Nicotine dependence is associated with functional variation in FMO3, an enzyme that metabolizes nicotine in the brain.

A common haplotype of the flavin-containing monooxygenase gene FMO3 is associated with aberrant mRNA splicing, a twofold reduction in in vivo nicotine N-oxidation and reduced nicotine dependence. Tobacco remains the largest cause of preventable mortality worldwide. CYP2A6, the primary hepatic nicotine metabolism gene, is robustly associated with cigarette consumption but other enzymes contribute to nicotine metabolism. We determined the effects of common variants in FMO3 on plasma levels of nicotine-N-oxide in 170 European Americans administered deuterated nicotine. The polymorphism rs2266780 (E308G) was associated with N-oxidation of both orally administered and ad libitum smoked nicotine (P⩽3.3 × 10-5 controlling for CYP2A6 genotype). In vitro, the FMO3 G308 variant was not associated with reduced activity, but rs2266780 was strongly associated with aberrant FMO3 mRNA splicing in both liver and brain (P⩽6.5 × 10-9). Surprisingly, in treatment-seeking European American smokers (n=1558) this allele was associated with reduced nicotine dependence, specifically with a longer time to first cigarette (P=9.0 × 10-4), but not with reduced cigarette consumption. As N-oxidation accounts for only a small percentage of hepatic nicotine metabolism we hypothesized that FMO3 genotype affects nicotine metabolism in the brain (unlike CYP2A6, FMO3 is expressed in human brain) or that nicotine-N-oxide itself has pharmacological activity. We demonstrate for the first time nicotine N-oxidation in human brain, mediated by FMO3 and FMO1, and show that nicotine-N-oxide modulates human α4ß2 nicotinic receptor activity in vitro. These results indicate possible mechanisms for associations between FMO3 genotype and smoking behaviors, and suggest nicotine N-oxidation as a novel target to enhance smoking cessation.

The neurosteroid 5ß-pregnan-3α-ol-20-one enhances actions of etomidate as a positive allosteric modulator of α1ß2γ2L GABAA receptors.

BACKGROUND AND PURPOSE: Neurosteroids potentiate responses of the GABAA receptor to the endogenous agonist GABA. Here, we examined the ability of neurosteroids to potentiate responses to the allosteric activators etomidate, pentobarbital and propofol. EXPERIMENTAL APPROACH: Electrophysiological assays were conducted on rat α1ß2γ2L GABAA receptors expressed in HEK 293 cells. The sedative activity of etomidate was studied in Xenopus tadpoles and mice. Effects of neurosteroids on etomidate-elicited inhibition of cortisol synthesis were determined in human adrenocortical cells. KEY RESULTS: The neurosteroid 5ß-pregnan-3α-ol-20-one (3α5ßP) potentiated activation of GABAA receptors by GABA and allosteric activators. Co-application of 1 µM 3α5ßP induced a leftward shift (almost 100-fold) of the whole-cell macroscopic concentration-response relationship for gating by etomidate. Co-application of 100 nM 3α5ßP reduced the EC50 for potentiation by etomidate of currents elicited by 0.5 µM GABA by about three-fold. In vivo, 3α5ßP (1mg kg(-1) ) reduced the dose of etomidate required to produce loss of righting in mice (ED50 ) by almost 10-fold. In tadpoles, the presence of 50 or 100 nM 3α5ßP shifted the EC50 for loss of righting about three- or ten-fold respectively. Exposure to 3α5ßP did not influence inhibition of cortisol synthesis by etomidate. CONCLUSIONS AND IMPLICATIONS: Potentiating neurosteroids act similarly on orthosterically and allosterically activated GABAA receptors. Co-application of neurosteroids with etomidate can significantly reduce dosage requirements for the anaesthetic, and is a potentially beneficial combination to reduce undesired side effects.

The insecticide fipronil and its metabolite fipronil sulphone inhibit the rat alpha1beta2gamma2L GABA(A) receptor.

BACKGROUND AND PURPOSE: Fipronil is the active ingredient in a number of widely used insecticides. Human exposure to fipronil leads to symptoms (headache, nausea and seizures) typically associated with the antagonism of GABA(A) receptors in the brain. In this study, we have examined the modulation of the common brain GABA(A) receptor subtype by fipronil and its major metabolite, fipronil sulphone. EXPERIMENTAL APPROACH: Whole-cell and single-channel recordings were made from HEK 293 cells transiently expressing rat alpha1beta2gamma2L GABA(A) receptors. KEY RESULTS: The major effect of fipronil was to increase the rate of current decay in macroscopic recordings. In single-channel recordings, the presence of fipronil resulted in shorter cluster durations without affecting the intracluster open and closed time distributions or the single-channel conductance. The alpha1V256S mutation, previously shown alleviate channel inhibition by inhibitory steroids and several insecticides, had a relatively small effect on channel block by fipronil. The mode of action of fipronil sulphone was similar to that of its parent compound but the metabolite was less potent at inhibiting the alpha1beta2gamma2L receptor. CONCLUSIONS AND IMPLICATIONS: We conclude that exposure to fipronil induces accumulation of receptors in a novel, long-lived blocked state. This process proceeds in parallel with and independently of, channel desensitization. The lower potency of fipronil sulphone indicates that the conversion serves as a detoxifying process in mammalian brain.

Actions of anesthetics on excitatory transmitter-gated channels.

Excitatory transmitter-gated receptors are found in three gene families: the glutamate ionotropic receptors, the Cys-loop receptor family (nicotinic and 5HT3), and the purinergic (P2X) receptors. Anesthetic drugs act on many members of these families, but in most cases the effects are unlikely to be related to clinically relevant anesthetic actions. However, the gaseous anesthetics (xenon and nitrous oxide) and the dissociative anesthetics (ketamine) have significant inhibitory activity at one type of glutamate receptor (the NMDA receptor) that is likely to contribute to anesthetic action. It is possible that some actions at neuronal nicotinic receptors may make a smaller contribution to effects of some anesthetics.

Mechanisms of potentiation of the mammalian GABAA receptor by the marine cembranoid eupalmerin acetate.

BACKGROUND AND PURPOSE: Eupalmerin acetate (EPA) is a marine diterpene compound isolated from the gorgonian octocorals Eunicea succinea and Eunicea mammosa. The compound has been previously shown to modulate muscle-type and neuronal nicotinic acetylcholine receptors, which are inhibited in the presence of low micromolar concentrations of EPA. In this study, we examined the effect of EPA on another transmitter-gated ion channel, the GABA(A) receptor. EXPERIMENTAL APPROACH: Whole-cell and single-channel recordings were made from HEK 293 cells transiently expressing rat wild-type and mutant alpha1beta2gamma2L GABA(A) receptors. KEY RESULTS: Our findings demonstrate that, at micromolar concentrations, EPA potentiates the rat alpha1beta2gamma2L GABA(A) receptor. The analysis of single-channel currents recorded in the presence of EPA showed that the kinetic mode of action of EPA is similar to that of neuroactive steroids. Mutations to residues alpha1Q241 and alpha1N407/Y410, previously shown to affect receptor modulation by neurosteroids, also diminished potentiation by EPA. Exposure to a steroid antagonist, (3alpha,5alpha)-17-phenylandrost-16-en-3-ol, reduced potentiation by EPA. Additionally, exposure to EPA led to potentiation of GABA(A) receptors activated by very high concentrations (1-10 microM) of allopregnanolone. In tadpole behavioural assays, EPA caused loss of righting reflex and loss of swimming reflex. CONCLUSIONS AND IMPLICATIONS: We conclude that EPA either interacts with the putative neurosteroid binding site on the GABA(A) receptor or shares with neurosteroids the key transduction elements involved in channel potentiation by steroids. The results indicate that cembranoids represent a novel class of GABA(A) receptor modulators.

Mode of cembranoid action on embryonic muscle acetylcholine receptor.

The mechanism of eupalmerin acetate (EUAC) actions on the embryonic muscle nicotinic acetylcholine receptor (nAChR) in BC3H-1 cells was studied by using whole-cell and single-channel patch-clamp current measurements. With whole-cell currents, EUAC did not act as an agonist on this receptor. Coapplication of 30 microM EUAC with 50 microM, 100 microM, or 500 microM carbamoylcholine (CCh) reversibly inhibited the current amplitude, whereas, with 20 microM CCh, current was increased above control values in the presence of EUAC. EUAC concentration curves (0.01-40 microM) obtained with 100 microM and 500 microM CCh displayed slope coefficients, n(H), significantly smaller than one, suggesting that EUAC bound to several sites with widely differing affinities on the receptor molecule. The apparent rate of receptor desensitization in the presence of EUAC and CCh was either slower than or equal to that obtained with CCh alone. The major finding from single-channel studies was that EUAC did not affect single-channel conductance or the ability of CCh to interact with the receptor. Instead, EUAC acted by increasing the channel closing rate constant. The results are not consistent with the competitive model for EUAC inhibition, with the sequential open-channel block model, or with inhibition by increased desensitization. The data are best accounted for by a model in which EUAC acts by closed-channel block at low concentrations, by positive modulation at intermediate concentrations, and by negative allosteric modulation of the open channel at high concentrations.

Modulation of GABA(A) receptor channel gating by pentobarbital.

1. We have studied the kinetic properties of channel gating of recombinant alpha 1 beta 2 gamma 2L GABA(A) receptors transiently expressed in human embryonic kidney 293 cells, using the cell-attached, single-channel patch-clamp technique. The receptors were activated by GABA, beta-alanine or piperidine-4-sulfonic acid (P4S), and the effects of pentobarbital (PB) on single-channel activity were examined. 2. At relatively high concentrations of agonist, single-channel activity occurred in well-defined clusters. In global terms, PB increased the mean open time for events in clusters, without changing the mean closed time. The addition of PB shifted the curve relating the probability of being open in a cluster (P(o)) to lower agonist concentrations, and that shift could be accounted for by the changes in mean open time. 3. The intracluster closed-time histograms contained four components. The durations and relative frequencies of these closed-dwell components were not affected by the presence of 40 microM PB, at any agonist concentration. The duration of one component was dependent upon the concentration of agonist used to activate the receptor. Accordingly, the inverse of the mean duration of this component will be called the effective opening rate. 4. The channel-opening rate constant (beta) was determined from the value of the effective opening rate at a saturating agonist concentration. beta was about 1900 s(-1) when the receptors were activated by GABA, 1500 s(-1) when activated by beta-alanine, and too low to be determined when P4S was administered. In the presence of 40 microM PB, beta was about 1500 s(-1) when the receptors were activated by GABA, 1400 s(-1) when activated by beta-alanine, and 50 s(-1) when activated by P4S. Hence, the potentiating effect of PB is not mediated by a change in beta. The concentration of agonist producing a half-maximal effective opening rate also remained unaffected in the presence of PB, indicating that receptor affinity for agonists is not influenced by PB. 5. The distributions of the intracluster open durations elicited by GABA could be described by the sum of three exponentials, with mean durations of about 0.4, 2.4 and 6.3 ms. The duration and relative frequency of the components did not change with GABA concentration (20 microM to 1 mM). In the presence of 40 microM PB, however, the mean duration of the longest of the open times increased (mean durations of about 0.4, 2.0 and 13 ms). The intracluster open durations elicited by beta-alanine could be described by the sum of two exponential components (1.1 and 3.5 ms). However, in the presence of 40 microM PB the open-time distribution contained three exponential components (0.2, 2 and 10 ms). Finally, openings elicited by P4S exhibited two components (0.3 and 0.9 ms). In the presence of 40 microM PB, three components could be distinguished (0.5, 2.5 and 13 ms). 6. These observations indicate that the potentiating effect of PB on GABA type A (GABA(A)) receptors reflects effects on the open state(s) of the receptors. In the case of receptors activated by GABA, the observations are consistent with the idea that the action is the result of PB stabilizing one of the open states. The actions on receptors activated by P4S or beta-alanine are also broadly consistent with this idea. However, the changes in open-time distributions caused by PB appear to be more complex. Possible explanations of the effects of PB on gating by different agonists are considered.

Kinetic and pharmacological properties of GABA(A) receptors in single thalamic neurons and GABA(A) subunit expression.

Synaptic inhibition in the thalamus plays critical roles in sensory processing and thalamocortical rhythm generation. To determine kinetic, pharmacological, and structural properties of thalamic gamma-aminobutyric acid type A (GABA(A)) receptors, we used patch-clamp techniques and single-cell reverse transcriptase polymerase chain reaction (RT-PCR) in neurons from two principal rat thalamic nuclei-the reticular nucleus (nRt) and the ventrobasal (VB) complex. Single-channel recordings identified GABA(A) channels with densities threefold higher in VB than nRt neurons, and with mean open time fourfold longer for nRt than VB [14.6 +/- 2.5 vs. 3.8 +/- 0.7 (SE) ms, respectively]. GABA(A) receptors in nRt and VB cells were pharmacologically distinct. Zn(2+) (100 microM) reduced GABA(A) channel activity in VB and nRt by 84 and 24%, respectively. Clonazepam (100 nM) increased inhibitory postsynaptic current (IPSC) decay time constants in nRt (from 44.3 to 77.9 ms, P < 0.01) but not in VB. Single-cell RT-PCR revealed subunit heterogeneity between nRt and VB cells. VB neurons expressed alpha1-alpha3, alpha5, beta1-3, gamma2-3, and delta, while nRt cells expressed alpha3, alpha5, gamma2-3, and delta. Both cell types expressed more subunits than needed for a single receptor type, suggesting the possibility of GABA(A) receptor heterogeneity within individual thalamic neurons. beta subunits were not detected in nRt cells, which is consistent with very low levels reported in previous in situ hybridization studies but inconsistent with the expected dependence of functional GABA(A) receptors on beta subunits. Different single-channel open times likely underlie distinct IPSC decay time constants in VB and nRt cells. While we can make no conclusion regarding beta subunits, our findings do support alpha subunits, possibly alpha1 versus alpha3, as structural determinants of channel deactivation kinetics and clonazepam sensitivity. As the gamma2 and delta subunits previously implicated in Zn(2+) sensitivity are both expressed in each cell type, the observed differential Zn(2+) actions at VB versus nRt GABA(A) receptors may involve other subunit differences.

Aromatics at the murine nicotinic receptor agonist binding site: mutational analysis of the alphaY93 and alphaW149 residues.

1. Two aromatic residues of the muscle nicotinic receptor putative agonist binding site, a tyrosine in position alpha93 and a tryptophan in position alpha149, were mutated to phenylalanine and the effects of the mutations on receptor properties were investigated using single-channel patch clamp. 2. The alphaY93F mutation reduced the receptor affinity by approximately 4-fold and the channel opening rate constant by 48-fold. The alphaW149F mutation reduced the receptor affinity by approximately 12-fold and the channel opening rate constant by 93-fold. 3. The kinetic properties of hybrid receptors that contained one wild-type and one mutated alpha subunit were also examined. Only one type of hybrid receptor activity was detected. The hybrid receptors had a channel opening rate constant intermediate to those of the wild-type and mutant receptors. It was concluded that the ligand binding sites in the mutated muscle nicotinic receptor contributed equally to channel gating. In the case of the alphaW149F mutation, the presence of the mutation in one of the binding sites had no effect on the binding properties of the other, non-mutated, site. 4. The mutant channel opening and closing rate constants were also estimated in the presence of tetramethylammonium. The data suggested significant interaction between the acetyl group of acetylcholine and the alphaY93 residue.

Pregnenolone sulfate block of GABA(A) receptors: mechanism and involvement of a residue in the M2 region of the alpha subunit.

Neurosteroids are produced in the brain, and can have rapid actions on membrane channels of neurons. Pregnenolone sulfate (PS) is a sulfated neurosteroid which reduces the responses of the [gamma]-aminobutyric acid A (GABA(A)) receptor. We analysed the actions of PS on single-channel currents from recombinant GABA(A) receptors formed from [alpha]1, [beta]2 and [gamma]2L subunits. Currents were elicited by a concentration of GABA eliciting a half-maximal response (50 microM) and a saturating concentration (1 mM). PS reduced the duration of clusters of single-channel activity at either concentration of GABA. PS had no discernable effect on rapid processes: no effects were apparent on channel opening and closing, nor on GABA affinity, and a rapidly recovering desensitised state was not affected. Instead, PS produced a slowly developing block which occurred at a similar rate for receptors with open or closed channels and with one or two bound GABA molecules. The rate of block was independent of membrane potential, implying that the charged sulfate moiety does not move through the membrane field. Change in a specific residue near the intracellular end of the channel lining portion of the [alpha]1 subunit had a major effect on the rate of block. Mutation of the residue [alpha]1 V256S reduced the rate of block by 30-fold. A mutation at the homologous position of the [beta]2 subunit ([beta]2 A252S) had no effect, nor did a complementary mutation in the [gamma]2L subunit ([gamma]2L S266A). It seems likely that this residue is involved in a conformational change underlying block by PS, instead of forming part of the binding site for PS.

Differential regulation of GABA release and neuronal excitability mediated by neuropeptide Y1 and Y2 receptors in rat thalamic neurons.

1. Neuropeptide Y (NPY) produced inhibitory effects on neurons of the thalamic reticular nucleus (RT; n = 18) and adjacent ventral basal complex (VB; n = 22), which included hyperpolarization (approximately 4 mV), a reduction in rebound and regular spikes and an increased membrane conductance. These effects were mediated predominantly via NPY1 receptor activation of G-protein-activated, inwardly rectifying K+ (GIRK) channels. 2. NPY reduced the frequency of spontaneous GABAA receptor-mediated inhibitory postsynaptic currents (sIPSCs) in RT (by 60 +/- 7 %, n = 14) and VB neurons (by 25 +/- 11 %, n = 16), but had no effect on the kinetic properties of sIPSCs. After removal of the RT nucleus, the inhibitory effects of NPY on sIPSCs in VB neurons remained (29 +/- 7 %, n = 5). The synaptic effects were mediated via NPY2 receptors. 3. NPY inhibited the frequency of miniature IPSCs (mIPSCs) in RT and VB neurons (by 63 +/- 7 %, n = 5, and 37 +/- 8 %, n = 10, respectively) in the presence of tetrodotoxin (TTX) (1 microM) but not TTX (1 microM) and Cd2+ (200 microM). 4. NPY inhibited evoked IPSCs in both RT (by 18 +/- 3 %, n = 6) and VB (by 5 +/- 4 %, n = 6) neurons without change in short-term synaptic plasticity. 5. We conclude that NPY1 and NPY2 receptors are functionally segregated in the thalamus: NPY1 receptors are predominantly expressed at the somata and dendrites and directly reduce the excitability of neurons in both the RT and VB nuclei by activating GIRK channels. NPY2 receptors are located at recurrent (RT) and feed-forward GABAergic terminals (VB) and downregulate GABA release via inhibition of Ca2+ influx from voltage-gated Ca2+ channels.

Structural elements near the C-terminus are responsible for changes in nicotinic receptor gating kinetics following patch excision.

We have studied the effect of patch excision on the gating kinetics of muscle nicotinic acetylcholine receptors transiently expressed in HEK 293 cells. The experiments were performed on embryonic and adult wild-type, and several mutated, receptors using acetylcholine, carbamylcholine and tetramethylammonium as agonists. We show that patch excision of cell-attached patches into the inside-out configuration led to a reduction of mean open duration in receptors containing a gamma-subunit (embryonic) but not an epsilon-subunit (adult receptors). Kinetic analysis of an embryonic receptor containing a mutated residue, alphaY93F, showed that the reduction in the mean open duration upon patch excision was mainly caused by an increase in the channel closing rate constant. This was confirmed by experiments on embryonic wild-type receptors using carbamylcholine as an agonist with low efficacy. By expressing receptors containing chimeric gamma-epsilon subunits we found that segments of the gamma-subunit corresponding to a region within the M3-M4 linker (the amphipathic helix, HA) and the M4 transmembrane domain were required for the reduction in channel open duration after excision. The results indicate that particular residues in both M4 and HA are required to allow the change in open time after excision. This finding suggests that there is an interaction between these two regions in determining the modulation of gating kinetics.

Activation and block of recombinant GABA(A) receptors by pentobarbitone: a single-channel study.

Recombinant GABA(A) receptors (alpha1beta2gamma2L) were transiently expressed in HEK 293 cells. We have investigated activation and block of these receptors by pentobarbitone (PB) using cell-attached single-channel patch clamp. Clusters of single-channel activity elicited by 500 microM PB were analysed to estimate rate constants for agonist binding and channel gating. The minimal model able to describe the kinetic data involved two sequential binding steps, followed by channel opening. The estimated channel opening rate constant is approximately 1500 s(-1), and the estimated equilibrium dissociation constants for the binding steps involved in activation are approximately 2 mM. Our results show a dose-dependent block of receptors at millimolar concentrations of PB that results in reduced open interval durations. The reduction in mean open time is linearly proportional to PB concentration, indicating that block can be produced by binding of a single PB molecule. Addition of millimolar concentrations of PB in the presence of GABA also produces a reduction of open channel lifetime in addition to a progressive increase in the closed interval durations within a cluster. The data suggest that the receptor contains two or more blocking sites while occupancy of only one of the sites is sufficient for channel block. Neither the blocking rate constant nor return rate from the blocked state(s) is affected by pH (ionization status of the PB molecule) demonstrating that both neutral and anionic forms of PB cause channel block.

Activation of muscle nicotinic acetylcholine receptor channels by nicotinic and muscarinic agonists.

1. The dose-response parameters of recombinant mouse adult neuromuscular acetylcholine receptor channels (nAChR) activated by carbamylcholine, nicotine, muscarine and oxotremorine were measured. Rate constants for agonist association and dissociation, and channel opening and closing, were estimated from single-channel kinetic analysis. 2. The dissociation equilibrium constants were (mM): ACh (0. 16)carbamylcholine (5.1)>oxotremorine M (0.6)>nicotine (0. 5)>muscarine (0.15). 4. Rat neuronal alpha4beta2 nAChR can be activated by all of the agonists. However, detailed kinetic analysis was impossible because the recordings lacked clusters representing the activity of a single receptor complex. Thus, the number of channels in the patch was unknown and the activation rate constants could not be determined. 5. Considering both receptor affinity and agonist efficacy, muscarine and oxotremorine are significant agonists of muscle-type nAChR. The results are discussed in terms of structure-function relationships at the nAChR transmitter binding site.

A mutational analysis of the acetylcholine receptor channel transmitter binding site.

Mutagenesis and single-channel kinetic analysis were used to investigate the roles of four acetylcholine receptor channel (AChR) residues that are candidates for interacting directly with the agonist. The EC50 of the ACh dose-response curve was increased following alpha-subunit mutations Y93F and Y198F and epsilon-subunit mutations D175N and E184Q. Single-channel kinetic modeling indicates that the increase was caused mainly by a reduced gating equilibrium constant (Theta) in alphaY198F and epsilonD175N, by an increase in the equilibrium dissociation constant for ACh (KD) and a reduction in Theta in alphaY93F, and only by a reduction in KD in epsilonE184Q. This mutation altered the affinity of only one of the two binding sites and was the only mutation that reduced competition by extracellular K+. Additional mutations of epsilonE184 showed that K+ competition was unaltered in epsilonE184D and was virtually eliminated in epsilonE184K, but that neither of these mutations altered the intrinsic affinity for ACh. Thus there is an apparent electrostatic interaction between the epsilonE184 side chain and K+ ( approximately 1.7kBT), but not ACh+. The results are discussed in terms of multisite and induced-fit models of ligand binding to the AChR.

Desensitization of mouse nicotinic acetylcholine receptor channels. A two-gate mechanism.

The rate constants of acetylcholine receptor channels (AChR) desensitization and recovery were estimated from the durations and frequencies of clusters of single-channel currents. Diliganded-open AChR desensitize much faster than either unliganded- or diliganded-closed AChR, which indicates that the desensitization rate constant depends on the status of the activation gate rather than the occupancy of the transmitter binding sites. The desensitization rate constant does not change with the nature of the agonist, the membrane potential, the species of permeant cation, channel block by ACh, the subunit composition (epsilon or gamma), or several mutations that are near the transmitter binding sites. The results are discussed in terms of cyclic models of AChR activation, desensitization, and recovery. In particular, a mechanism by which activation and desensitization are mediated by two distinct, but interrelated, gates in the ion permeation pathway is proposed.

Binding sites contribute unequally to the gating of mouse nicotinic alpha D200N acetylcholine receptors.

1. Single channel currents were recorded from HEK 293 cells expressing recombinant mouse adult (alpha 2 beta delta gamma) acetylcholine receptors (AChRs) containing a mutation at residue D200 of the alpha-subunit. Rate and equilibrium constants for AChR activation were estimated from open and closed time obtained over a range of ACh concentrations. 2. Mutation of alpha D200 to asparagine (alpha D200N) dramatically slows the rate constant of channel opening, with adult AChRs slowing 100-fold and embryonic AChRs slowing 400-fold. the rate constant of channel closing increased 3-fold, resulting in a decrease of the gating equilibrium constant of up to 1200-fold. In contrast to channel gating steps, ACh-binding steps are only modestly effected by alpha D200N. 3. Introduction of a potential glycosylation site in alpha D200N cannot account for the effect on channel gating because eliminating the consensus for glycosylation with the mutation alpha D200N + T202V fails to restore efficient gating. Gating is similarly impaired with the substitutions of E, K and Q at position alpha 200. 4. the agonists carbamylcholine and tetramethylammonium also activate the alpha D200N AChR, but with channel opening rates even slower than with ACh. The agonist dependence of the opening rate constant is similar in alpha D200N and wild type AChRs. 5. AChRs containing D200N at just one of the two alpha-subunits show either small or large changes in the gating equilibrium constant, presumably due to the presence of the mutation at either the alpha delta or alpha epsilon/alpha gamma sites. The changes in free energy of channel gating show that the contribution of each binding site is nearly independent. However, the sites do not contribute equally to gating, as an alpha D200N mutation at the alpha epsilon or alpha gamma binding site slows channel opening relatively more than at the alpha delta site.

Voltage dependence of mouse acetylcholine receptor gating: different charge movements in di-, mono- and unliganded receptors.

1. The voltage dependence of binding and gating in wild-type and mutant recombinant mouse nicotinic acetylcholine receptors (AChRs) was examined at the single-channel level. 2. The closing rate constant of diliganded receptors decreased e-fold with approximately 66 mV hyperpolarization in both wild-type (adult and embryonic) and mutant receptors. The opening rate constant of a mutant receptor (alpha Y93F) was not voltage dependent. 3. The voltage dependence of closing in monoliganded receptors was examined in several receptors having a mutation in the binding site (alpha G153S) or pore region (alpha L251C and epsilon T264P). The closing rate constant of these monoliganded receptors decreased e-fold with approximately 124 mV hyperpolarization. 4. The voltage dependence of closing and opening in unliganded receptors was examined in two receptors having a mutation in the pore region (alpha L251C and epsilon T264P). Neither the closing nor the opening rate constants of unliganded receptors were voltage dependent. 5. If z if the amount of charge that moves during channel closure and delta is the distance (as a fraction of the electric field) that the charge moves, we conclude that z delta = 0.4 in diliganded receptors, 0.2 in monoliganded receptors, and 0.0 in unliganded receptors. It is likely that charges on the protein, rather than the agonist molecule, move z delta = 0.2 after each ACh molecule has bound. 6. The results suggest that unliganded openings arise from a local, concerted change in the structure of the pore (channel opening) that does not involve the net movement of charged residues. We speculate that as a consequence of agonist binding, charged moieties in the protein change their disposition so that they move with respect to the electric field when the channel gates. The results are consistent with the idea that there is semi-independent movement of distinct domains during AChR gating.

Inorganic, monovalent cations compete with agonists for the transmitter binding site of nicotinic acetylcholine receptors.

The properties of adult mouse recombinant nicotinic acetylcholine receptors activated by acetylcholine (ACh+) or tetramethylammonium (TMA+) were examined at the single-channel level. The midpoint of the dose-response curve depended on the type of monovalent cation present in the extracellular solution. The shifts in the midpoint were apparent with both inward and outward currents, suggesting that the salient interaction is with the extracellular domain of the receptor. Kinetic modeling was used to estimate the rate constants for agonist binding and channel gating in both wild-type and mutant receptors exposed to Na+, K+, or Cs+. The results indicate that in adult receptors, the two binding sites have the same equilibrium dissociation constant for agonists. The agonist association rate constant was influenced by the ionic composition of the extracellular solution whereas the rate constants for agonist dissociation, channel opening, and channel closing were not. In low-ionic-strength solutions the apparent association rate constant increased in a manner that suggests that inorganic cations are competitive inhibitors of ACh+ binding. There was no evidence of an electrostatic potential at the transmitter binding site. The equilibrium dissociation constants for inorganic ions (Na+, 151 mM; K+, 92 mM; Cs+, 38 mM) and agonists (TMA+, 0.5 mM) indicate that the transmitter binding site is hydrophobic. Under physiological conditions, about half of the binding sites in resting receptors are occupied by Na+.

Activation kinetics of recombinant mouse nicotinic acetylcholine receptors: mutations of alpha-subunit tyrosine 190 affect both binding and gating.

Affinity labeling and mutagenesis studies have demonstrated that the conserved tyrosine Y190 of the acetylcholine receptor (AChR) alpha-subunit is a key determinant of the agonist binding site. Here we describe the binding and gating kinetics of embryonic mouse AChRs with mutations at Y190. In Y190F the dissociation constant for ACh binding to closed channels was reduced approximately 35-fold at the first binding site and only approximately 2-fold at the second site. At both binding sites the association and dissociation rate constants were decreased by the mutation. Compared with wildtype AChRs, doubly-liganded alpha Y190F receptors open 400 times more slowly but close only 2 times more rapidly. Considering the overall activation reaction (vacant-closed to fully occupied-open), there is an increase of approximately 6.4 kcal/mol caused by the Y-to-F mutation, of which at least 2.1 and 0.3 kcal/mol comes from altered agonist binding to the first and second binding sites, respectively. The closing rate constant of alpha Y190F receptors was the same with ACh, carbamoylcholine, or tetramethylammonium as the agonist. This rate constant was approximately 3 times faster in ACh-activated S, W, and T mutants. The equilibrium dissociation constant for channel block by ACh was approximately 2-fold lower in alpha Y190F receptors compared with in wildtype receptors, suggesting that there are changes in the pore region of the receptor as a consequence of the mutation. The activation reaction is discussed with regard to energy provided by agonist-receptor binding contacts, and by the intrinsic folding energy of the receptor.