Activation of ion channels in the frog end-plate by high concentrations of acetylcholine

Heterogeneous conductance levels of native AMPA receptors

The single-channel properties of AMPA receptors can affect information processing in neurons by influencing the amplitude and kinetics of synaptic currents, yet little is known about the unitary properties of native AMPA receptors in situ. Using whole-cell and outside-out patch-clamp recordings from granule cells in acute cerebellar slices, we found that migrating granule cells begin to express AMPA receptors before they arrive in the internal granule cell layer and receive synaptic input. At saturating agonist concentrations, the open probability of channels in outside-out patches from migrating cells was very high, allowing us to identify patches that contained only one or two active channels. Analysis of the single-channel activity in these patches showed that individual AMPA receptors exhibit as many as four distinguishable conductance levels. The conductance levels observed varied substantially for different channels, although on average the values fell within the range of unitary conductances estimated previously for synaptic AMPA receptors. In contrast to patches from migrating granule cells, we rarely observed directly resolvable single-channel currents in patches excised from the somata of granule cells in the internal granular layer, even though these cells gave large AMPA receptor whole-cell currents. We did, however, detect AMPA receptors with apparent unitary conductances of <1 pS in patches from both migrating and mature granule cells. Our results suggest that granule cells express a heterogeneous population of AMPA receptors, a subset of which are segregated to postsynaptic sites after synaptogenesis.

Evaluation of the number of agonist molecules needed to activate a ligand-gated channel from the current rising phase

We propose a new method for calculating the number of agonist binding sites (n) in ligand-gated receptor channels from the initial phase of the current. This method is based on the fact that the relation between the current (I) and its first-time derivative (I') at the beginning of the current reflects the number of transitions that lead to channel opening. We show that, for constant agonist concentration, the above relationship at t --> 0 provides the number of steps leading to channel opening. When the agonist concentration is not constant but rather increases linearly with time, the corresponding value can be obtained using a slightly modified procedure. The analytical results were compared with computer simulations and a good match between the two was obtained. The theoretical procedure was then validated experimentally using the nicotinic receptor, because, for this receptor, the number of binding sites is well established. Indeed, the expected number of two binding sites was obtained. The method was then tested for the quisqualate-type glutamate receptor channel from the opener muscle of crayfish. The number of this receptor's binding sites is not fully resolved. Our results suggest that, for this glutamate receptor as well, two binding sites must be occupied to open the channel.

Recovery from open channel block by acetylcholine during neuromuscular transmission in zebrafish

At larval zebrafish neuromuscular junctions (NMJs), miniature end plate currents (mEPCs) recorded in vivo have an unusually fast time course. We used fast-flow application of acetylcholine (ACh) onto outside-out patches to mimic the effect of synaptic release onto small numbers of ACh receptor channels (AChRs). Positively charged ACh acted at hyperpolarized potentials and at millimolar concentrations as a fast ("flickering") open channel blocker of AChRs. Because of filtering, the open channel block resulted in reduced amplitude of single channel currents. Immediately after brief (1 msec) application (without significant desensitization) of millimolar ACh at hyperpolarized potentials, a slower, transient current appeared because of delayed reversal of the block. This rebound current depended on the ACh concentration and resembled in time course the mEPC. A simple kinetic model of the AChR that includes an open channel-blocking step accounted for our single channel results, as well as the experimentally observed slowing of the time course of mEPCs recorded at a hyperpolarized compared with a depolarized potential. Recovery from AChR block is a novel mechanism of synaptic transmission that may contribute in part at all NMJs.

Recovery from open channel block by acetylcholine during neuromuscular transmission in zebrafish

At larval zebrafish neuromuscular junctions (NMJs), miniature end plate currents (mEPCs) recorded in vivo have an unusually fast time course. We used fast-flow application of acetylcholine (ACh) onto outside-out patches to mimic the effect of synaptic release onto small numbers of ACh receptor channels (AChRs). Positively charged ACh acted at hyperpolarized potentials and at millimolar concentrations as a fast ("flickering") open channel blocker of AChRs. Because of filtering, the open channel block resulted in reduced amplitude of single channel currents. Immediately after brief (1 msec) application (without significant desensitization) of millimolar ACh at hyperpolarized potentials, a slower, transient current appeared because of delayed reversal of the block. This rebound current depended on the ACh concentration and resembled in time course the mEPC. A simple kinetic model of the AChR that includes an open channel-blocking step accounted for our single channel results, as well as the experimentally observed slowing of the time course of mEPCs recorded at a hyperpolarized compared with a depolarized potential. Recovery from AChR block is a novel mechanism of synaptic transmission that may contribute in part at all NMJs.

Strychnine activates neuronal alpha7 nicotinic receptors after mutations in the leucine ring and transmitter binding site domains

Recent work has shown that strychnine, the potent and selective antagonist of glycine receptors, is also an antagonist of nicotinic acetylcholine (AcCho) receptors including neuronal homomeric alpha7 receptors, and that mutating Leu-247 of the alpha7 nicotinic AcCho receptor-channel domain (L247Talpha7; mut1) converts some nicotinic antagonists into agonists. Therefore, a study was made of the effects of strychnine on Xenopus oocytes expressing the chick wild-type alpha7 or L247Talpha7 receptors. In these oocytes, strychnine itself did not elicit appreciable membrane currents but reduced the currents elicited by AcCho in a reversible and dose-dependent manner. In sharp contrast, in oocytes expressing L247Talpha(7) receptors with additional mutations at Cys-189 and Cys-190, in the extracellular N-terminal domain (L247T/C189-190Salpha7; mut2), micromolar concentrations of strychnine elicited inward currents that were reversibly inhibited by the nicotinic receptor blocker alpha-bungarotoxin. Single-channel recordings showed that strychnine gated mut2-channels with two conductance levels, 56 pS and 42 pS, and with kinetic properties similar to AcCho-activated channels. We conclude that strychnine is a modulator, as well as an activator, of some homomeric nicotinic alpha7 receptors. After injecting oocytes with mixtures of cDNAs encoding mut1 and mut2 subunits, the expressed hybrid receptors were activated by strychnine, similar to the mut2, and had a high affinity to AcCho like the mut1. A pentameric symmetrical model yields the striking conclusion that two identical alpha7 subunits may be sufficient to determine the functional properties of alpha7 receptors.

Single-channel properties of synaptic and extrasynaptic GABAA receptors suggest differential targeting of receptor subtypes

Many neurons express a multiplicity of GABAA receptor subunit isoforms. Despite having only a single source of inhibitory input, the cerebellar granule cell displays, at various stages of development, more than 10 different GABAA subunit types. This subunit diversity would be expected to result in significant receptor heterogeneity, yet the functional consequences of such heterogeneity remain poorly understood. Here we have used single-channel properties to characterize GABAA receptor types in the synaptic and extrasynaptic membrane of granule cells. In the presence of high concentrations of GABA, which induced receptor desensitization, extrasynaptic receptors in outside-out patches from the soma entered long-lived closed states interrupted by infrequent clusters of openings. Each cluster of openings, which is assumed to result from the repeated activation of a single channel, was to one of three main conductance states (28, 17, or 12 pS), the relative frequency of which differed between patches. Such behavior indicates the presence of at least three different receptor types. This heterogeneity was not replicated by individual recombinant receptors (alpha1beta2gamma2S or alpha1beta3gamma2S), which gave rise to clusters of a single type only. By contrast, the conductance of synaptic receptors, determined by fluctuation analysis of the synaptic current or direct resolution of channel events, was remarkably uniform and similar to the highest conductance value seen in extrasynaptic patches. These results suggest that granule cells express multiple GABAA receptor types, but only those with a high conductance, most likely containing a gamma subunit, are activated at the synapse.

Low resting potential and postnatal upregulation of NMDA receptors may cause Cajal-Retzius cell death

Using in situ patch-clamp techniques in rat telencephalic slices, we have followed resting potential (RP) properties and the functional expression of NMDA receptors in neocortical Cajal-Retzius (CR) cells from embryonic day 18 to postnatal day 13, the time around which these cells normally disappear. We find that throughout their lives CR cells have a relatively depolarized RP (approximately -50 mV), which can be made more hyperpolarized (approximately -70 mV) by stimulation of the Na/K pump with intracellular ATP. The NMDA receptors of CR cells are subjected to intense postnatal upregulation, but their similar properties (EC50, Hill number, sensitivity to antagonists, conductance, and kinetics) throughout development suggest that their subunit composition remains relatively homogeneous. The low RP of CR cells is within a range that allows for the relief of NMDA channels from Mg2+ blockade. Our findings are consistent with the hypothesis that CR cells may degenerate and die subsequent to uncontrolled overload of intracellular Ca2+ via NMDA receptor activation by ambient glutamate. In support of this hypothesis we have obtained evidence showing the protection of CR cells via in vivo blockade of NMDA receptors with dizocilpine.

Single-channel properties of synaptic and extrasynaptic GABAA receptors suggest differential targeting of receptor subtypes

Many neurons express a multiplicity of GABAA receptor subunit isoforms. Despite having only a single source of inhibitory input, the cerebellar granule cell displays, at various stages of development, more than 10 different GABAA subunit types. This subunit diversity would be expected to result in significant receptor heterogeneity, yet the functional consequences of such heterogeneity remain poorly understood. Here we have used single-channel properties to characterize GABAA receptor types in the synaptic and extrasynaptic membrane of granule cells. In the presence of high concentrations of GABA, which induced receptor desensitization, extrasynaptic receptors in outside-out patches from the soma entered long-lived closed states interrupted by infrequent clusters of openings. Each cluster of openings, which is assumed to result from the repeated activation of a single channel, was to one of three main conductance states (28, 17, or 12 pS), the relative frequency of which differed between patches. Such behavior indicates the presence of at least three different receptor types. This heterogeneity was not replicated by individual recombinant receptors (alpha1beta2gamma2S or alpha1beta3gamma2S), which gave rise to clusters of a single type only. By contrast, the conductance of synaptic receptors, determined by fluctuation analysis of the synaptic current or direct resolution of channel events, was remarkably uniform and similar to the highest conductance value seen in extrasynaptic patches. These results suggest that granule cells express multiple GABAA receptor types, but only those with a high conductance, most likely containing a gamma subunit, are activated at the synapse.

A re-examination of adult mouse nicotinic acetylcholine receptor channel activation kinetics

1. During routine sequencing of our mouse muscle alpha subunit acetylcholine receptor channel (AChR) cDNA clones, we detected a discrepancy with the GenBank database entry (accession X03986). At nucleotides 1305-7 (residue 433, in the M4 domain) the database lists GTC which encodes a valine, while our putative 'wild-type' cDNA had the nucleotides GCC, which encodes an alanine. No other sequence differences were found. 2. PCR amplification of genomic DNA confirmed that the BALB/C mouse alpha subunit gene has a T nucleotide at position 1306, and, therefore, that the protein has a V at position 433 in the M4 segment. 3. In order to determine the functional consequences of this difference, either wild-type (V433) or mutant (A433) alpha subunits were co-expressed in HEK cells with mouse beta, epsilon and delta subunits. Single-channel currents were recorded in cell-attached patches, and rate and equilibrium constants were estimated from open and closed durations obtained from a range of ACh concentrations. No significant differences were found between the activation rate constants or equilibrium constants of the V433 and A433 variants. 4. Kinetic modelling of alphaV433 AChR suggests that the two transmitter binding sites have similar dissociation equilibrium constants for acetylcholine ( approximately 160 microM in 142 mM extracellular KCl). 5. Diliganded AChRs occupy a closed state that has a lifetime of approximately 1 ms. The rate constants for entering and leaving this state do not vary with the ACh concentration. 6. The kinetics of a mutant AChR that causes a slow channel congenital myaesthenic syndrome, alphaG153S, was re-examined. The properties of this mutant were similar with a V or an A at position alpha433.

Low resting potential and postnatal upregulation of NMDA receptors may cause Cajal-Retzius cell death

Using in situ patch-clamp techniques in rat telencephalic slices, we have followed resting potential (RP) properties and the functional expression of NMDA receptors in neocortical Cajal-Retzius (CR) cells from embryonic day 18 to postnatal day 13, the time around which these cells normally disappear. We find that throughout their lives CR cells have a relatively depolarized RP (approximately -50 mV), which can be made more hyperpolarized (approximately -70 mV) by stimulation of the Na/K pump with intracellular ATP. The NMDA receptors of CR cells are subjected to intense postnatal upregulation, but their similar properties (EC50, Hill number, sensitivity to antagonists, conductance, and kinetics) throughout development suggest that their subunit composition remains relatively homogeneous. The low RP of CR cells is within a range that allows for the relief of NMDA channels from Mg2+ blockade. Our findings are consistent with the hypothesis that CR cells may degenerate and die subsequent to uncontrolled overload of intracellular Ca2+ via NMDA receptor activation by ambient glutamate. In support of this hypothesis we have obtained evidence showing the protection of CR cells via in vivo blockade of NMDA receptors with dizocilpine.

Channel opening locks agonist onto the GABAC receptor

Determination of the activation mechanism of neurotransmitter-operated ion channels has been hindered by a limited understanding of the relationship between agonist binding and the gating of the integral ion pore. Here we describe a [3H]ligand binding assay that enables us to make repeated binding measurements from the same intact oocyte expressing recombinant human rho 1 GABAC receptors and directly correlate the binding kinetics with electrophysiological measurements. We have determined an association rate for GABA of about 10(5) M-1s-1; this is four orders of magnitude slower than diffusion, indicating GABA has restricted access to its binding site. We also demonstrate that GABA dissociates at two rates. Our data are consistent with the faster rate being the true microscopic dissociation rate of GABA, with the slower rate occurring because the opening of the pore detains agonist release.

Presynaptic effects of muscarine on ACh release at the frog neuromuscular junction

1. Presynaptic effects of muscarine on neurotransmitter release were studied at the frog neuromuscular junction, using focal depolarization of the presynaptic terminal to different levels. 2. Muscarine (10 microM) had a dual effect on ACh release: concomitant inhibition and enhancement of release at the same patch of presynaptic membrane. 3. These two effects were maximal at low depolarizing pulses and diminished as depolarization increased. 4. At low depolarizing pulses, atropine (1 microM) enhanced release, suggesting that ACh in the synaptic cleft causes a net tonic inhibition of ACh release. 5. In the presence of the M2 antagonist methoctramine (1 microM), muscarine (10 microM) enhanced ACh release. 6. In the presence of the M1 antagonist pirenzepine (10 microM), muscarine (10 microM) produced stronger inhibition. 7. These results show that the M2 receptor is responsible for inhibition of ACh release, while the M1 receptor is responsible for its enhancement. 8. The inhibitory effect of muscarine did not depend on extracellular [Ca2+]. Enhancement of release was abolished at low extracellular [Ca2+]. 9. The muscarine inhibitory effect was not associated with a reduction of Ca2+ current, while release enhancement was associated with an increase of Ca2+ current.

Defining affinity with the GABAA receptor

At nicotinic and glutamatergic synapses, the duration of the postsynaptic response depends on the affinity of the receptor for transmitter (Colquhoun et al., 1977;Pan et al., 1993). Affinity is often thought to be determined by the ligand unbinding rate, whereas the binding rate is assumed to be diffusion-limited. In this view, the receptor selects for those ligands that form a stable complex on binding, but binding is uniformly fast and does not itself affect selectivity. We tested these assumptions for the GABAA receptor by dissecting the contributions of microscopic binding and unbinding kinetics for agonists of equal efficacy but of widely differing affinities. Agonist pulses applied to outside-out patches of cultured rat hippocampal neurons revealed that agonist unbinding rates could not account for affinity if diffusion-limited binding was assumed. However, direct measurement of the instantaneous competition between agonists and a competitive antagonist revealed that binding rates were orders of magnitude slower than expected for free diffusion, being more steeply correlated with affinity than were the unbinding rates. The deviation from diffusion-limited binding indicates that a ligand-specific energy barrier between the unbound and bound states determines GABAA receptor selectivity. This barrier and our kinetic observations can be quantitatively modeled by requiring the participation of movable elements within a flexible GABA binding site.

Channel-opening mechanism of a kainate-activated glutamate receptor: kinetic investigations using a laser-pulse photolysis technique

Kainate is an excitatory neurotransmitter that binds to the kainate and AMPA receptor subtypes of the glutamate receptor and triggers the formation of cation permeable transmembrane channels in these receptors. In the present report the channel-opening mechanism of the AMPA receptors by kainate has been determined in rat hippocampal neurons using two different kinetic methods, namely, the rapid-flow method (cell-flow) with a 10 ms time resolution and a laser-pulse photolysis technique with a approximately 65 microseconds time resolution. The whole-cell currents induced by kainate, using the cell-flow method, are nondesensitizing and inhibited significantly by CNQX and hence pertain to activation of the AMPA receptors and not the kainate receptors. The cell-flow measurements were used to evaluate the constants pertaining to the minimum mechanism that could account for the concentration of the receptor in the open-channel form over a 500-fold range of kainate concentration. These constants, namely, the intrinsic dissociation constant of kainate from the AMPA receptor and the channel-opening equilibrium constant, were determined to be 140 +/- 30 microM and 8 +/- 2, respectively. On the other hand, the kinetics of the steps leading to channel opening was evaluated using the laser-pulse photolysis techniques. In this technique whole-cell currents were obtained by releasing kainate in the submillisecond time scale near the cell by photolysis of N-(alpha-carboxy-2-nitrobenzyl) kainate. The concentration of the released kainate was calculated by comparing the whole-cell currents obtained from the laser-pulse photolysis experiments with the whole currents obtained with 100 microM kainate on the same cell using cell-flow measurements. The rate constants for channel opening and closing were then determined from the observed rate constants for the current rise obtained as a function of kainate concentration. These rates were 5000 +/- 2000 and 640 +/- 30 s-1, respectively. The rate and equilibrium constants obtained in the present report allow an evaluation of the fraction of the receptors in the open-channel form as a function of time and kainate concentration, hence providing insight into the role of kainate in neuronal signal transmission.

Ion channel modulation as the basis for general anesthesia

(1) Modulation of the function of the GABA(A) and neuronal nicotinic acetylcholine receptor channels caused by general anesthetics and modulation of the GABA(A) receptor-channel by halothane, enflurane, isoflurane, and n-octanol was channel state-dependent. (3) Halothane modulation of the GABA(A) receptor was independent of subunits, but n-octanol modulation was subunit-dependent. (4) Ethanol at 30-100 microM was very potent in accelerating the desensitization of currents induced by acetylcholine. (5) The ethanol modulation was subunit- and state-dependent, occurring in the alpha3beta4 combination but only weakly in the alpha3beta2 combination. (6) In contrast, halothane at 430 microM (approximately 1 MAC) potently suppressed ACh-induced currents in the alpha3beta2 subunit combination.

Defining affinity with the GABAA receptor

At nicotinic and glutamatergic synapses, the duration of the postsynaptic response depends on the affinity of the receptor for transmitter (Colquhoun et al., 1977;Pan et al., 1993). Affinity is often thought to be determined by the ligand unbinding rate, whereas the binding rate is assumed to be diffusion-limited. In this view, the receptor selects for those ligands that form a stable complex on binding, but binding is uniformly fast and does not itself affect selectivity. We tested these assumptions for the GABAA receptor by dissecting the contributions of microscopic binding and unbinding kinetics for agonists of equal efficacy but of widely differing affinities. Agonist pulses applied to outside-out patches of cultured rat hippocampal neurons revealed that agonist unbinding rates could not account for affinity if diffusion-limited binding was assumed. However, direct measurement of the instantaneous competition between agonists and a competitive antagonist revealed that binding rates were orders of magnitude slower than expected for free diffusion, being more steeply correlated with affinity than were the unbinding rates. The deviation from diffusion-limited binding indicates that a ligand-specific energy barrier between the unbound and bound states determines GABAA receptor selectivity. This barrier and our kinetic observations can be quantitatively modeled by requiring the participation of movable elements within a flexible GABA binding site.

Single channel currents at six microsecond resolution elicited by acetylcholine in mouse myoballs

1. A patch-clamp set-up was optimized for low noise and high time resolution. An Axoclamp 200B amplifier was modified to incorporate a Teflon connector to the electrode. An electrode puller was equipped with a hydrogen-oxygen burner to produce quartz-glass pipettes with optimally 0.2 micron openings and 20 MOmega resistance. 2. The r.m.s. (root mean square) noise of sealed pipettes in the bath ranged from 3.6 fA with 100 Hz filter cut-off to 1.5 pA with 61 kHz filter cut-off. At these extremes currents of 17 fA and more than 3 ms, or 9 pA and more than 6 micros could be resolved with a negligible error rate. 3. The system was tested on mouse myoballs, recording 9-10 pA single channel currents on-cell at -200 mV polarization which were elicited by 0.1-5000 microM acetylcholine (ACh). 4. Distributions of open and closed times and of correlations of open times to the preceding closed time defined several open states: single openings with mean durations of 1.2 and 25 micros, from single-liganded receptors, and bursts of 10 ms mean duration containing on average 800 micros openings and 16 micros closings, from double liganded receptors. Above 0.1 mM ACh these openings are interrupted increasingly by on average 18 micros and 72 micros channel blocks by ACh.

Kinetics of AMPA-type glutamate receptor channels in rat caudate-putamen neurones show a wide range of desensitization but distinct recovery characteristics

alpha-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)-type glutamate receptor channels of rat caudate-putamen neurones were studied by ultrafast application of agonists to outside-out vesicles taken from medium-sized spiny neurones in thin slices. Upon application of 10 mM glutamate for 50 ms, fast rising and desensitizing currents were activated. Ten to 90% rise time values were approximately 0.5 ms. Dose-response studies revealed an EC50 of 0.63 mM glutamate. In double logarithmic coordinates, the curve had a maximal slope between 1.33 and 1.85 at low concentrations, indicating at least two binding sites for glutamate. Rise time increased with low agonist concentrations, whereas desensitization kinetics showed only a weak dependence on concentration. The time constant of desensitization was fitted with one exponential and ranged between 2 and 11 ms, with a mean of 6.19+/-2.31 ms (n = 239). Following brief glutamate pulses (1 ms) currents decayed with time constants of 2.7+/-0.23 ms (n = 12). Recovery from desensitization was investigated by double-pulse experiments. Recovery time constants fell in two subgroups with respective mean values of 110.6+/-14.2 ms (n = 8) and 288.6+/-33.2 ms (n = 8). By adding low glutamate concentrations to the bath solution, predesensitization of AMPA-type receptors without channel opening could be shown. A 50% reduction in control amplitude was achieved with 5.2+/-2.1 microM (n = 22) glutamate in the background. We hypothesize a circular reaction scheme with at least two binding sites for glutamate to describe activation, desensitization and recovery from desensitization in rat caudate-putamen neurones.

Transient low-affinity agonist binding to Torpedo postsynaptic membranes resolved by using sequential mixing stopped-flow fluorescence spectroscopy

We have detected the binding of the fluorescent agonist Dns-C6-Cho to both low- and high-affinity states of the nicotinic acetylcholine receptor (nAcChoR) using sequential mixing stopped-flow fluorescence spectroscopy. Our approach to resolving low- and high-affinity binding was to first preincubate receptor membranes with the fluorescent partial agonist Dns-C6-Cho for 15 ms to 1000 s and then to follow the fluorescence decay upon chemical dilution into excess acetylcholine. The fast and slow decays, reflecting Dns-C6-Cho dissociation from low- and high-affinity receptors, had rates of 140 +/- 27 s-1 and 0.1 +/- 0.02 s-1, respectively. With increasing preincubation times, the number of low-affinity receptors decreased while the number of high-affinity receptors increased in a Dns-C6-Cho concentration-dependent manner consistent with current models for agonist-induced affinity state conversion. At receptor-activating concentrations of Dns-C6-Cho, the apparent rates with which high-affinity receptors formed approximated those of ion flux desensitization, implying that the fast desensitized state has an agonist dissociation rate that is indistinguishable from the equilibrium slow desensitized state. The KD for the low-affinity binding site was determined to be 1.1 microM from the increase in the amplitude of the fast decay with Dns-C6-Cho concentration with preincubation times that were sufficiently brief to minimize affinity state conversion. Assuming a bimolecular association rate of 10(8) M-1 s-1, a second estimate of 1.4 microM was made for low-affinity binding. We also detected a fluorescence enhancement consistent with a conformational isomerization of Dns-C6-Cho-inhibited nAcChoRs.

Topology of ligand binding sites on the nicotinic acetylcholine receptor

The nicotinic acetylcholine receptor (AChR) presents two very well differentiated domains for ligand binding that account for different cholinergic properties. In the hydrophilic extracellular region of both alpha subunits there exist the binding sites for agonists such as the neurotransmitter acetylcholine (ACh) and for competitive antagonists such as d-tubocurarine. Agonists trigger the channel opening upon binding while competitive antagonists compete for the former ones and inhibit its pharmacological action. Identification of all residues involved in recognition and binding of agonist and competitive antagonists is a primary objective in order to understand which structural components are related to the physiological function of the AChR. The picture for the localisation of the agonist/competitive antagonist binding sites is now clearer in the light of newer and better experimental evidence. These sites are mainly located on both alpha subunits in a pocket approximately 30-35 A above the surface membrane. Since both alpha subunits are sequentially identical, the observed high and low affinity for agonists on the receptor is conditioned by the interaction of the alpha subunit with the delta or the gamma chain, respectively. This relationship is opposite for curare-related drugs. This molecular interaction takes place probably at the interface formed by the different subunits. The principal component for the agonist/competitive antagonist binding sites involves several aromatic residues, in addition to the cysteine pair at 192-193, in three loops-forming binding domains (loops A-C). Other residues such as the negatively changed aspartates and glutamates (loop D), Thr or Tyr (loop E), and Trp (loop F) from non-alpha subunits were also found to form the complementary component of the agonist/competitive antagonist binding sites. Neurotoxins such as alpha-, kappa-bungarotoxin and several alpha-conotoxins seem to partially overlap with the agonist/competitive antagonist binding sites at multiple point of contacts. The alpha subunits also carry the binding site for certain acetylcholinesterase inhibitors such as eserine and for the neurotransmitter 5-hydroxytryptamine which activate the receptor without interacting with the classical agonist binding sites. The link between specific subunits by means of the binding of ACh molecules might play a pivotal role in the relative shift among receptor subunits. This conformational change would allow for the opening of the intrinsic receptor cation channel transducting the external chemical signal elicited by the agonist into membrane depolarisation. The ion flux activity can be inhibited by non-competitive inhibitors (NCIs). For this kind of drugs, a population of low-affinity binding sites has been found at the lipid-protein interface of the AChR. In addition, several high-affinity binding sites have been found to be located at different rings on the M2 transmembrane domain, namely luminal binding sites. In this regard, the serine ring is the locus for exogenous NCIs such as chlorpromazine, triphenylmethylphosphonium, the local anaesthetic QX-222, phencyclidine, and trifluoromethyliodophenyldiazirine. Trifluoromethyliodophenyldiazirine also binds to the valine ring, which is the postulated site for cembranoids. Additionally, the local anaesthetic meproadifen binding site seems to be located at the outer or extracellular ring. Interestingly, the M2 domain is also the locus for endogenous NCIs such as the neuropeptide substance P and the neurotransmitter 5-hydroxytryptamine. In contrast with this fact, experimental evidence supports the hypothesis for the existence of other NCI high-affinity binding sites located not at the channel lumen but at non-luminal binding domains. (ABSTRACT TRUNCATED)

Control of rat GluR6 glutamate receptor open probability by protein kinase A and calcineurin

1. We have used non-stationary variance analysis to examine the single channel conductance and the probability of channel opening at the peak of the homomeric GluR6 response (Po,peak) to 100-200 ms application (10-90% exchange time, 0.3 ms) of glutamate onto excised membrane patches from transiently transfected human embryonic kidney cells (HEK 293). 2. Our determinations of both Po,peak and single channel conductance of simulated current responses are insensitive to system filtering, response rise time, desensitization rate and measured variation in our drug perfusion speed. Isolation of stochastic current fluctuations using the local mean response waveform minimizes problems associated with modest rundown of response amplitude during the experiment. 3. The slope conductance calculated from the weighted mean unitary currents for the channels activated in response to glutamate application is 16 pS. Chord conductance between-40 and -80 mV is independent of agonist concentration. Conversion of the codon for glutamine621 to arginine (Q621R) by RNA editing reduces conductance by more than 35-fold to less than 0.4 pS without changing response time course, desensitization, or Po,peak. 4. Po,peak is high at saturating glutamate concentrations (0.65 +/- 0.23; mean +/- S.D.) and varies with agonist concentrations. The half-maximally effective glutamate concentration (EC50) determined for Po,peak (0.2 mM; Hill slope = 0.6) is similar to that determined for the macroscopic peak current amplitude (0.5 mM; Hill slope = 1.0) in response to rapid agonist application. 5. Inclusion of the purified catalytic subunit of cAMP-dependent protein kinase A (PKA) in the patch pipette increases Po,peak to 0.85 +/- 0.12 and co-transfection of cells with a cDNA encoding the catalytic subunit of PKA (C alpha-PKA) increases Po,peak to 0.94 +/- 0.09. 6. Inclusion of purified calcineurin plus its coactivators 200 nM Ca2+ and calmodulin in the patch pipette decreases Po,peak to 0.48 +/- 0.10. The calcineurin-stimulated decrease of Po,peak in cells co-transfected with C alpha-PKA is blocked by 800 nM deltamethrin, a calcineurin inhibitor. Calmodulin, 200 nM Ca2+ and deltamethrin have no effect on Po,peak in the absence of calcineurin. As predicted from its effects on Po,peak, inclusion of calcineurin in the patch pipette accelerates the run-down of whole cell GluR6 responses in cells co-transfected with C alpha-PKA. 7. The effects of both calcineurin and PKA on Po,peak for GluR6 receptors in excised patches occur without any detectable changes to response time course, desensitization, or chord conductance. 8. We conclude that the binding of glutamate to homomeric GluR6 receptors is associated with a high probability of channel opening, which is under the control of two signalling systems that are known to be co-localized at the neuronal membrane: PKA (Po,peak near 1.0) and calcineurin (Po,peak near 0.5).

Neuronal nicotinic threonine-for-leucine 247 alpha7 mutant receptors show different gating kinetics when activated by acetylcholine or by the noncompetitive agonist 5-hydroxytryptamine

Mutation of the highly conserved leucine residue (Leu-247) converts 5-hydroxytryptamine (5HT) from an antagonist into an agonist of neuronal homomeric alpha7 nicotinic acetylcholine receptor expressed in Xenopus oocytes. We show here that acetylcholine (AcCho) activates two classes of single channels with conductances of 44 pS and 58 pS, similar to those activated by 5HT. However, the mean open time of AcCho-gated ion channels (11 ms) is briefer than that of 5HT-gated ion channels (18 ms). Furthermore, whereas the open time of AcCho channels lengthens with hyperpolarization, that of 5HT channels is decreased. In voltage-clamped oocytes, the apparent affinity of the alpha7 mutant receptor for 5HT is not modified by the presence of dihydro-beta-erythroidine, which acts on the AcCho binding site in a competitive manner. This indicates a noncompetitive action of 5HT on nicotinic acetylcholine receptors. Considered together, our findings show that AcCho gates alpha7 mutant channels with similar conductance but with different kinetic profile than the channels gated by 5HT, suggesting that the two agonists act on different docking sites. These results will help to understand the crosstalk between cholinergic and serotonergic systems in the central nervous system.

Nicotinic acetylcholine sensitivity of rat petrosal sensory neurons in dissociated cell culture

Using whole-cell, patch-clamp techniques we investigated acetylcholine (ACh) sensitivity of dissociated sensory neurons from rat petrosal ganglia after 4 h-14 days in vitro. In approx. 68% of petrosal neurons (PN; n = 109) ACh, applied by fast perfusion or pressure ejection from a 'puffer' pipette, caused a rapid depolarization associated with a conductance increase. Under voltage clamp near the resting potential (approx. - 60 mV), ACh induced a hexamethonium-sensitive, inward current (IACh), mimicked by nicotine application, suggesting the presence of neuronal nicotinic acetylcholine receptors (nAChR). The reversal potential of IACh occurred near 0 mV (n = 4), a region where the I-V curve displayed a prominent rectification. The dose-response relation for IACh versus ACh concentration was fitted by the Hill equation with EC50 = approx. 33.9 microM and Hill coefficient = approx. 1.6. The activation phase of IACh was well fitted by a single exponential with mean (+/- S.E.M.) time constant of 102 +/- 82 ms (n = 6); the desensitization phase of IACh was best fitted by the sum of two exponentials, with time constant of 870 +/- 210 ms (n = 6) and 8576 +/- 1435 ms (at -70 mV). Fluctuation analysis yielded an apparent single-channel conductance of 21.6 +/- 10 pS (mean +/- S.E.M.; n = 4). These data indicate that a major subpopulation of sensory neurons in visceral petrosal ganglia of the rat express nAChR. Thus, if similar receptors are present on corresponding nerve terminals, they could mediate fast afferent excitation in response to ACh released at peripheral targets, e.g., the chemosensory carotid body.

Mouse-Torpedo chimeric alpha-subunit used to probe channel-gating determinants on the nicotinic acetylcholine receptor primary sequence

1. To determine if structural domains are important for nicotinic acetylcholine receptor (nAChr) channel function, six mouse-Torpedo chimeric alpha-subunits were constructed (Fig. 2) and coexpressed with Torpedo californica beta-, gamma-, and delta-subunits in Xenopus laevis oocytes. 2. nAChRs containing a chimeric alpha-subunit were examined by voltage- and patch-clamp methods to determine their functional characteristics. Dose-response curves from voltage-clamped oocytes were used to estimate EC50's and Hill coefficients. Whole-cell currents were normalized against the alpha-bungarotoxin (alpha-BTX) binding sites to obtain normalized responses to acetylcholine (ACh). Open time constants at 4 microM ACh were used to examine single-channel behavior. 3. The EC50 for ACh was modulated by the N-terminal half of the alpha-subunit. When the Torpedo subunit sequence between position 1 and position 268 was replaced by mouse sequence, the EC50 shifted toward the value for the wild-type mouse subunit. Replacement of either the 1-159 or the 160-268 positions of the Torpedo sequence with the mouse sequence lowered the EC50. This suggests that at least two regions play a role in determining the EC50. 4. When the primary sequence (160-268) of the Torpedo alpha-subunit was introduced in the mouse alpha-subunit (T160-268), the expressed chimeric receptor was nonfunctional. The inverse chimera (M160-268) was functional and the open time constant and EC50 were similar to those of mouse but the normalized response was characteristic of Torpedo. 5. The normalized macroscopic response to ACh (300 microM) of the chimera containing the mouse alpha-subunit showed a ninefold increase relative to the Torpedo wild type. Receptors which contain the C terminal of the mouse alpha-subunit also show an increase in the maximum normalized current. Receptors with the alpha-subunit which contain the Torpedo C-terminal sequence have a lower normalized response. 6. The combined results suggest that AChR channel function is modulated by structural determinants within the primary sequence. These structural domains might modulate channel function through specific allosteric interactions. The lack of response of the T160-268 chimera suggests that a critical interaction essential for the coupling of agonist binding and channel gating was disrupted. This result suggests that the interaction of structural domains within the nAChR primary structure are essential for channel function and that these intractions could be very specific within different nAChR species.

Kinetics of NMDA channel opening

The period required for NMDA channels to open for the first time after agonist binding (the first latency) was estimated in outside-out patch recordings from rat hippocampal neurons using fast-application techniques and the open channel blocker MK-801. In the presence of MK-801, brief applications of L-glutamate or the low-affinity agonist L-cysteate resulted in a similar amount of block despite the much shorter period of channel activation by L-cysteate. A brief coapplication of L-glutamate and MK-801 resulted in a block similar to that found with an application of L-glutamate in a background of MK-801. These results, along with our findings that MK-801 does not block desensitized receptors, indicate that NMDA channels have a mean first latency of approximately 10 msec, consistent with a peak open probability near 0.3. If NMDA channels at synapses behave similarly, relatively few channels would be required to produce the postsynaptic calcium transient associated with synaptic plasticity and developmental regulation.

Stoichiometry of a recombinant GABAA receptor

GABA is the main inhibitory neurotransmitter in the mammalian brain. The postsynaptic GABAA receptor/pore complex is presumed to be a pentamer typically composed of a combination of alpha, beta, and gamma subunits, although the stoichiometry remains controversial. We probed the stoichiometry of the GABAA receptor by site-directed mutagenesis of a conserved leucine (to serine) in the putative second membrane-spanning domain of the rat alpha 1(alpha L263S), beta 2(alpha L259S), and gamma 2(alpha L274S) subunit isoforms. Coexpression of wild-type and mutant subunits of each class (e.g., alpha and alpha L263S), along with their wild-type counter-parts (e.g., beta and gamma), in Xenopus laevis oocytes resulted in mixed populations of receptors with distinct GABA sensitivities. This is consistent with the interpretation that the leucine mutation increased the GABA sensitivity in proportion to the number of incorporated mutant subunits. The apparent number of incorporated subunits for each class (alpha, beta, and gamma) could then be determined from the number of components comprising the compound GABA dose-response relationships. Using this approach, we conclude that the recombinant alpha 1 beta 2 gamma 2 GABAA receptor is a pentamer composed of two alpha subunits, two beta subunits, and one gamma subunit.

Tryptophan substitutions at the lipid-exposed transmembrane segment M4 of Torpedo californica acetylcholine receptor govern channel gating

Our previous amino acid substitutions at the postulated lipid-exposed transmembrane segment M4 of the Torpedo californica acetylcholine receptor (AChR) focused on the alpha C418 position. A tryptophan substitution on the alpha C418 produced a 3-fold increase in normalized macroscopic response to acetylcholine in voltage-clamped Xenopus laevis oocytes (Lee et al., 1994). This result was explained by a 23-fold decrease in the closing rate constant measured from single-channel analysis (Ortiz-Miranda et al., 1996). In this study, we introduce more tryptophan substitutions at different positions of this postulated lipid-exposed segment M4 in order to examine functional consequences at the single-channel level. From a series of amino acid substitutions at alpha G421, only phenylalanine and tryptophan produced a substantial increase in the open time constant. The lack of response from a tyrosine substitution at the alpha G421 suggests that the side chain volume is not the main structural element responsible for the effect of tryptophan on the stabilization of the open state of the channel. Three multiple mutants, alpha C418W/G421A, alpha C418W/G421W, and alpha C418W/beta C447W, were constructed in order to establish the correlation between the number of lipid-exposed tryptophans and the channel open time constant. The alpha C418W/G421A double mutant demonstrated that when both previous mutations are combined the open time constant was increased 1.5-fold relative to the alpha C418W. When the two mutants (alpha C418W and alpha G421W) were combined in a single mutation, a functional receptor was expressed and the open time constant of the new double mutant increased to 33.4 ms, an 80-fold increase relative to wild type. Estimations of free energy changes calculated from the rate constant for the opening transition suggest that each tryptophan contributes to the stabilization of the open state of the channel by about 0.8 kcal/mol, and the effect of tryptophan substitutions on the free energy is additive. This result suggests that in the channel gating mechanism of the AChR, each subunit contributes independently to the energy barrier between the open and closed state. At selected positions within the postulated lipid surface of the AChR, tryptophan substitutions could establish hydrophobic and perhaps dipole interactions that may play a dramatic role in the channel gating mechanism.

Fading and rebound of currents induced by ATP in PC12 cells

1. Patch clamp recording (whole cell configuration) was used to study the action of ATP on rat phaeochromocytoma (PC12) cells usually held at -70 mV and rapidly superfused with buffered saline. ATP (0.5, 1 or 5 mM), applied from micropipettes by pressure application with brief (< or = 50 ms) pulses, induced inward currents with rapid onset and decay. ADP and alpha, beta-methylene ATP were ineffective. 2. ATP (5 mM) applied with pulses > 200 ms long elicited a complex current response characterized by a rapid peak which faded and was followed by a strong current rebound (lasting several s) as soon as the application was terminated. This type of response was readily replicated as long as ATP applications were spaced at 2-3 min intervals. The amplitude of peak and rebound currents was dependent on the length of pressure pulse and was similarly depressed by bath application of a threshold dose (25 microM) of ATP. Rapid fading and rebound of ATP-induced membrane currents were also observed when the Y-tube method was used for applying this agonist. 3. The reversal potential for peak and rebound currents was the same while the time constant values for peak fading and rebound onset were insensitive to changes in membrane potential between -70 and -40 mV. When ATP was applied to a cell clamped at depolarized potential, no current was observed but rapid return of the membrane potential to -70 mV immediately at the end of ATP application was associated with a large rebound current. 4. Brief (20 ms) application of ATP during the onset of the rebound current strongly and transiently suppressed it. The same application performed during the gradual decay of the rebound wave elicited a transient inward current which was much smaller and shorter than the one observed when the cell was in its resting state. Application of 2 s ATP pulses at 20 s intervals equally reduced the initial peak and rebound currents which recovered at the same rate. 5. The present data are interpreted according to a scheme which suggests two types of ATP receptor desensitization. The first one (D1) would be characterized by fast kinetics and low agonist affinity; rapid recovery from D1 would then be manifested as current rebound presumably due to receptor reactivation. The second desensitized state (D2) has slow kinetics and high affinity for the agonist: it is therefore typically seen with sustained application of a low dose of ATP. It is proposed that desensitization and its recovery can influence the time course of membrane responses mediated by purinoceptors.

Kinetics of homomeric GluR6 glutamate receptor channels

We studied the kinetics of the unedited version of rat GluR6 glutamate (glu) receptor channels, GluR6Q, in outside-out patches using a system for submillisecond solution exchange. Half-maximum activation of the channels was reached with approximately 0.5 microM glu. The maximum slope of the double-logarithmic plot of the peak current versus glu was approximately 1.3, indicating that at least two binding steps are necessary to open the channels. Currents in response to a pulse of 10 microM glu had a short rise time (10-90% of peak current) of approximately 220 microseconds at approximately 20 degrees C. The rise time increased with falling glu concentration, reaching approximately 6.0 ms with 10 microM glu. In the continued presence of glu, the channels desensitized, and this desensitization can be described with a single time constant of approximately 7.0 ms for a pulse of 10 microM glu. The steady-state current in response to a long pulse of 10 microM glu was below 1/280th of the peak current. The time constant of desensitization was found to be independent of concentration between 30.0 and 0.3 microM glu, but to be increased for lower concentrations. After a short pulse of 1 ms duration and 10 or 0.3 microM glu, currents decayed with a time constant of approximately 2.5 ms. Recovery from desensitization after a pulse took approximately 5 s, and the half-time of recovery was approximately 2.2 s. Continuous application of low concentrations of glutamate reduced the peak currents in response to a pulse of 10 microM glu markedly. Fifty percent response reduction was observed in the continuous presence of approximately 0.3 microM glu. Our results for homomeric GluR6 agree with a cyclical reaction scheme developed for completely desensitizing, glu-activated channels on crayfish muscles.

Activation kinetics of glutamate receptor channels from wild-type Drosophila muscle

Outside-out patches from wild-type Drosophila larval muscle were exposed briefly to L-Glutamate (Glu) using a piezo-driven application system. Glu in concentrations of 0.1 to 30 mM was applied and the responses to repeated applications of a given concentration were averaged. The peak current, î, and the current rise time, tr, from 0.1 î to 0.9 î were determined from the averages. Half-maximum activation of the channels was reached with approximately 2 mM Glu. î increased proportional to the power n = 3. 5 to n = 5.8 (average of four experiments, n = 4.4) for Glu concentrations between 0.3 and 0.5 mM. tr increased from approximately 0.2 ms at 10 mM Glu to a value of approximately 3.5 ms at 0.2 mM Glu. A linear reaction scheme with five binding steps preceding the channel-opening conformational change is proposed as the kinetic mechanism of channel activation and investigated in computer simulations. A set of rate constants assuming the same affinity for each binding site is found to describe the data better than one assuming positive cooperativity. The results are very similar to those for Glu-gated channels of crayfish and locust muscle, which is evidence for a common kinetic mechanism of these channels.

Ion channel properties of a protein complex with characteristics of a glutamate/N-methyl-D-aspartate receptor

The functional reconstitution of glutamate receptor proteins purified from mammalian brain has been difficult to accomplish. However, channels activated by L-glutamate (L-Glu) and N-methyl-D-aspartate (NMDA) were detected in planar lipid bilayer membranes (PLMs) following the reconstitution of a complex of proteins with binding sites for NMDA receptor (NMDAR) ligands. The presence of glycine was necessary for optimal activation. A linear current-voltage relationship was observed with the reversal potential being zero. Channels activated by L-Glu had conductances of 23, 47 and 65 pS, and were suppressed partially by competitive and fully by noncompetitive inhibitors of NMDARs. Magnesium had little effect on the reconstituted channels.

Stoichiometry of a recombinant GABAA receptor

GABA is the main inhibitory neurotransmitter in the mammalian brain. The postsynaptic GABAA receptor/pore complex is presumed to be a pentamer typically composed of a combination of alpha, beta, and gamma subunits, although the stoichiometry remains controversial. We probed the stoichiometry of the GABAA receptor by site-directed mutagenesis of a conserved leucine (to serine) in the putative second membrane-spanning domain of the rat alpha 1(alpha L263S), beta 2(alpha L259S), and gamma 2(alpha L274S) subunit isoforms. Coexpression of wild-type and mutant subunits of each class (e.g., alpha and alpha L263S), along with their wild-type counter-parts (e.g., beta and gamma), in Xenopus laevis oocytes resulted in mixed populations of receptors with distinct GABA sensitivities. This is consistent with the interpretation that the leucine mutation increased the GABA sensitivity in proportion to the number of incorporated mutant subunits. The apparent number of incorporated subunits for each class (alpha, beta, and gamma) could then be determined from the number of components comprising the compound GABA dose-response relationships. Using this approach, we conclude that the recombinant alpha 1 beta 2 gamma 2 GABAA receptor is a pentamer composed of two alpha subunits, two beta subunits, and one gamma subunit.

An evaluation of neuronal nicotinic acetylcholine receptor activation by quaternary nitrogen compounds indicates that choline is selective for the alpha 7 subtype

The agonist properties of acetylcholine (ACh), tetramethylammonium, ethyl-trimethylammonium and choline were evaluated for muscle and neuronal nicotinic receptors in Xenopus oocytes. The only essential feature for a neuronal receptor agonist appears to be the charged nitrogen. For specific receptor subtypes, other structural elements appear permissive (neither increasing nor decreasing activity) or non-permissive (decreasing activity). Choline was a full agonist for alpha 7, but a hydroxyl group was strongly non-permissive for other receptor subtypes (alpha 1 beta 1 gamma delta, alpha 3 beta 4, alpha 3 beta 2, and alpha 4 beta 2). The binding of these ligands to brain membranes is consistent with the electrophysiological results. Physiological concentrations of choline desensitize alpha 7 receptors to ACh suggesting that, in vivo, choline may regulate both the activation and inactivation of this receptor.

Alpha-bungarotoxin-sensitive nicotinic responses in rat tuberomammillary neurons

Application of acetylcholine (ACh), nicotine or 1, 1-dimethyl-4-phenylpiperazinium elicited an inward current in histaminergic neurons of the tuberomammillary nucleus. These responses were blocked by 25-50 nM alpha-bungarotoxin. Acutely dissociated neurons from the tuberomammillary nucleus displayed fast, desensitizing responses to ACh. ACh-activated currents exhibited rectification at positive membrane potentials. The Hill coefficient and half-maximally effective concentration (EC50) for ACh were 1.85 and 119 microM, respectively. Desensitization could be fitted by an exponential. Preincubation in low concentrations of ACh diminished subsequent responses to higher concentrations of ACh. The alpha-bungarotoxin sensitivity in conjunction with the low potency of ACh at this receptor are consistent with its identification as an alpha7-subunit-containing receptor. These alpha-bungarotoxin-sensitive receptors are ligand-gated cationic channels which are not thought to play a role in synaptic transmission, but they may be an important site for central actions of nicotine.

Kinetics of NMDA channel opening

The period required for NMDA channels to open for the first time after agonist binding (the first latency) was estimated in outside-out patch recordings from rat hippocampal neurons using fast-application techniques and the open channel blocker MK-801. In the presence of MK-801, brief applications of L-glutamate or the low-affinity agonist L-cysteate resulted in a similar amount of block despite the much shorter period of channel activation by L-cysteate. A brief coapplication of L-glutamate and MK-801 resulted in a block similar to that found with an application of L-glutamate in a background of MK-801. These results, along with our findings that MK-801 does not block desensitized receptors, indicate that NMDA channels have a mean first latency of approximately 10 msec, consistent with a peak open probability near 0.3. If NMDA channels at synapses behave similarly, relatively few channels would be required to produce the postsynaptic calcium transient associated with synaptic plasticity and developmental regulation.

Activation and cooperative multi-ion block of single nicotinic-acetylcholine channel currents of Ascaris muscle by the tetrahydropyrimidine anthelmintic, morantel

1. We have investigated activation and block, by the tetrahydropyrimidine anthelmintic, morantel, of nicotinic-acetylcholine receptor (AChR) currents in membrane vesicles isolated from somatic muscle cells of the nematode parasite Ascaris suum. Standard single-channel recording techniques were employed. Morantel in the pipette (6 nM to 600 microM), activated single nicotinic AChR currents. 2. Kinetic properties of the main-conductance state of morantel-activated currents were investigated in detail throughout the concentration range, 0.6 microM to 600 microM. Open-time distributions were best fitted by a single exponential. Mean open-times were slightly voltage-dependent, increasing from 0.9 ms at +75 mV to 1.74 ms at -75 mV in the presence of 0.6 microM morantel. At low concentrations, closed-time distributions were best fitted by the sum of two or three exponential components. 3. As the concentration of morantel was increased (100-600 microM), fast-flickering open channel-block was observed at positive potentials, even though morantel, a cation, was only present at the extracellular surface of the membrane. The block rate was dependent on morantel concentration and both block rate and duration of block increased as the potential became less positive. A simple channel-block mechanism did not explain properties of this block. 4. At negative potentials, as the morantel concentration increased, a complex block was observed. With increases in morantel concentration two additional gap components appeared in closed-time distributions: one was short with a duration (approximately 13 ms) independent of morantel concentration; the other was long with a duration that increased with morantel concentration (up to many minutes). In combination, these two components produced a marked reduction in probability of channel opening (Po) with increasing morantel concentration. The relationship between the degrees of block and morantel concentration had a Hill coefficient of 1.6, suggesting the involvement of at least two blocking molecules. The data were analysed by use of a simple sequential double block kinetic model.

Agonist self-inhibitory binding site of the nicotinic acetylcholine receptor

A major focus of current research on the nicotinic acetylcholine receptor (AChR) has been to understand the molecular mechanism of ion channel inhibition. In particular, we put special emphasis on the description of the localization of the agonist self-inhibitory binding site. Binding of agonist in the millimolar concentration range to this particular site produces inhibition of the ion flux activity previously elicited by the same agonist at micromolar concentrations. Due to the similitude in the pharmacological and electrophysiological behavior in inhibiting the ion channel of both high agonist concentrations and noncompetitive antagonists, we first describe the localization of noncompetitive inhibitor binding sites on the AChR. There is a great body of experimental evidence for the existence and location of luminal high-affinity noncompetitive inhibitor binding sites. In this regard, the most simple mechanism to describe the action of noncompetitive inhibitors which bind to luminal sites and, by its semblance, the agonist self-inhibition itself, is based on the assumption that these compounds enter the open channel, bind to different rings within the M2 transmembrane domain of the receptor, and block cation flux by occluding the receptor pore. However, the existence of high-affinity nonluminal noncompetitive inhibitor binding sites is not consistent with the open-channel-blocking mechanism. Instead, the presence of the quinacrine locus at the lipid-protein (alpha M1) interface approximately 7 A from the lipid-water interface and the ethidium domain located approximately 46 A from the membrane surface in the wall of the vestibule open the possibility for the regulation of cation permeation by an allosteric process. Additionally, the observed (at least partially) overlapping between the quinacrine and the agonist self-inhibitory binding site also suggests an allosteric process for agonist self-inhibition. For this alternative mechanism, cholinergic agonist molecules first need to be partitioned into (or to be adsorbed onto) the lipid membrane to further interact with its binding site located at the lipid-protein interface.

Insights into the activation mechanism of rho1 GABA receptors obtained by coexpression of wild type and activation-impaired subunits

To gain insight into the activation mechanism of homomeric ligand-gated receptor-channels, we examined human homomeric rho1 GABA receptors with fewer than the normal number of agonist binding sites. This was accomplished by coexpressing different ratios of wild type and activation-impaired rho1 subunits. Dose-response relations from oocytes coexpressing wild type and mutant subunits were comprised of two components in terms of GABA sensitivity; one 'wild type'-like and the other 'mutant'-like. Applying the binomial hypothesis to subunit coassembly enabled use to correlate these two components of the GABA dose-response relations to the underlying chimaeric receptor subtypes. We demonstrate that the receptors activate near normal provided that they are comprised of at least three wild type subunits. Our data are consistent with five equivalent and independent GABA binding sites of which only three need bind GABA to open the pore. The two additional binding sites may increase the GABA sensitivity of the rho1 receptor and, when bound by agonist, stabilize the open state.

Effects of the quinoline derivatives quinine, quinidine, and chloroquine on neuromuscular transmission

The quinoline derivatives quinine, its stereoisomer quinidine, and chloroquine may worsen or provoke disorders of neuromuscular transmission. In this study, we investigate effects of these drugs on neuromuscular transmission by conventional microelectrode as well as patch-clamp techniques. At 5 x 10(-5) M, quinine, quinidine, and chloroquine reduced the quantal content of the end-plate potential by 37-45%. Between 10(-6) and 10(-4) M, all 3 drugs progressively decreased the amplitude and decay time constant of miniature end-plate potential (MEPP) and miniature end-plate current (MEPC); at 5 x 10(-3) M, the MEPP became undetectable. The effect on the MEPP was not reversed by 1 microgram/mL neostigmine. Single-channel patch-clamp analysis of the effects of quinine showed that this agent causes a long-lived open-channel as well as a closed-channel block of AChR. Tests for competitive inhibition or desensitization of the acetylcholine receptor (AChR) by quinine in concentrations that had a marked effect on the MEPC and on single-channel open and closed intervals were negative. Because quinoline drugs adversely affect both presynaptic and postsynaptic aspects of neuromuscular transmission at concentrations close to those employed in clinical practice, they should not be used, or used with caution, in disorders that compromise the safety margin of neuromuscular transmission.

Agonist-induced displacement of quinacrine from its binding site on the nicotinic acetylcholine receptor: plausible agonist membrane partitioning mechanism

It was previously demonstrated that high concentrations of cholinergic agonists such as acetylcholine (ACh), carbamylcholine (CCh), suberyldicholine (SubCh) and spin-labelled acetylcholine (SL-ACh) displaced quinacrine from its high-affinity binding site located at the lipid-protein interface of the nicotinic acetylcholine receptor (AChR) (Anas, H. R. and Johnson, D. A. (1995) Biochemistry, 34, 1589-1595). In order to account for the agonist self-inhibitory binding site which overlaps, at least partially, with the quinacrine binding site, we determined the partition coefficient (Kp) of these agonists relative to the local anaesthetic tetracaine in AChR native membranes from Torpedo californica electric organ by examining (1) the ability of tetracaine and SL-ACh to quench membrane-partitioned 1-pyrenedecanoic acid (C10-Py) monomer fluorescence, and (2) the ability of ACh, CCh and SubCh to induce an increase in the excimer/monomer ratio of C10-Py-labelled AChR membrane fluorescence. To further assess the differences in agonist accessibility to the quinacrine binding site, we calculated the agonist concentration in the lipid membrane (CM) at an external agonist concentration high enough to inhibit 50% of quinacrine binding (IC50), which in turn was obtained by agonist back titration of AChR-bound quinacrine. Initial experiments established that high agonist concentrations do not affect either transmembrane proton concentration equilibria (pH) of AChR membrane suspension or AChR-bound quinacrine fluorescence spectra. The agonist membrane partitioning experiments indicated relatively small (< or = 20) Kp values relative to tetracaine. These values follow the order: SL-ACh>SubCh>>CCh-ACh. A direct correlation was observed between Kp and the apparent inhibition constant (Ki) for agonists to displace AChR-bound quinacrine. Particularly, agonist with high KpS such as SL-ACh and SubCh showed low Ki values, and this relationship was opposite for CCh and ACh. The calculated CM values indicated significant (between 7 and 54 mM) agonist accessibility to lipid membrane. By themselves, these results support the conjecture that agonist self-inhibition seems to be mediated by the quinacrine binding site via a membrane approach mechanism. The existence of an agonist self-inhibitory binding site, not located in the channel lumen would indicate an allosteric mechanism of ion channel inhibition; however, we can not discard that the process of agonist self-inhibition can also be mediated by a steric blockage of the ion channel.

Quantal transmission at purinergic junctions: stochastic interaction between ATP and its receptors

The time course of most quantal currents recorded with a small diameter electrode placed over visualized varicosities of sympathetic nerve terminals that secrete ATP was determined: these had a time to reach 90% of peak of 1.3-1.8 ms and a time constant of decay of 12-18 ms; they were unaffected by blocking ectoenzymes or the uptake of adenosine. Monte Carlo methods were used to analyze the stochastic interaction between ATP, released in a packet from a varicosity, and the underlying patch of purinoceptors, to reconstitute the time course of the quantal current. This leads to certain restrictions on the possible number of ATP molecules in a quantum (about 1000) and the density of purinoceptors at the junctions (about 1000 microns-1), given the known geometry of the junction and the kinetics of ATP action. The observed quantal current has a relatively small variability (coefficient of variation < 0.1), and this stochastic property is reproduced for a given quantum of ATP. Potentiation effects (of about 12%) occur if two quanta are released from the same varicosity because the receptor patch is not saturated even by the release of two quanta. The simulations show that quantal currents have a characteristically distinct shape for varicosities with different junctional cleft widths (50-200 nm). Finally, incorporation of an ectoenzyme with the known kinetics of ATPase into the junctional cleft allows for a quantal current of the observed time course, provided the number of ATP molecules in a quantum is increased over the number in the absence of the ATPase.

Acetylcholine receptor channel imaged in the open state

The structure of the open-channel form of the acetylcholine receptor has been determined from electron images of Torpedo ray postsynaptic membranes activated by brief (< 5 ms) mixing with droplets containing acetylcholine. Comparison with the closed-channel form shows that acetylcholine initiates small rotations of the subunits in the extracellular domain, which trigger a change in configuration of alpha-helices lining the membrane-spanning pore. The open pore tapers towards the intracellular membrane face, where it is shaped by a 'barrel' of alpha-helices having a pronounced right-handed twist.

Open-channel block by internally applied amines inhibits activation gate closure in batrachotoxin-activated sodium channels

We have studied the action of several pore-blocking amines on voltage-dependent activation gating of batrachotoxin(BTX)-activated sodium channels, from bovine heart and rat skeletal muscle, incorporated into planar lipid bilayers. Although structurally simpler, the compounds studied show general structural features and channel-inhibiting actions that resemble those of lidocaine. When applied to the cytoplasmic end of the channel, these compounds cause a rapid, voltage-dependent, open-channel block seen as a reduction in apparent single-channel amplitude (companion paper). Internal application of phenylpropanolamine, phenylethylamine, phenylmethylamine, and diethylamine, as well as causing open-channel block, reduces the probability of channel closure, producing a shift of the steady-state activation curve toward more hyperpolarizing potentials. These gating effects were observed for both cardiac and skeletal muscle channels and were not evoked by addition of equimolar N-Methyl-D-Glucamine, suggesting a specific interaction of the blockers with the channel rather than a surface charge effect. Kinetic analysis of phenylpropanolamine action on skeletal muscle channels indicated that phenylpropanolamine reduced the closed probability via two separate mechanisms. First, mean closed durations were slightly abbreviated in its presence. Second, and more important, the frequency of the gating closures was reduced. This action was correlated with the degree, and the voltage dependence, of open-channel block, suggesting that the activation gate cannot close while the pore is occluded by the blocker. Such a mechanism might underlie the previously reported immobilization of gating charge associated with local anesthetic block of unmodified sodium channels.