Reaction of [3H]meproadifen mustard with membrane-bound Torpedo acetylcholine receptor

The Torpedo nicotinic acetylcholine receptor (AChR) contains a binding site for aromatic amine noncompetitive antagonists that is distinct from the binding site for agonists and competitive antagonists. To characterize the location and function of this allosteric antagonist site, an alkylating analog of meproadifen has been synthesized, 2-(chloroethylmethylamino)-ethyl-2, 2-diphenylpentanoate HCl (meproadifen mustard). Reaction of [3H]meproadifen mustard with AChR-rich membrane suspensions resulted in specific incorporation of label predominantly into the AChR alpha-subunit with minor incorporation into the beta-subunit. Specific labeling required the presence of high concentration of agonist and was inhibited by reversible noncompetitive antagonists including proadifen, meproadifen, perhydrohistrionicotoxin (HTX), and tetracaine when present at concentrations consistent with the binding affinity of these compounds for the allosteric antagonist site. No specific alkylation of the AChR alpha-subunit was detected in the absence of agonist, or in the presence of the partial agonist phenyltrimethylammonium or the competitive antagonists, d-tubocurarine, gallamine triethiodide, or decamethonium. Reaction with 35 microM meproadifen mustard for 70 min in the presence of carbamylcholine produced no alteration in the concentration of [3H]ACh-binding sites, but decreased by 38 +/- 4% the number of allosteric antagonist sites as measured by [3H]HTX binding. This decrease was not observed when the alkylation reaction was blocked by the presence of HTX. These results lead us to conclude that meproadifen mustard alkylates the allosteric antagonist site in the Torpedo AChR and that part of that site is associated with the AChR alpha-subunit.     

Molecular mechanisms and binding site location for the noncompetitive antagonist crystal violet on nicotinic acetylcholine receptors

We investigated the molecular mechanisms and the binding site location for the fluorophor crystal violet (CrV), a noncompetitive antagonist of the nicotinic acetylcholine receptor (AChR). To this end, radiolabeled competition binding, fluorescence spectroscopy, Schild-type analysis, patch-clamp recordings, and molecular dynamics approaches were used. The results indicate that (i) CrV interacts with the desensitized Torpedo AChR with higher affinity than with the resting state at several temperatures (5-37 degrees C); (ii) CrV-induced inhibition of the phencyclidine (PCP) analogue [(3)H]thienylcyclohexylpiperidine binding to the desensitized or resting AChR is mediated by a steric mechanism; (iii) tetracaine inhibits CrV binding to the resting AChR, probably by a steric mechanism; (iv) barbiturates modulate CrV binding to the resting AChR by an allosteric mechanism; (v) CrV itself induces AChR desensitization; (vi) CrV decreases the peak of macroscopic currents by acting on the resting AChR but without affecting the desensitization rate from the open state; and (vii) two tertiary amino groups from CrV may bind to the alpha1-Glu(262) residues (located at position 20') in the resting state. We conclude that the CrV binding site overlaps the PCP locus in the resting and desensitized state. The noncompetitive action of CrV may be explained by an allosteric mechanism in which the binding of CrV to the extracellular mouth of the resting receptor leads to an inhibition of channel opening. Binding of CrV probably increases desensitization of the resting channel and stabilizes the desensitized state.     

Allosterically linked noncompetitive antagonist binding sites in the resting nicotinic acetylcholine receptor ion channel

Previous studies have established the presence of overlapping binding sites for the noncompetitive antagonists (NCAs) amobarbital, tetracaine, and 3-trifluoromethyl-3-(m-[(125)I]iodophenyl) diazirine ([(125)I]TID) within the ion channel of the Torpedo nicotinic acetylcholine receptor (AChR) in the resting state. These well-characterized NCAs and competitive radioligand binding and photolabeling experiments were employed to better characterize the interaction of the dissociative anesthetics ketamine and thienylcycloexylpiperidine (TCP) with the resting AChR. Our experiments yielded what appear to be conflicting results: (i) both ketamine and TCP potentiated [(125)I]TID photoincorporation into AChR subunits; and (ii) ketamine and TCP had very little effect on [(14)C]amobarbital binding. Nevertheless, (iii) both ketamine and TCP completely displaced [(3)H]tetracaine binding (K(i)s approximately 20.9 and 2.0 microM, respectively) by a mutually exclusive mechanism. To reconcile these results we propose that, in the resting ion channel, TCP and ketamine bind to a site that is spatially distinct from the TID and barbiturate locus, while tetracaine bridges both binding sites.     

Decidium. A novel fluorescent probe of the agonist/antagonist and noncompetitive inhibitor sites on the nicotinic acetylcholine receptor

We have examined the interaction of the nicotinic acetylcholine receptor with decidium diiodide, a bisquaternary analogue of ethidium containing 10 methylene groups between the endocyclic and trimethylamino quaternary nitrogens. Decidium inhibits mono-[125I]iodo-alpha-toxin binding, inhibits agonist-elicited 22Na+ influx in intact cells, augments agonist competition with mono-[125I]iodo-alpha-toxin binding, and enhances [3H]phencyclidine (PCP) binding to a noncompetitive inhibitor site. These effects occur over similar concentration ranges (half-maximum effects between 0.1 and 0.4 microM). Thus, decidium binds to the agonist site and converts the receptor to a desensitized state exhibiting increased affinity for agonist and heterotropic inhibitors. These properties are similar to metaphilic antagonists characterized in classical pharmacology. At higher concentrations decidium associates directly with the noncompetitive inhibitor site identified by [3H]phencyclidine binding. Dissociation constants of decidium at this site in the resting and desensitized states are determined to be 29 and 1.2 microM, respectively. Analysis of fluorescence excitation and emission maxima reveal that binding to both the agonist and noncompetitive inhibitor sites is associated with approximately 2-fold enhancement of fluorescence. The excitation maximum for decidium bound at the agonist site appears at 490 nm while that for decidium bound at the noncompetitive inhibitor site appears at 530 compared to 480 nm in buffer. These results suggest that decidium experiences a more hydrophobic environment upon binding to the nicotinic acetylcholine receptor sites, particularly to the noncompetitive inhibitor site. Fluorescence energy transfer between N'-fluorescein isothiocyanate-lysine-23 alpha-toxin (FITC-toxin), and decidium is not detected when each is bound to one of the two agonist sites on the receptor. This allows a minimal distance to be estimated between fluorophores. In contrast, energy transfer is observed between decidium nonspecifically associated with the membrane or with nonspecific sites and the FITC-toxin at the agonist sites.     

[3H]MK-801 Labels a Site on the N-Methyl-D-Aspartate Receptor Channel Complex in Rat Brain Membranes

The potent noncompetitive N-methyl-D-aspartate (NMDA) receptor antagonist [3H]MK-801 bound with nanomolar affinity to rat brain membranes in a reversible, saturable, and stereospecific manner. The affinity of [3H]MK-801 was considerably higher in 5 mM Tris-HCl (pH 7.4) than in previous studies using Krebs-Henseleit buffer. [3H]MK-801 labels a homogeneous population of sites in rat cerebral cortical membranes with KD of 6.3 nM and Bmax of 2.37 pmol/mg of protein. This binding was unevenly distributed among brain regions, with hippocampus greater than cortex greater than olfactory bulb = striatum greater than medulla-pons, and the cerebellum failing to show significant binding. Detailed pharmacological characterization indicated [3H]MK-801 binding to a site which was competitively and potently inhibited by known noncompetitive NMDA receptor antagonists, such as phencyclidine, thienylcyclohexylpiperidine (TCP), ketamine, N-allylnormetazocine (SKF 10,047), cyclazocine, and etoxadrol, a specificity similar to sites labelled by [3H]TCP. These sites were distinct from the high-affinity sites labelled by the sigma receptor ligand (+)-[3H]SKF 10,047. [3H]MK-801 binding was allosterically modulated by the endogenous NMDA receptor antagonist Mg2+ and by other active divalent cations. These data suggest that [3H]MK-801 labels a high-affinity site on the NMDA receptor channel complex, distinct from the NMDA recognition site, which is responsible for the blocking action of MK-801 and other noncompetitive NMDA receptor antagonists.     

The hydrophobic photoreagent 3-(trifluoromethyl)-3-m-([125I] iodophenyl) diazirine is a novel noncompetitive antagonist of the nicotinic acetylcholine receptor

We have shown previously that the lipophilic photoreagent 3-(trifluoromethyl)3-m-([125I]iodophenyl)-diazirine ([125I]TID) photolabels all four subunits of the Torpedo nicotinic acetylcholine receptor (AChR) and that greater than 70% of this photoincorporation is inhibited by cholinergic agonists and some noncompetitive antagonists, including histrionicotoxin (HTX), but not phencyclidine (PCP; White, B.H., and Cohen, J.B. (1988) Biochemistry 27, 8741-8751). We have now examined the effects of nonradioactive TID on (a) AChR photoincorporation of [125I]TID, (b) AChR-mediated ion transport, and (c) AChR binding of several cholinergic ligands. We find that TID inhibits [125I]TID photoincorporation into the AChR to the same extent as carbamylcholine. The saturable component of [125I]TID photolabeling is half-maximal at 4 microM [125I]TID with 0.5 mol specifically incorporated per mol of AChR after 30 min photolysis with 60 microM [125I]TID. Repeated labeling of membranes at a fixed [125I]TID concentration gave results consistent with a maximal incorporation of one [125I]TID molecule per AChR. Nonradioactive TID also noncompetitively inhibits agonist-stimulated 22Na+ efflux from Torpedo vesicles with an IC50 of 1 microM. Furthermore, TID inhibits allosterically the binding of [3H]HTX, decreasing its affinity for the AChR 5-fold both in the presence and absence of agonist. In contrast, TID has little effect on [3H]PCP binding in the absence of agonist but completely inhibits it in the presence of agonist. TID enhances the cooperativity of [3H]nicotine binding. [125I]TID is thus a photoaffinity label for a novel noncompetitive antagonist binding site on the AChR that is linked allosterically to the binding sites of both agonists and other noncompetitive antagonists. The [125I]TID site is presumably located within the central pore of the AChR.     

Noncompetitive antagonist binding sites in the torpedo nicotinic acetylcholine receptor ion channel. Structure-activity relationship studies using adamantane derivatives

We used a series of adamantane derivatives to probe the structure of the phencyclidine locus in either the resting or desensitized state of the nicotinic acetylcholine receptor (AChR). Competitive radioligand binding and photolabeling experiments using well-characterized noncompetitive antagonists such as the phencyclidine analogue [piperidyl-3,4-(3)H(N)]-N-[1-(2-thienyl)cyclohexyl]-3,4-piperidine ([(3)H]TCP), [(3)H]ethidium, [(3)H]tetracaine, [(14)C]amobarbital, and 3-(trifluoromethyl)-3-(m-[(125)I]iodophenyl)diazirine ([(125)I]TID) were performed. Thermodynamic and structure-function relationship analyses yielded the following results. (1) There is a good structure-function relationship for adamantane amino derivatives inhibiting [(3)H]TCP or [(3)H]tetracaine binding to the resting AChR. (2) Since the same derivatives inhibit neither [(14)C]amobarbital binding nor [(125)I]TID photoincorporation, we conclude that these positively charged molecules preferably bind to the TCP locus, perhaps interacting with alphaGlu(262) residues at position M2-20. (3) The opposite is true for the neutral molecule adamantane, which prefers the TID (or barbiturate) locus instead of the TCP site. (4) The TID site is smaller and more hydrophobic (it accommodates neutral molecules with a maximal volume of 333 +/- 45 A(3)) than the TCP locus, which has room for positively charged molecules with volumes as large as 461 A(3) (e.g., crystal violet). This supports the concept that the resting ion channel is tapering from the extracellular mouth to the middle portion. (5) Finally, although both the hydrophobic environment and the size of the TCP site are practically the same in both states, there is a more obvious cutoff in the desensitized state than in the resting state, suggesting that the desensitization process constrains the TCP locus. A plausible location of neutral and charged adamantane derivatives is shown in a model of the resting ion channel.     

Inhibition of yeast mitochondrial F1-ATPase, F0F1-ATPase and submitochondrial particles by rhodamines and ethidium bromide

ATP hydrolysis by F1-ATPase is strongly inhibited by cationic rhodamines; neutral rhodamines are very poor inhibitors. Rhodamine 6G is a noncompetitive inhibitor of purified F0F1-ATPase and submitochondrial particles, however, an uncompetitive inhibitor of F1-ATPase (KI approximately equal to 2.4 microM for all three enzyme forms). Ethidium bromide is a noncompetitive inhibitor of F0F1-ATPase, submitochondrial particles and also F1-ATPase (KI approximately equal to 270 microM). Neither of the inhibitors affects the negative cooperativity (nH approximately equal to 0.7). The non-identical binding sites for rhodamine 6G and ethidium bromide are located on the F1-moiety and are topologically distinct from the catalytic site. Binding of the inhibitors prevents the conformational changes essential for energy transduction. It is concluded that the inhibitor binding sites are involved in proton translocation. In F1-ATPase, binding of MgATP at a catalytic site causes conformational changes, which allosterically induce the correct structure of the rhodamine 6G binding site. In F0F1-ATPase, this conformation of the F1-moiety exists a priori, due to allosteric interactions with F0-subunits. The binding site for ethidium bromide on F1-ATPase does not require substrate binding at the catalytic site and is not affected by F0F1-subunit interactions.     

Interaction of noncompetitive inhibitors with the acetylcholine receptor. The site specificity and spectroscopic properties of ethidium binding

The spectroscopic properties and specificity of binding of a fluorescent quaternary amine, ethidium, with acetylcholine receptor-enriched membranes from Torpedo californica have been examined. Competition binding with [3H]phencyclidine in the presence of carbamylcholine showed that ethidium binds with high affinity to a noncompetitive inhibitor site (KD = 3.6 X 10(-7) M). However, in the presence of alpha-toxin, ethidium's affinity is substantially lower (KD approximately 1 X 10(-3) M). Ethidium was also found to enhance [3H]acetylcholine binding with a KD characteristic of ethidium binding to a high-affinity noncompetitive inhibitor site. These findings indicate that ethidium binds to an allosteric site which is regulated by agonist binding and can convert the agonist sites from low to high affinity. Fluorescence titrations of ethidium in the presence of carbamylcholine yielded a similar KD (2.5 X 10(-7) M) and showed an ethidium stoichiometry of one site/acetylcholine receptor monomer. Ethidium was completely displaced by noncompetitive inhibitors such as phencyclidine, histrionicotoxin, and dibucaine. The enhanced fluorescence lifetime of the bound species showed that the increased fluorescence intensity reflects a 13-fold increase in quantum yield for the complex compared to ethidium in buffer. Fractional dissociation of ethidium with phencyclidine produced a double-exponential fluorescence decay rate with lifetime components characteristic of ethidium free in solution and bound to the receptor. These data argue that the alterations in ethidium fluorescence elicited by other ligands is due to a change in the fraction of specifically bound ethidium rather than a change in quantum yield of a pre-existing ethidium-acetylcholine receptor complex. The extent of polarization indicates that bound ethidium is strongly immobilized. The magnitude of the quantum yield enhancement and the shifts of excitation and emission maxima of bound ethidium suggest that its binding site is within a hydrophobic domain with limited accessibility to the aqueous phase.     

(−)-Reboxetine inhibits muscle nicotinic acetylcholine receptors by interacting with luminal and non-luminal sites

The interaction of (−)-reboxetine, a non-tricyclic norepinephrine selective reuptake inhibitor, with muscle-type nicotinic acetylcholine receptors (AChRs) in different conformational states was studied by functional and structural approaches. The results established that (−)-reboxetine: (a) inhibits (±)-epibatidine-induced Ca²⁺ influx in human (h) muscle embryonic (hα1β1γδ) and adult (hα1β1εδ) AChRs in a non-competitive manner and with potencies IC₅₀ = 3.86 ± 0.49 and 1.92 ± 0.48 μM, respectively, (b) binds to the [³H]TCP site with ∼13-fold higher affinity when the Torpedo AChR is in the desensitized state compared to the resting state, (c) enhances [³H]cytisine binding to the resting but activatableTorpedo AChR but not to the desensitized AChR, suggesting desensitizing properties, (d) overlaps the PCP luminal site located between rings 6′ and 13′ in the Torpedo but not human muscle AChRs. In silico mutation results indicate that ring 9′ is the minimum structural component for (−)-reboxetine binding, and (e) interacts to non-luminal sites located within the transmembrane segments from the Torpedo AChR γ subunit, and at the α1/ε transmembrane interface from the adult muscle AChR. In conclusion, (−)-reboxetine non-competitively inhibits muscle AChRs by binding to the TCP luminal site and by inducing receptor desensitization (maybe by interacting with non-luminal sites), a mechanism that is shared by tricyclic antidepressants.     

Characterization of [3H]desmethylimipramine binding in bovine adrenal medulla: interactions with sigma- and (or) phencyclidine-receptor ligands.

High-affinity binding sites (apparent KD 2.87 nM) for [3H]desmethylimipramine ([3H]DMI), have been demonstrated and characterized in membrane preparations of bovine adrenal medulla. The binding of [3H]DMI improved upon pretreatment of the membrane with KCl and was saturable, sodium dependent, and potently inhibited by nisoxetine and imipramine. [3H]DMI binding was also inhibited by various phencyclidine (PCP)- and (or) sigma-receptor ligands, with the following order of potency: haloperidol > rimcazole > (-)-butaclamol > dextromethorphan > MK-801 > (+)-3-(3-hydroxyphenyl)-N-(1-propyl)piperidine ((+)-3-PPP) > PCP > N-(2-thienyl)cyclohexyl-3,4-piperidine (TCP) > (+)-SKF-10047 > (-)-SKF-10047. The inhibition produced by sigma ligands was not attributed to stimulation of either sigma 1- or sigma 2-receptors, owing to inactivity of the selective sigma-receptor ligands (+)-pentazocine and 1,3-di(2-tolyl)guanidine (DTG). The inhibition of [3H]DMI binding by sigma- and PCP-receptor ligands was not attributed to PCP1- or PCP2-receptor stimulation, owing to the decreased potency (100-fold) of these ligands in [3H]DMI assays compared with the affinity for brain PCP1 sites, and the ineffectiveness of the PCP2-ligand N-(1-(2-benzo(b)thiophenyl)cyclohexyl)piperidine (BTCP). Scatchard analysis of the inhibition by the sigma-ligands haloperidol and (+)-3-PPP, as well as the PCP1 receptor ligand MK-801, demonstrated noncompetitive interaction with the site bound by [3H]DMI. These studies indicate that bovine adrenomedullary membranes possess a specific receptor for the noradrenaline uptake inhibitor [3H]DMI, which is sensitive to allosteric modulation produced by PCP and sigma-ligands.     

Interaction of 18-methoxycoronaridine with nicotinic acetylcholine receptors in different conformational states

The interaction of 18-methoxycoronaridine (18-MC) with nicotinic acetylcholine receptors (AChRs) was compared with that for ibogaine and phencyclidine (PCP). The results established that 18-MC: (a) is more potent than ibogaine and PCP inhibiting (±)-epibatidine-induced AChR Ca²⁺ influx. The potency of 18-MC is increased after longer pre-incubation periods, which is in agreement with the enhancement of [³H]cytisine binding to resting but activatable Torpedo AChRs, (b) binds to a single site in the Torpedo AChR with high affinity and inhibits [³H]TCP binding to desensitized AChRs in a steric fashion, suggesting the existence of overlapping sites. This is supported by our docking results indicating that 18-MC interacts with a domain located between the serine (position 6′) and valine (position 13′) rings, and (c) inhibits [³H]TCP, [³H]ibogaine, and [³H]18-MC binding to desensitized AChRs with higher affinity compared to resting AChRs. This can be partially attributed to a slower dissociation rate from the desensitized AChR compared to that from the resting AChR. The enthalpic contribution is more important than the entropic contribution when 18-MC binds to the desensitized AChR compared to that for the resting AChR, and vice versa. Ibogaine analogs inhibit the AChR by interacting with a luminal domain that is shared with PCP, and by inducing desensitization.     

A Comparison of [3H]MK-801 and N-[1-(2-Thienyl)cyclohexyl]-3,4-[3H]Piperidine Binding to the N-Methyl-D-Aspartate Receptor Complex in Human Brain

The binding of (+)-[3H]5-methyl-10,11-dihydro-5H-dibenzo[a,d] cyclohepten-5,10-imine maleate ([3H]MK-801) and N-[1-(2-thienyl)cyclohexyl]-3,4-[3H]piperidine ([3H]TCP) to the N-methyl-D-aspartate (NMDA) receptor complex of human brain has been investigated. Significant differences were noted between the binding of the two ligands in the same tissue samples. Binding of both ligands was stimulated by addition of glutamic acid or glycine. However, addition of both compounds resulted in an additional effect with [3H]MK-801 but not [3H]TCP binding. Saturation analysis revealed approximately twice as many high-affinity sites for [3H]MK-801 (Bmax, 1,500 +/- 300 fmol/mg of protein) than for [3H]TCP (Bmax, 660 +/- 170 fmol/mg of protein). In addition, a low-affinity site was detected for [3H]MK-801 binding but not [3H]TCP binding. The pharmacology of the high-affinity [3H]MK-801 and [3H]TCP binding sites was similar with rank order of potency of inhibitors being MK801 greater than TCP greater than phencyclidine greater than N-allylnormetazocine (SKF 10047). 2-Amino-5-phosphonopentanoate inhibited binding of both ligands with comparable potency whereas both 7-chlorokynurenic acid and ZnCl2 were more potent inhibitors of [3H]MK-801 than of [3H]TCP binding. All compounds examined exhibited Hill coefficients of significantly less than unity. Saturation analysis performed in the striatum revealed that the number of binding sites was the same for both [3H]MK-801 (Bmax, 1,403 +/- 394 fmol/mg) and [3H]TCP (Bmax, 1,292 +/- 305 fmol/mg). Addition of glutamate or glycine stimulated striatal binding but there was no further increase on addition of both together.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure of the agonist-binding site of the nicotinic acetylcholine receptor. [3H]acetylcholine mustard identifies residues in the cation-binding subsite.

To characterize the structure of the agonist-binding site of the Torpedo nicotinic acetylcholine receptor (AChR), we have used [3H]acetylcholine mustard [( 3H]AChM), a reactive analog of acetylcholine, to identify residues contributing to the cation-binding subsite. Reaction of [3H]AChM, in its aziridinium form, with AChR-rich membrane suspensions, resulted initially in reversible, high affinity binding (K approximately 0.3 microM) followed by slow alkylation of the acetylcholine-binding site. Incorporation of label into AChR alpha-subunit was inhibited by agonists and competitive antagonists, but not by noncompetitive antagonists, and reaction with 3 microM [3H]AChM for 2 h resulted in specific alkylation of 0.6% of alpha-subunits. Within the alpha-subunit, greater than 90% of specific incorporation was contained within an 18-kDa Staphylococcus aureus V8 proteolytic fragment beginning at Val-46 and containing N-linked carbohydrate. To identify sites of specific alkylation, [3H]AChM-labeled alpha-subunit was digested with trypsin, and the digests were fractionated by reverse phase high pressure liquid chromatography. Specifically labeled material was recovered within a single peak containing a peptide extending from Leu-80 to Lys-107. NH2-terminal amino acid sequencing revealed specific release of 3H in cycle 14 corresponding to alpha-subunit Tyr-93. Identification of Tyr-93 as the site of alkylation was confirmed by radiosequence analysis utilizing o-phthalaldehyde to establish that the released 3H originated from a peptide containing prolines at residues 2 and 9. Because [3H]AChM contains as its reactive group a positively charged quaternary aziridinium, alpha-subunit Tyr-93 is identified as contributing to the cation-binding domain of the AChR agonist-binding site. The selective reaction of [3H]AChM with tyrosyl rather than acidic side chains indicates the importance of aromatic interactions for the binding of the quaternary ammonium group, and the lack of reaction with the tyrosyl or acidic side chains within alpha 190-200 emphasizes the selective orientation of acetylcholine within its binding site.     

The ion channel of the nicotinic acetylcholine receptor is formed by the homologous helices M II of the receptor subunits

A binding site for the channel-blocking noncompetitive antagonist [3H]triphenylmethylphosphonium ([3H]TPMP+) was localized in the alpha-, beta- and delta-chains of the nicotinic acetylcholine receptor (AChR) from Torpedo marmorata electric tissue. The photolabel was found in homologous positions of the highly conserved sequence helix II, alpha 248, beta 254, and delta 262. The site of the photoreaction appears to not be affected by the functional state of the receptor. [3H]TPMP+ was found in position delta 262 independent of whether photolabeling was performed with the receptor in its resting, desensitized or antagonist state. A model of the AChR ion channel is proposed, according to which the channel is formed by the five helices II contributed by the five receptor subunits.     

Neomycin Is an Agonist at a Polyamine Site on the N-Methyl-D-Aspartate Receptor

Neomycin appears as a full agonist and spermidine as a partial agonist at the site where polyamines enhance 1-[1-(2-thienyl)cyclohexyl][3H]piperidine ([3H]TCP) binding on the N-methyl-D-aspartate (NMDA) receptor. Other aminoglycosides also enhance [3H]TCP binding with efficacies roughly proportional to the number of primary amine groups. The polyamine antagonists ifenprodil and arcaine inhibit enhancement of [3H]TCP binding by spermidine or neomycin. The inhibition of [3H]TCP binding by arcaine is apparently competitively reduced by neomycin and spermidine, supporting a common site. Diethylenetriamine (previously described as a polyamine antagonist) may be a partial agonist. Enhancement by neomycin or spermidine is not additive to that of Mg2+, consistent with competition of Mg2+ and spermidine or neomycin at the site where these compounds enhance [3H]TCP binding. Polyamines also enhance the binding of the competitive antagonist 2-(2-carboxypiperazin-4-yl)[3H]propyl-1-phosphonic acid ([3H]CPP). Neomycin, which does not enhance [3H]CPP binding, inhibits the enhancement by spermidine. That this site is distinct from the site where spermidine and neomycin increase [3H]TCP binding is supported by different pharmacology. Arcaine and diethylenetriamine do not inhibit spermidine enhancement of [3H]CPP binding. Mg2+ also does not compete with the spermidine enhancement of [3H]CPP binding. Ifenprodil inhibits the spermidine enhancement of [3H]CPP binding. The data suggest two or more polyamine sites, with arcaine selective for the site that enhances [3H]TCP binding. Neomycin is an agonist at one polyamine site and antagonist to the second.     

Novel positive allosteric modulators of the human α7 nicotinic acetylcholine receptor

The pharmacological activity of a series of novel amide derivatives was characterized on several nicotinic acetylcholine receptors (AChRs). Ca(2+) influx results indicate that these compounds are not agonists of the human (h) α4β2, α3β4, α7, and α1β1γδ AChRs; compounds 2-4 are specific positive allosteric modulators (PAMs) of hα7 AChRs, whereas compounds 1-4, 7, and 12 are noncompetitive antagonists of the other AChRs. Radioligand binding results indicate that PAMs do not inhibit binding of [(3)H]methyllycaconitine but enhance binding of [(3)H]epibatidine to hα7 AChRs, indicating that these compounds do not directly, but allosterically, interact with the hα7 agonist sites. Additional competition binding results indicate that the antagonistic action mediated by these compounds is produced by direct interaction with neither the phencyclidine site in the Torpedo AChR ion channel nor the imipramine and the agonist sites in the hα4β2 and hα3β4 AChRs. Molecular dynamics and docking results suggest that the binding site for compounds 2-4 is mainly located in the inner β-sheet of the hα7-α7 interface, ～12 ? from the agonist locus. Hydrogen bond interactions between the amide group of the PAMs and the hα7 AChR binding site are found to be critical for their activity. The dual PAM and antagonistic activities elicited by compounds 2-4 might be therapeutically important.     

Modulation of glutamate-induced uncompetitive blocker binding to the NMDA receptor by temperature and by glycine

The effect of temperature on the binding of [3H]-N-[1-(2-thienyl)cyclohexyl]piperidine [( 3H]TCP) to the ion channel of the N-methyl-D-aspartate (NMDA) receptors was studied in washed rat brain-cortex membranes. Raising the temperature from 5 to 33 degrees C resulted in a significant increase in the association rates of [3H]TCP binding measured in the presence of 1 microM glutamate and 1 microM glycine, but was less effective in the absence of the added agonists. No such effects of temperature on the dissociation rates of [3H]TCP-receptor complexes were observed. In the absence of agonists, neither the association nor the dissociation binding components varied with temperature, suggesting a diffusion-controlled limitation of access of the ligand to its site within the nonactivated NMDA receptor. No evidence was found for a temperature-dependent change in the density of [3H]TCP binding sites or for heterogeneity of [3H]TCP binding sites associated with the NMDA receptor, even though when approaching equilibrium the binding kinetics in the presence of glutamate and glycine deviated from an ordinary bimolecular reaction scheme. The data were fitted instead to a two-exponent binding function, comprising the sum of a fast and a slow binding component. Their corresponding time constants exhibited an increase with temperature, and the increase of each one was correlated significantly with the corresponding decrease in the equilibrium binding constant; however, there was no temperature-related change in the relative proportions of the two components, with the fast binding component (alpha) accounting for 50-70% of the site population.(ABSTRACT TRUNCATED AT 250 WORDS)     

Multiple mode of binding of phencyclidines: high affinity association between phencyclidine receptors in rat brain and a monovalent ion-sensitive polypeptide

Two populations of phencyclidine (PCP) binding sites are shown to exist in the rat brain: a high-affinity monovalent ion-sensitive site (Kd of 10-14 nM for [3H]TCP, [3H]N-[1-(2-thienyl)cyclohexyl]piperidine), which exists in both the frontal cortex and the hippocampus, and a lower affinity site (Kd of 80-130 nM for [3H]TCP) which is found in the hippocampus but not in the frontal cortex. The nature of the interactions between the ion-binding sites and the high affinity PCP receptors depend on both ligand structure (PCP or TCP) and the ion involved (K' or Na'). The high-affinity sites are associated with an Mr 90,000 polypeptide whose labeling by [3H]azido phencyclidine is selectively inhibited by monovalent ions.     

MPTP lesions of the nigrostriatal dopaminergic projection decrease [3H]1-[1-(2-thienyl)cyclohexyl]-piperidine binding to PCP site 2: Further evidence that PCP site 2 is associated with the biogenic amine reuptake complex

Our previous studies have demonstrated that, using membranes of guinea pig brain, [³H]1-[1-(2-thienyl)cyclohexyl]piperidine ([³H]TCP) labels not only the phencyclidine binding site associated with the NMDA receptor (PCP site 1), but also a second high affinity binding site which is associated with the biogenic amine reuptake carrier (termed PCP site 2). To test this hypothesis, the binding of [³H]GBR12935 to the dopamine transporter, and [³H]TCP binding to PCP sites 1 and 2 were measured in caudates harvested from control MPTP-treated and reserpine-treated dogs. MPTP treatment decreased dopamine levels by over 99%, decreased [³H]GBR12935 binding by over 90%, decreased [³H]TCP binding to PCP site 2 by about 50%, and had no significant effect on [³H]TCP binding to PCP site 1. These data are consistent with hypothesis that a portion of PCP site 2 is associated with dopaminergic nerve, terminals in dog caudate.