Activation, inactivation, and desensitization of acetylcholine receptor channel complex detected by binding of perhydrohistrionicotoxin

Divergent Nine-Step Syntheses of Perhydrohistrionicotoxin Analogs and Their Inhibition Activity Toward Chicken α4β2-Neuronal Nicotinic Acetylcholine Receptors

Histrionicotoxin (HTX) alkaloids, which are isolated from Colombian poison dart frogs, are analgesic neurotoxins that modulate nicotinic acetylcholine receptors (nAChRs) as antagonists. Perhydrohistrionicotoxin (pHTX) is the potent synthetic analogue of HTX and possesses a 1-azaspiro[5.5]undecane skeleton common to the HTX family. Here, we show for the first time the divergent nine-step synthesis of pHTX and its three stereoisomers from the known aldehyde through a one-step construction of the 1-azaspiro[5.5]undecane framework from a linear amino ynone substrate. Surprisingly, some pHTX diastereomers exhibited antagonistic activities on the chicken α4β2-neuronal nAChRs that were more potent than pHTX.

Nicotinic receptor inhibition by Tetraponera ant alkaloids

1. Tetraponerines are a group of alkaloids occurring in the venoms of ants belonging to the genus Tetraponera. Eight compounds had been isolated and their structures elucidated, but their mechanisms of action had not yet been reported. We have studied the actions of several of these tetraponerines on vertebrate neuromuscular, ganglionic, and brain nicotinic acetylcholine receptors (nAChRs) using a variety of techniques including muscle contracture, cultured cell functional assays, neuronal patch clamping, and radioligand binding methods. 2. Potency for inhibition of the frog muscle carbachol-elicited contracture increased as the carbon 9 side chain alkyl group was increased in length to 10-12 carbons, then decreased when the chain was 18-carbons long. Potency differences between T-7 and T-8, which differ only in the stereochemistry of the carbon pentyl side chain were rather small. Quaternization of either N atom in a T-8 analog bearing a 10-carbon length alkyl substituent did not greatly affect potency for inhibition of the muscle response; thus the ionized form is an active form of this tetraponerine. 3. T-7 inhibited the nicotine-stimulated efflux of 86Rb from cultured PC12 cells, which primarily express alpha3-beta4 ganglionic type nicotinic receptors. T-8 blockade of BTX-sensitive and insensitive neuronal nAChRs, as studied by patchclamp recordings from cultured rat brain neurons, was also consistent with a noncompetitive type of inhibition. 4. T-7 displaced binding of the nAChR ion channel binding ligand thienylcyclophenidyl (TCP), an analog of PCP, to Torpedo neuromuscular type receptors. The affinity of the TCP binding site for T-7 did not depend upon the desensitization state of the receptor. 5. We conclude that the tetraponerines act at a site on nAChRs different from the ACh binding site which is probably located within the ion channel.

Chlorpyrifos, parathion, and their oxons bind to and desensitize a nicotinic acetylcholine receptor: relevance to their toxicities

The nicotinic acetylcholine receptor (nAChR) of the electric organ of the electric ray. Torpedo sp., the richest source of nAChR, with similar structure and pharmacology to the mammalian skeletal muscle nAChR, carries several binding sites for different ligands. Incubation of Torpedo membrane-bound nAChRs with the agonist carbamylcholine (Carb) stimulated the binding of [3H]thienyl-cyclohexylpiperidine ([3H]TCP), which binds to the receptor's noncompetitive antagonist binding site in its ionic channel, with high affinity (Kd of 196 nM). The agonist-stimulated binding of [3H]TCP (i.e., binding to activated nAChRs) was inhibited in a concentration-dependent manner by four organophosphate (OP) anticholinesterases, chlorpyrifos oxon (CPO), chlorpyrifos (CPS), parathion (PS), and paraoxon (PO) with IC50 (concentration that inhibits 50% of the effect) values of 5, 150, 200, and 300 microM, respectively. The binding of CPO was totally reversible. The OPs had no effect on equilibrium binding of [alpha-125I]bungarotoxin ([alpha-125I]BGT) to the receptor's acetylcholine (ACh)-binding site, but preincubation of the membranes with the OPs increased this site's affinity for Carb. In absence of agonist, 100 microM of the OPs increased the binding of [3H]TCP by two- to fivefold with the following order of decreasing potency: PS > CPO > CPS > PO. The data suggest that in addition to inhibition of acetylcholinesterase, these OPs bind to a site on the nAChR that is different from the sites that bind ACh or TCP and that this binding induces nAChR desensitization. The relevance of this direct action of OPs on nAChRs on their acute toxicities is discussed.

Inhibition of N-methyl-D-aspartate- and kainate-evoked noradrenaline release in human cerebral cortex slices by ethanol

The effect of ethanol on the release of noradrenaline evoked by various stimuli was investigated in human cerebral cortical slices from patients undergoing neurosurgery. The slices were preincubated with [3H]noradrenaline and then superfused. Tritium overflow was stimulated by exposure to N-methyl-D-aspartate (NMDA; in slices superfused without Mg2+), kainic acid, veratridine or by increasing the K+ concentration. The NMDA-evoked tritium overflow was concentration-dependently inhibited by ethanol; an inhibition by 37% occurred at 48 mmol/l ethanol. This ethanol concentration was not yet effective when kainic acid was used for stimulation, but ethanol 150 mmol/l strongly inhibited the tritium overflow evoked by kainic acid as well. The tritium overflow evoked by veratridine or high K+ was not affected by ethanol in the concentration range investigated. These findings are compatible with the suggestion that the NMDA receptor and, with less susceptibility, the kainate receptor are sites of action underlying the effect of ethanol in the human brain.

Pharmacological specificity of a nicotinic acetylcholine receptor optical sensor

The pharmacological specificity of a nicotinic acetylcholine receptor (nAChR) optical biosensor was investigated using three fluorescein isothiocyanate (FITC)-tagged neurotoxic peptides that vary in the reversibility of their receptor inhibition: alpha-bungarotoxin (alpha-BGT), alpha-Naja toxin (alpha-NT), and alpha-conotoxin (GI) (alpha-CNTX). Kinetic analysis of the time course of binding of FITC-neurotoxins to the nAChR-coated fiber gave association rate constants (k+1) of 8.4 x 10(6) M-1 min-1 for FITC-alpha-BGT, 6.0 x 10(6) M-1 min-1 for FITC-alpha-NT and 1.4 x 10(6) M-1 min-1 for FITC-alpha-CNTX. The dissociation rate constants (k-1) for the three neurotoxins were 7.9 x 10(-3) min-1. 4.8 x 10(-2) min-1 and 8.0 x 10(-1) min-1 for FITC-alpha-BGT. FITC-alpha-NT and FITC-alpha-CNTX, respectively. The equilibrium dissociation constant (Kd) values for the three toxins. calculated from these rare constants, were similar to published values obtained from tissue responses or ligand binding assays. The optical signal generated by FITC-alpha-NT binding to the nAChR-coated fiber was effectively quenched by agonists and antagonists of the nAChR but not by most of the tested agonists and antagonists of muscarinic cholinergic, adrenergic, glutamatergic, serotonergic, dopaminergic or GABAergic receptors. Interestingly, 5-hydroxy-tryptamine, haloperidol and (+)cis-methyldioxolane gave significant inhibition of FITC-alpha-NT binding to the immobilized receptor. Equilibrium constants of inhibition (Ki) for d-tubocurarine (d-TC) and carbamylcholine (carb) were determined from competition studies using FITC-alpha-CNTX. FITC-alpha-NT or FITC-alpha-BGT as probes for receptor occupancy. When the more reversible probe FITC-alpha-CNTX was used, the Ki value for d-TC was an order of magnitude lower than those determined using the less reversible probes. Ki values for carb however, were independent of the FITC-toxin probe used.

Functional properties of the nicotinic and glutamatergic receptors

Several important physiological processes such as plasticity, memory, cell death, and rhythmic firing involve the N-methyl-D-aspartate (NMDA)-type of glutamatergic receptor. Nicotinic acetylcholine receptors (AChR), recently demonstrated in the central nervous system (CNS), are also of great interest. We have used several ligands to study the physiology and pharmacology of the agonist recognition sites of these receptors and kinetic properties of associated ion channels using whole-cell, cell-attached or outside-out variants of the patch-clamp technique. Enzymatically dissociated frog interosseal muscles were used to study peripheral AChRs, and tissue cultured or acutely dissociated hippocampal neurons and retinal ganglion cells (RGCs) for CNS receptors. For reproducible and fast solution changes when recording in the whole-cell configuration, we modified the "U"-shaped tube system to obtain different outputs from the same outflow port. We used fluorescent rhodamine-labeled latex microspheres to identify RGCs. Our studies provide important information regarding the molecular mechanisms of several clinically used agents. Additionally, similar actions of noncompetitive agents on the ion channels of the nicotinic ACh and NMDA receptors support the concept of a receptor ion channel superfamily.

Inhibition of N-methyl-D-aspartate (NMDA)- and L-glutamate-induced noradrenaline and acetylcholine release in the rat brain by ethanol

The influence of ethanol on stimulation-evoked 3H-transmitter release was examined in slices of the rat brain cortex and corpus striatum preincubated with 3H-noradrenaline and 3H-choline, respectively. 3H-Transmitter release was stimulated by NMDA, L-glutamate, electrical impulses, reintroduction of Ca2+ ions ("Ca2(+)-evoked release", after superfusion with Ca2(+)-free, K(+)-rich solution) or veratridine. In cortical slices preincubated with 3H-noradrenaline and superfused with Mg2(+)-free, otherwise physiologically composed salt solution, ethanol inhibited the NMDA- or L-glutamate-induced tritium overflow (IC50 45 and 37 mmol/l, respectively). In contrast, the tritium overflow in response to electrical stimulation, reintroduction of Ca2+ ions or veratridine was not affected by ethanol at concentrations up to 320 mmol/l; these experiments were carried out in cortical slices superfused with solution containing a physiological Mg2+ concentration. Ethanol also failed to inhibit Ca2(+)-evoked release in the absence of Mg2+ ions. In the presence of 1 mumol/l veratridine, but not in its absence, NMDA induced tritium overflow even when cortical slices were superfused with salt solution containing a physiological Mg2+ concentration; again, ethanol inhibited this NMDA-evoked tritium overflow (IC50 73 mmol/l. In striatal slices preincubated with 3H-choline and superfused with Mg2(+)-free "physiological" salt solution the NMDA-evoked tritium overflow was also, although at lower potency, inhibited by ethanol (IC50 192 mmol/l). In spite of the differences between the IC50 values of ethanol determined for the inhibition of cortical noradrenaline and striatal acetylcholine release, it may be concluded that the NMDA receptor-ion channel complex is one of the sites of action underlying the ethanol-induced inhibition of neurotransmitter release.(ABSTRACT TRUNCATED AT 250 WORDS)

Desensitization of the nicotinic acetylcholine receptor: molecular mechanisms and effect of modulators

1. Loss of response after prolonged or repeated application of stimulus is generally termed desensitization. A wide variety of phenomena occurring in living organisms falls under this general definition of desensitization. There are two main types of desensitization processes: specific and non-specific. 2. Desensitization of the nicotinic acetylcholine receptor is triggered by prolonged or repeated exposure to agonists and results in inactivation of its ion channel. It is a case of specific desensitization and is an intrinsic molecular property of the receptor. 3. Desensitization of the nicotinic acetylcholine receptor at the neuromuscular junction was first reported by Katz and Thesleff in 1957. Desensitization of the receptor has been demonstrated by rapid kinetic techniques and also by the characteristic "burst kinetics" obtained from single-channel recordings of receptor activity in native as well as in reconstituted membranes. In spite of a number of studies, the detailed molecular mechanism of the nicotinic acetylcholine receptor desensitization is not known with certainty. The progress of desensitization is accompanied by an increase in affinity of the receptor for its agonist. This change in affinity is attributed to a conformational change of the receptor, as detected by spectroscopic and kinetic studies. A four-state general model is consistent with the major experimental observations. 4. Desensitization of the nicotinic acetylcholine receptor can be potentially modulated by exogenous and endogenous substances and by covalent modifications of the receptor structure. Modulators include the noncompetitive blockers, calcium, the thymic hormone peptides (thymopoietin and thymopentin), substance P, the calcitonin gene-related peptide, and receptor phosphorylation. Phosphorylation is an important posttranslational covalent modification that is correlated with the regulation and desensitization of the receptor through various protein kinases. 5. Although the physiological significance of desensitization of the nicotinic receptor is not yet fully understood, desensitization of receptors probably plays a significant role in the operation of the neuronal networks associated in memory and learning processes. Desensitization of the nicotinic receptor could also possibly be related to the neuromuscular disease, myasthenia gravis.

Macromolecular sites for specific neurotoxins and drugs on chemosensitive synapses and electrical excitation in biological membranes

The present review deals with the molecular mechanisms and elementary phenomena underlying the activation of the voltage- and chemo-sensitive membrane macromolecules: sodium- and potassium-ion channels and nicotinic ACh receptors and their associated ion channel. To achieve an understanding of their various kinetics and conformational states, a number of novel alkaloids, BTX, HTXs, gephyrotoxins, and certain psychotomimetic drugs such as phencyclidine, and many other pharmacologically active agents have been used. Biochemical assays and various electrophysiological techniques have been used in a number of biological preparations--e.g., Torpedo membranes, brain synaptosomes, amphibian and mammalian neuromuscular preparations--to describe the action of such agents. The availability of BTX and scorpion toxins together with aconitine and veratridine as activators and TTX and STX as antagonists of the voltage-sensitive sodium channels, made possible the identification and the physiological and pharmacological characterization of these channels. These studies provided the basis for understanding the mechanisms underlying electrical excitability and culminated, more recently, in the purification and reconstitution of sodium channels from rat brain and in the successful cloning of these channels with the elucidation of their primary structure. We now know that the sodium channel has a molecular mass of 316,000 daltons, consists of five subunits, and has multiple sites for various ligands. In contrast to sodium channels, various classes of potassium channels (inward and outward rectifier potassium channels and Ca(2+)-activated potassium channels) have been described. Unlike the sodium channels, there are no known specific activators for potassium channels. However, a number of potassium channel blockers such as 4-aminopyridine, HTX, histamine, and norepinephrine have been identified which complement the varying types of potassium channels in different neurons. One class of potassium channel blockers with profound medical and social implications comprises PCP and its analogues. The blockade of the potassium-induced 86Rb+ efflux from brain cells, the resulting prolongation of muscle and nerve action potentials, and the increase in transmitter release observed with PCP and some analogues are all highly suggestive of a role for the potassium channel in the behavioral effects of these drugs and its potential involvement in schizophrenia. A number of toxic principles of both plant and animal origin played a significant role in the development of our knowledge about the nAChR.(ABSTRACT TRUNCATED AT 400 WORDS)

The novel anticonvulsant MK-801 binds to the activated state of the N-methyl-D-aspartate receptor in rat brain

The influence of endogenous and exogenous acidic amino acids on the binding of [3H]-MK-801, a selective, non-competitive antagonist of N-methyl-D-aspartate (NMDA) receptors, has been investigated in rat cerebral cortex crude synaptic membranes (CSM). Removal of endogenous glutamate and aspartate from CSM by repeated washing reduced the affinity of [3H]-MK-801 for its binding site (with no change in the total number of binding sites) and increased NMDA-sensitive L-[3H]-glutamate binding. In washed CSM, competitive NMDA antagonists of the DL-alpha-amino-omega-phosphonocarboxylate series reduced [3H]-MK-801 binding and NMDA-sensitive L-[3H]-glutamate binding, the most active compounds being 2-amino-5-phosphonovalerate (AP5) and 2-amino-7-phosphono-heptanoate (AP7). Exogenous excitatory amino acid agonists enhanced the binding of [3H]-MK-801 to washed CSM by up to 700%. A selective involvement of NMDA receptors in these effects was indicated by the excellent correlation between EC50s for stimulation of [3H]-MK-801 binding and IC50s for inhibition of NMDA-sensitive L-[3H]-glutamate binding in the same membranes. The selective, competitive NMDA receptor antagonist D-AP5 blocked the L-glutamate-induced increase in [3H]-MK-801 binding in a competitive manner with a pA2 value of 6.0. These results seem to reflect a molecular interaction between two distinct components of the NMDA receptor complex: the transmitter recognition site and the site through which MK-801 exerts its antagonist effects, possibly the ion channel.

Histrionicotoxins: effects on binding of radioligands for sodium, potassium, and calcium channels in brain membranes

A series of eight histrionicotoxins and two synthetic analogs inhibit binding of [3H]batrachotoxinin B to sites on voltage dependent sodium channels in brain membranes. Perhydrohistrionicotoxin (IC50 0.33 microM) and octahydrohistrionicotoxin (IC50 1.2 microM) are comparable in activities to potent local anesthetics. Histrionicotoxin (IC50 17 microM) and the other histrionicotoxins are much less potent. The histrionicotoxins also inhibit binding of [3H]phencyclidine to putative potassium channels in brain membranes. Histrionicotoxin (IC50 15 microM) and the other histrionicotoxins are much more potent than perhydrohistrionicotoxin (IC50 200 microM), but are at least 200-fold less potent than phencyclidine. The histrionicotoxins enhance binding of [3H]nitrendipine to sites on calcium channels in brain membranes, with the exception of perhydrohistrionicotoxin, which inhibits binding. Structure activity relationships at these channel sites and at the sites for noncompetitive blockers on the nicotinic acetylcholine receptor channel (AChR) complex differ. The histrionicotoxins are more potent at the sites on the AChR complex than at sites on other channels with the exception of perhydrohistrionicotoxin, which has comparable potency at the AChR complex and sodium channels.

Characterization of the transient agonist-triggered state of the acetylcholine receptor rapidly labeled by the noncompetitive blocker [3H]chlorpromazine: additional evidence for the open channel conformation

The kinetics of covalent labeling of the alpha, beta, gamma, and delta chains of the acetylcholine receptor (AcChR) from Torpedo marmorata by the noncompetitive blocker [3H]chlorpromazine ([3H]CPZ) are investigated by using rapid mixing photolabeling techniques. In an initial study [Heidmann, T., & Changeux, J. P. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 1897-1901], it was shown that the rate of [3H]CPZ labeling increases 100-1000-fold upon simultaneous addition of nicotinic agonists to the AcChR and that prior addition of these agonists abolishes the effect. The data were interpreted in terms of the rapid labeling of the transient active state of the AcChR where the ion channel is in its open configuration. This interpretation was recently challenged [Cox, R. N., Kaldany, R. R. J., Di Paola, M., & Karlin, A. (1985) J. Biol. Chem. 260, 7186-7193] on the ground of studies with a different noncompetitive blocker, [3H]quinacrine azide, and the suggestion was made that this compound labels the rapidly desensitized closed channel conformation of the AcChR. In this paper it is shown that the rate of rapid labeling of the AcChR by [3H]CPZ decreases to negligible values upon exposure of the AcChR to nicotinic agonists, in the 100-500-ms time range. The absolute values of the rate constants of this decrease (10-15 s-1 for saturating concentrations of acetylcholine and carbamoylcholine) and their variation with agonist concentration (apparent dissociation constants of 40 microM and 0.4 mM for acetylcholine and carbamoylcholine, respectively) are those expected for the rapid desensitization of the AcChR.(ABSTRACT TRUNCATED AT 250 WORDS)

Voltage- and time-dependent effects of phencyclidines on the endplate current arise from open and closed channel blockade

The actions of phencyclidine [1-(1-phenylcyclohexyl)piperidine, PCP] and its morpholine analog [1-(1-phenylcyclohexyl)morpholine, PCM] on ionic currents of nicotinic acetylcholine receptors were studied at the neuromuscular junction of frog skeletal muscle and on embryonic rat muscle cells in tissue culture. PCP and PCM reduced the peak amplitude and the decay time constant of the endplate current (EPC). PCP produced a voltage-dependent curvature and a time-dependent hysteresis loop at negative potentials (at potentials from -50 to -150 mV). In contrast, PCM caused a depression of EPC peak amplitude, but the current-voltage relationship (+60 to -150 mV) remained linear. When PCP-modified EPCs were elicited in trains at hyperpolarized potentials the amplitudes of successive events were progressively decreased and the magnitude of the decrease was dependent on the level of hyperpolarization. At positive potentials the process was reversed; the amplitude increased with successive stimulations. The EPC decayed exponentially in the presence of PCP and PCM, with a shortened time constant of decay that was less dependent on membrane potential than control. PCP and PCM caused only a 20% decrease of the amplitude of the iontophoretically evoked acetylcholine potential, which was significantly different from that induced by the desensitizing alkaloid perhydrohistrionicotoxin. Both PCP and PCM reduced by 50% the mean channel open time obtained from rat myoballs, giving a potency ratio for PCP to PCM of 2.5. This relative potency was correlated with that obtained for the reduction in the decay time constant of the EPC (ratio = 2.2). The effects of PCP on the peak amplitude of the EPC seem to be related to a conformational change of the acetylcholine receptor occurring before channel activation and not to a receptor desensitization.

Covalent labeling of functional states of the acetylcholine receptor. Effects of antagonists on the receptor conformation

Photoaffinity labeling of membrane-bound nicotinic acetylcholine receptor from Torpedo marmorata electric tissue with the ion-channel blocker [3H]TPMP+ reveals various functional states of the receptor protein if labeling is performed with ms time resolution. In the resting and in the activated state most of the label is incorporated into the alpha-polypeptide chains of the receptor complex. When equilibrated with agonists and antagonists, predominantly the delta-polypeptide chain (and to a lesser extent the beta-chain) reacts with the photolabel. Reactivity of the delta-chain increases after exposure to cholinergic effectors with a half-life slower than the kinetics of receptor activation or rapid desensitization. Agonists and antagonists stimulate photolabelling of the delta-chain with different kinetics. For acetylcholine, carbamoylcholine and suberyldicholine the half-life of the reactivity increases is 400 - 500 ms; for the antagonists hexamethonium, d-tubocurarine and flaxedil it is about 10 s. The latter slow kinetics are also observed when the receptor is preequilibrated with agonists or antagonists prior to mixing with [3H]TPMP+ and starting the photoreaction. We conclude that time-resolved photoaffinity labeling can convalently mark protein structures involved in receptor functions. Of special interest is the observation that antagonists also induce a conformational change in the receptor protein.

Effect of histrionicotoxin on ion channels in synaptic and conducting membranes of electroplax of Electrophorus electricus

Histrionicotoxin (HTX) at low concentrations of 5-10 microM blocks the postsynaptic potential of the electroplax of Electrophorus electricus. At 100-fold higher concentrations, HTX blocks the directly evoked action potentials of the conducting membrane. The pH dependence of the blockade by HTX at synaptic channels is different from that at the conducting membrane. At the synapse HTX is more potent at acid pH, while at the conducting membrane it is more potent at basic pH. HTX at high concentrations antagonizes the effects of batrachotoxin, indicative of an effect on the batrachotoxin-sensitive sodium channels involved in action potential generation. While the effects of HTX on the synaptic channels are concentration, time, and pH dependent, the effects on the channels of the conducting membrane are, in addition, use dependent, suggesting interactions of HTX with the activated forms of these channels.

Two-component desensitization at the neuromuscular junction of the frog

Desensitization to ionophoretically applied ACh has been studied at voltage-clamped neuromuscular junctions of Rana pipiens. The time courses of both the onset of and recovery from desensitization displayed two components. The application of metabolic inhibitors to the preparation decreased the degree of recovery and also decreased both time constants of onset. The effect on onset was more pronounced on the slow component while no effect selective for either of the two components of recovery was seen. Intracellular injection of EGTA into the muscle cell increased both time constants of desensitization onset. The effect was much more pronounced on the slow component. Increasing the dose of ACh selectively decreased the fast time constant of desensitization onset. The effect was more selective in low-calcium than normal Ringer solution. These observations suggest that there are at least two independent mechanisms in the process of desensitization at the neuromuscular junction. These mechanisms differ in time course, degree of dependency on [Ca]i, and sensitivity to acetylcholine dose.

Conduction and block by organic cations in a K+-selective channel from sarcoplasmic reticulum incorporated into planar phospholipid bilayers

A collection of organic cations has been used to probe the gross structural features of the ionic diffusion pathway in a K+-selective channel from sarcoplasmic reticulum (SR). Channels were incorporated into planar phospholipid bilayer membranes, and single-channel currents were measured in the presence of ammonium-derived cations in the aqueous phases. Small monovalent organic cations are able to permeate the channel: the channel conductance drops sharply for cations having molecular cross sections larger than 18-20 A2. Impermeant or poorly permeant cations such as tetraethylammonium, choline, and glucosamine, among others, block K+ conduction through the channel. This block is voltage dependent and can be described by a one-site, one-ion blocking scheme. 19 monovalent organic cations blocks primarily from the trans side of the membrane (the side defined as zero voltage), and much more weakly, if at all, from the cis side (to which SR vesicles are added). These blockers all appear to interact with a site located at 63% (average value) of the electric potential drop measured from the trans side. Furthermore, block by 1,3-bis[tris(hydroxymethyl)-methylamino] propane (BTP) shows that the presence of a blocking ion increases the duration of the apparent open state, as expected for a scheme in which the blocking site can be reached only when the channel is open. The results lead to a picture of the channel containing a wide (at least 50 A2) nonselective trans entry in series with a narrow (20 A2) constriction.

Triphenylmethylphosphonium is an ion channel ligand of the nicotinic acetylcholine receptor

The lipophilic cation triphenylmethylphosphonium (Ph3MeP+), which is widely used as a sensor for membrane potential with cells, organelles, and membrane vesicles, is shown also to accumulate in membranes rich in nicotinic acetylcholine receptor in a voltage-independent way. Evidence is presented that Ph3MeP+ in this system is bound to a cation-binding site of the ion channel that is part of the acetylcholine receptor complex. Binding is stimulated by cholinergic effectors (Kd = 13 microM in the absence of carbamoylcholine; Kd = 1.5 microM in the presence of 10 microM carbamoylcholine), and this stimulation is blocked by alpha-bungarotoxin. Ph3MeP+ blocks efflux of 22Na from receptor-rich microsacs and appears to compete with the channel ligand phencyclidine for a common binding site. In contrast to the binding of other proven channel ligands, Ph3MeP+-binding is not affected by desensitization.

Desensitization at the frog neuromuscular junction: a biphasic process

1. The desensitization of the cholinergic receptor has been investigated at the frog neuromuscular junction. The agonist was either perfused or applied by ionophoresis.2. In all situations, desensitization develops in two phases: a fast one, experimentally in the second range but likely to be briefer, and a slower one, which extends over tens of seconds.3. When the presence of the agonist is prolonged, desensitization approaches a steady state, estimated through the amplitude of a test response. In steady-state conditions, this amplitude depends upon the desensitizing agonist concentration. The dose-response curve for desensitization induced by carbachol (CCh) indicates that half of the receptors can be desensitized at room temperature in the presence of 2.3 mum-CCh. The shape of the curve suggests that one desensitized receptor can bind two CCh molecules.4. The recovery from desensitization, estimated with a repetitive test pulse, displays two exponential phases. The time constant of the fast phase is 11-12 sec, and 4-5 min for the slow phase, regardless of the concentration or the nature of the agonist (acetylcholine or carbachol).5. The factor which most strikingly affects the relative amplitudes of the fast and slow phases of recovery is the duration of the (desensitizing) agonist application. Desensitizations lasting a few seconds are followed by a ;fast' recovery, whereas the slow phase of recovery is prominent when the agonist has been applied for more than 2 min.6. The fast and slow phases of desensitization onset and offset are not due to independent causes but are coupled: in given conditions, the onset can be essentially fast, and the recovery slow.7. All our findings can fit in a cyclic scheme of desensitization, derived from the one of Katz & Thesleff (1957) with two modifications: whether activatable or desensitized, one receptor molecule would have two agonist binding sites; moreover, the desensitized receptor would exist in two distinct and interconverting conformations: D(1), giving rise to the fast phases of onset and offset, and D(2), responsible for the existence of the slow components of desensitization.

Selective labeling of the delta subunit of the acetylcholine receptor by a covalent local anesthetic

A radioactive photoaffinity derivative of the potent local anesthetic trimethisoquin, 5-azido[3H]trimethisoquin, was used to label the acetylcholine receptor from Torpedo marmorata electric organ. The product labeled the 66 000-dalton (delta) subunit of the receptor with the selectivity expected for an affinity label of the site for noncompetitive blockers. That is, the labeling was enhanced by cholinergic agonists and inhibited by other noncompetitive blockers. The 40 000-dalton (alpha)( subunit of the receptor was labeled in a manner consistent with the attachment of 5-azido[3H]trimethisoquin to an acetylcholine binding site as the incorporation of radioactivity into the alpha chain was inhibited by cholinergic agonists and antagonists, such as carbamylcholine, d-tubocurarine, and alpha-bungarotoxin. The reversible binding of [3H]phencyclidine, a potent noncompetitive blocker, to acetylcholine receptor rich membranes resembled qualitatively and quantitatively the 5-azido[3H]trimethisoquin labeling of the delta subunit and was inhibited by the prior covalent labeling of the membranes with nonradioactive 5-azidotrimethisoquin. Thus, 5-azido[3H]-trimethisoquin labels at least a portion of the binding site for noncompetitive blockers at the level of the delta subunit. The functional significance of this site and the use of 5-azidotrimethisoquin in the study of acetylcholine receptor structure and function are discussed.

Recent advances in the molecular mechanisms of human and animal models of myasthenia gravis

The receptor-channel molecule is a dynamic system which exists in multiple conformations and that is the way we should think of it when we study antibody interaction with the molecule. The results presented here suggest that some antibodies may affect receptor function by occupying sites other than the receptor site. Some of these sites may by exposed only in certain conformations, and occupation of some site by antibodies may effect conformational changes. These small but perhaps important differences in cholinergic channel properties of the myasthenic muscle from the normal one are revealed by studying the effect of myasthenic sera on drug interactions with the channel sites. The sera of myasthenics are able to react with certain channel conformations and are able to affect the interaction of channel antagonists such as H12HTX and QNB. The sera appear to act preferentially with the open conformation of the channel. As a consequence of such an effect, important conformational changes of the channel may fail to occur upon activation.

Differentiation of the open and closed states of the ionic channels of nicotinic acetylcholine receptors by tricyclic antidepressants

The actions of two clinically important dibenzocycloheptane antidepressant drugs, amitriptyline and nortriptyline, were studied on ionic channels of nicotinic acetylcholine (AcCho) receptors at the neuromuscular junction of frog skeletal muscle. Amitriptyline (5-10 microM) and nortriptyline (1-2 microM), like imipramine (5-10 microM), did not react with the nicotinic AcCho receptor but caused a voltage- and time-dependent decrease in the peak amplitude of the endplate current (epc). The time constant of epc decay, however, retained its voltage sensitivity. The voltage- and time-dependent effect of amitriptyline was nonlinear with regard to the current/voltage (I/V) relationship. Nortriptyline also had a more pronounced voltage- and time-dependent effect evidenced by a hysteresis loop in the I/V relationship of the epc was eliminated by the use of 50-msec stepwise changes of the membrane potential. The nonlinearity and hysteresis were due to a time-dependent phenomenon and did not involve previous AcCho receptor activation. The rate constant of the voltage- and time-dependent decrease in epc amplitude was sensitive to the membrane electric field and varied linearly with the membrane potential. Iontophoretically elicited epcs were much more depressed by both drugs than were spontaneous miniature epcs. There was no effect on the time constant of miniature epc decay, single-channel lifetime, or conductance. Thus (as we have pointed out in our histrionicotoxin studies) the primary site of action of these agents presumably is the activated but nonconducting species of the ionic channel of the nicotinic AcCho receptor. These agents, particularly nortriptyline, point to several different binding sites of the ionic channel and are suitable tools for the separation of the effects on peak current amplitude from its time constant of decay.

Anatoxin-a interactions with cholinergic synaptic molecules

Anatoxin-a, a bicyclic amine isolated from blue-green alga, binds to the nicotinic acetylcholine receptor of Torpedo electric tissue, thereby inducing conformational changes in the postsynaptic receptor--ion channel complex as evidenced by alterations in the binding of radiolabeled ligands to the complex. Anatoxin-a binds to the acetylcholine recognition site (Kd = 0.1--0.2 microM) as indicated by its competitive inhibition of specific [3H]acetylcholine and d-[3H]tubocurarine binding, Anatoxin-a stimulates the binding of three physiologically identified "ion channel blockers," [3H]perhydrohistrionicotoxin, [3H]phencyclidine, and [3H]phencyclidine methiodide. The 50% effective doses for these effects range from 0.14 to 0.28 microM. Incubation of Torpedo membranes with anatoxin-a before addition of a radiolabeled channel probe produces a time- and concentration-dependent attenuation of the binding compared to the situation in which anatoxin-a and the probe are added simultaneously. The time course for the elaboration of this decrease corresponds to electrophysiological measurements of anatoxin-a-induced desensitization of neuromuscular junction responses. In these nicotinic actions, anatoxin-a is about as potent as acetylcholine. Anatoxin-a has relatively low affinity for the muscarinic acetylcholine receptors of rat brain, inhibiting 3-[3H]quinuclidinyl benzilate binding (10(-10) M) by 50% at concentrations between 10 and 20 microM. In contrast to classical muscarinic agonists, anatoxin-a displays little regional selectivity in its binding, and its receptor affinity is unaltered by alkylation of the neural membranes with N-ethylmaleimide.

Ultraviolet light-induced labeling by noncompetitive blockers of the acetylcholine receptor from Torpedo marmorata

Reversible ligands were attached covalently to membrane-bound acetylcholine receptor from Torpedo marmorata by a method which is generally applicable and does not require the synthesis of specially designed molecules. UV irradiation of the receptor in the presence of [3H]trimethisoquin, [3H]phencyclidine, or [3H]perhydrohistrionicotoxin resulted in the labeling of the binding site(s) for these noncompetitive blockers of the permeability response. The labeling of the delta chain was enhanced by carbamoylcholine, and this increase was blocked by snake alpha-toxins. The effect of carbamoylcholine on [3H]trimethisoquin binding was more pronounced than with the other two noncompetitive blockers; in all instances, the labeling was abolished by unlabeled histrionicotoxin. These three compounds therefore interact with the high-affinity site for noncompetitive blockers. Incorporation of radioactivity also occurred into the alpha chain but either was insensitive to cholinergic effectors or decreased in the presence of carbamoylcholine (or snake alpha-toxin), probably as a result of an interaction with the acetylcholine-binding site. In contrast to the other noncompetitive blockers tested, [3H]chlorpromazine heavily labeled the four receptor polypeptides (alpha, beta, gamma, delta), and this labeling also was enhanced by carbamoylcholine and decreased by histrionicotoxin. These data indicate a contribution of the delta chain to the binding site(s) of several well-characterized noncompetitive blockers and suggest that other receptor polypeptides may also contribute to this binding.

Dissection of the 66 000-dalton subunit of the acetylcholine receptor

The 66 000-dalton or delta subunit of the acetylcholine receptor from Torpedo marmorata was covalently labeled in the presence of carbamoylcholine by 5-azido [3H]trimethisoquin (5-A[3H]T), a photoaffinity derivative of the local anesthetic trimethisoquin. After the attack of purified receptor with increasing concentrations of trypsin, the delta chain successively yielded fragments with apparent molecular weights of 50 000 (distinct from the beta subunit and referred to as the 50 000-bis (fragment), 49 000, and 47 000. With nondenatured (sodium cholate solubilized or membrane-bound) receptor, the 47 000-dalton fragment was not sensitive to trypsin and contained all of the covalent 5-A[3H]T label. This fragment was still glycosylated and had the same amino acid N terminus, valine, as the intact delta chain. A specific in vitro phosphorylation site of the delta subunit was located between the 49 000- and 50 000-dalton trypsin cleavage fragment and most likely is exposed to the cytoplasmic side of the membrane. A 16 000-dalton fragment of the delta chain was identified, which carriers a disulfide bond (or bonds) capable of cross-linking nonreduced receptor 9S monomerse into 12S dimers. The fragment did not remain associated with the receptor molecule after trypsin treatment.

[3H]Phencyclidine: a probe for the ionic channel of the nicotinic receptor

To evaluate [3H]phencyclidine ([3H]PCP)as a probe for the ionic channel of the nicotinic receptor, the characteristics of its binding to electric organ membranes od Torpedo ocellata and its effects on frog sartorius muscle were studied. Similar to PCP, [3H]PCP depressed the peak amplitude of endplate current, caused nonlinearity in the voltage-current relationship at negative potentials, accelerated the decay time of the end-plate current, and shortened the channel lifetime. Thus, [3H]PCP interacted with the ionic channel of the nicotinic receptor, although there were a few differences between its effect and that of PCP. Binding of [3H]PCP to Torpedo membranes was to sites on the ionic channel of acetylcholine (AcCho) receptor because it was saturable, dependent upon protein concentration, and inhibited by drugs that interact with the ionic channel, and the initial rate of binding was potentiated by receptor agonists. Equilibrium binding of [3H]PCP to Torpedo membranes was with two affinities, but in the presence of AcCho, [3H]PCP binding was with a single affinity. The affinities of channel drugs obtained by inhibition of binding of [3H]PCP and [3H[perhydrohistrionicotoxin to Torpedo membranes were different, with correlation coefficients of 0.52 and 0.82 in the absence and presence of a receptor agonist, respectively; this suggests differences in their binding sites on the ionic channel of the AcCho receptor.