Type II channels were relatively voltage independent at negative voltages and were inactivated at highly positive voltages. Type I channels showed spontaneous irreversible inactivation often preceded by sudden transition to subconducting states. DIDS blocked type I channels only from thecis side, while it blocked type II channels from either side.     

Activation and conductance properties of ryanodine-sensitive calcium channels from brain microsomal membranes incorporated into planar lipid bilayers

Summary Rat brain microsomal membranes were found to contain high-affinity binding sites for the alkaloid ryanodine (k _d 3nm.B _max 0.6 pmol per mg protein). Exposure of planar lipid bilayers to microsomal membrane vesicles resulted in the incorporation, apparently by bilayer-vesicle fusion, of at least two types of ion channel. These were selective for Cl^– and Ca²⁺, respectively. The reconstituted Ca²⁺ channels were functionally modified by 1 m ryanodine, which induced a nearly permanently open subconductance state. Unmodified Ca²⁺ channels had a slope conductance of almost 100 pS in 54mm CaHEPES and a Ca²⁺/TRIS⁺ permeability ratio of 11.0. They also conducted other divalent cations (Ba²⁺>Ca²⁺>Sr²⁺>Mg²⁺) and were markedly activated by ATP and its nonhydrolysable derivative AMPPCP (1mm). Inositol 1,4,5-trisphosphate (1–10 m) partially activated the same channels by increasing their opening rate. Brain microsomes therefore contain ryanodine-sensitive Ca²⁺ channels, sharing some of the characteristics of Ca²⁺ channels from striated but not smooth muscle sarcoplasmic reticulum. Evidence is presented to suggest they were incorporated into bilayers following the fusion of endoplasmic reticulum membrane vesicles, and their sensitivity to inositol trisphosphate may be consistent with a role in Ca²⁺ release from internal membrane stores.     

Formation of ion channels by Colicin B in planar lipid bilayers

Summary The gene for the antibacterial peptide colicin B was cloned and transformed into a host background where it was constitutively overexpressed. The purified gene product was biologically active and formed voltage-dependent, ion-conducting channels in planar phospholipid bilayers composed of asolectin. Colicin B channels exhibited two distinct unitary conductance levels, and a slight preference for Na⁺ over Cl^–. Kinetic analysis of the voltage-driven opening and closing of colicin channels revealed the existence of at least two conducting states and two nonconducting states of the protein. Both the ion selectivity and the kinetics of colicin B channels were highly dependent on pH. Excess colicin protein was readily removed from the system by perfusing the bilayer, but open channels could be washed out only after they were allowed to close. A monospecific polyclonal antiserum generated against electrophoretically purified colicin B eliminated both the biological and in vitro activity of the protein. Membrane-associated channels, whether open or closed, remained functionally unaffected by the presence of the antiserum. Taken together, our results suggest that the voltage-independent binding of colicin B to the membrane is the rate-limiting step for the formation of ion channels, and that this process is accompanied by a major conformational rearrangement of the protein.     

Interaction of influenza virus proteins with planar bilayer lipid membranes. I. Characterization of their adsorption and incorporation into lipid bilayers

Alterations in the surface potential difference (delta U) of asolectin planar bilayer lipid membranes were measured following the adsorption of isolated matrix protein (M-protein) or neuraminidase of influenza virus. The method used was based upon measurement of the bilayer lipid membrane capacitance current second harmonic. The delta U dependence on the M-protein and neuraminidase concentration indicates different mechanisms of adsorption of these viral proteins by the lipid bilayer. The conductance (G0) dependence of the bilayer lipid membrane with different compositions on the concentration of isolated surface glycoproteins, hemagglutinin and neuraminidase, M-protein or neuraminidase was investigated. The change in G0 for M-protein was observed only after adsorption saturation had been achieved. Neuraminidase alone does not affect the membrane conductivity. The surface charge and lipid composition of the lipid bilayer influences the adsorption and incorporation of influenza virus M-protein and surface glycoproteins. The reversibility of protein incorporation into the bilayers was investigated by a perfusion technique. The results show reversibility of surface glycoprotein incorporation while M-protein binding appears to be irreversible.     

Delta-endotoxins form cation-selective channels in planar lipid bilayers.

Delta-endotoxins CryIA(c) and CryIIIA, two members of a large family of toxic proteins from Bacillus thuringiensis, were each allowed to interact with planar lipid bilayers and were analyzed for their ability to form ion-conducting channels. Both of these toxins made clearly resolved channels in the membranes and exhibited several conductance states, which ranged from 200 pS to about 4000 pS (in 300 mM KCl). The channels formed by both toxins were highly cation-selective, but not ideally so. The permeability ratio of K+ to Cl- was about 25 for both channels. The ability of these proteins to form such channels may account for their toxic action on sensitive cells, and suggests that this family of toxins may act by a common mechanism.     

Pure lipid vesicles can induce channel-like conductances in planar bilayers

Summary Typical channel-like current fluctuations were observed in planar lipid bilayers following brief exposure to large concentrations of lipid vesiclesdevoid of protein. Vesicles, formed by sonication of pure lipids suspended in 150mm salt solutions, were ejected 0.5 mm from a planar bilayer with a pipette. Over the next several minutes the bilayer conductance changed in ways usually considered to be indicative of reconstituted protein channels including step conductance changes (both up and down), flickering, ion selectivity, and inactivation. This observation demonstrates the need for caution in interpreting conductance changes which occur following ejection of channel-containing vesicles near a membrane.     

猪心室肌细胞膜K+通道在人工磷脂双层的重装

目的：将提取的猪心室肌细胞膜上K^ 通道重装在磷脂双层上,用电压嵌方法研究离子通道。方法：将猪心室肌制成匀浆,通过蔗糖梯度离心,分离出通道蛋白成分,利用双室系统将其重装在人工膜上,在电压籍位下记录通道电流。结果：提取的通道蛋白成分优势电导为27～31ps,此外还记录到有15,50和100ps的几种通道活动,其中以27～31ps最为常见。经测定反转电位,确定它们为K^ 选择性通道。结论：本研究在国内首次完成了心肌钾通道在人工脂双层膜上的重装,为在单通道基础上研究K^ 通道提供了重要手段。     

Formation of cation channels in planar lipid bilayers by brefeldin A.

Brefeldin A (BFA) is a novel agent with the unique property of effecting a rapid increase of Golgi cisternae volume and subsequent loss of a recognizable Golgi apparatus in treated cells. Although a receptor-mediated mechanism has been proposed, the molecular basis of BFA action remains unknown (Lippincott-Schwartz, J., Glickman, J., Donaldson, J. G., Robbins, J., Kreis, T. E., Seamon, K. B., Sheetz, M. P., and Klausner, R. D. (1991) J. Cell Biol. 112, 567-577). Since a variety of ionophores distort Golgi architecture by initially causing osmotic swelling of the cisternae (Mollenhauer, H. H., Morre, D. J., and Rowe, L. D. (1990) Biochim. Biophys. Acta 1031, 225-246), Golgi membrane permeabilization by BFA seemed possible. We examined the effects of BFA on the conductance of planar lipid bilayers bathed in several aqueous salt solutions. Addition of BFA (1 microgram/ml) quickly augmented alkali cation conductance (K+ greater than Na+ much greater than Li+) but not anion conductance of the bilayer. Lower concentrations (1 ng/ml) indicated that BFA formed discrete, cation-selective channels in these bilayers. Given that Golgi cisternae volume increases immediately upon treatment with BFA, these findings suggest that alteration of ion gradients or Golgi membrane potential followed by an influx of water may be the mechanism by which BFA initiates disruption of Golgi structural integrity. Subsequent functional perturbations may then ensue either as a consequence of these initial structural changes or by a combination of several distinct mechanisms.     

Ion-conducting channels produced by botulinum toxin in planar lipid membranes

The interaction of botulinum neurotoxin (Botx) with planar lipid membranes was studied by measuring the ability of the toxin to form ion-conducting channels. Channel formation was pH dependent. At physiological pH, Botx formed no channels, whereas at pH 6.6, the toxin formed channels with a unit conductance of 12 pS in 0.1 M NaCl. The rate of channel formation increased with decreasing pH, reaching a maximum at pH 6.1, and then decreased at lower values of pH. The channels, once formed, were permanent entities in the membrane throughout the course of an experiment and fluctuated between an open and a closed state. The rate of channel formation depended upon the square of the toxin concentration, suggesting an aggregation step is involved in channel formation. The data were consistent with the hypothesis that Botx enters cells through endocytosis, followed by its release into the cytoplasm at low pH.     

Quantitation of cholesterol incorporation into extruded lipid bilayers

Cholesterol incorporation into lipid bilayers, in the form of multilamellar vesicles or extruded large unilamellar vesicles, has been quantitated. To this aim, the cholesterol contents of bilayers prepared from phospholipid:cholesterol mixtures 33-75 mol% cholesterol have been measured and compared with the original mixture before lipid hydration. There is a great diversity of cases, but under most conditions the actual cholesterol proportion present in the extruded bilayers is much lower than predicted. A quantitative analysis of the vesicles is thus required before any experimental study is undertaken.     

Incorporation of ion channels from bovine rod outer segments into planar lipid bilayers.

Membranes vesicles, prepared from bovine rod outer segments were fused with planar lipid bilayers. Two different ion channels were identified by recording currents from single channels. Both types of channels were selective for sodium rather than potassium and were impermeable to chloride ions. Unit conductances were 20 and 120 pS, respectively, in 150 mM sodium chloride. The channel with the larger unit conductance was sensitive to the transmembrane potential. This channel rapidly activated within less than 10 ms after a voltage jump to a more negative membrane potential and then inactivated after several seconds. The duration of the active period and the properties of the channel depended on the amplitude of the voltage jump. The channel of smaller unit conductance did not show any voltage-dependent activation or inactivation. Both types of channels were insensitive to light in the planar bilayer system. Channels incorporated into planar bilayers on a Teflon sandwich septum or on the tip of a glass micropipette gave similar results.     

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.