ACh Binding Research Articles

The anthelmintic pyrantel acts as a low efficacious agonist and an open-channel blocker of mammalian acetylcholine receptors

Pyrantel is an anthelmintic which acts as an agonist of nicotinic receptors (AChRs) of nematodes and exerts its therapeutic effects by depolarizing their muscle membranes. Here we explore at the single-channel level the action of pyrantel at mammalian muscle AChR. AChR currents are elicited by pyrantel. However, openings do not appear in clearly identifiable clusters over a range of pyrantel concentrations (1–300 μM). The mean open time decreases as a function of concentration, indicating an additional open-channel block. Single-channel recordings in the presence of high ACh concentrations and pyrantel demonstrate that the anthelmintic acts as a high-affinity open-channel blocker. When analyzed in terms of a sequential blocking scheme, the calculated forward rate constant for the blocking process is 8×10 7 M −1 s −1, the apparent dissociation constant is 8 μM at a membrane potential of −70 mV and the process is voltage dependent. Pyrantel displaces α-bungarotoxin binding but the concentration dependence of equilibrium binding is shifted towards higher concentrations with respect to that of ACh binding. Thus, by acting at the binding site pyrantel activates mammalian AChRs with low efficacy, and by sterical blockade of the pore, the activated channels are then rapidly inhibited.

Rearrangement of Nicotinic Receptor α Subunits during Formation of the Ligand Binding Sites

Muscle nicotinic acetylcholine receptors (AChRs) are pentamers that contain two alpha subunits a beta, gamma (or epsilon), and delta subunit. In this paper, we have characterized subunit processing and folding events leading to formation of the two AChR ligand binding sites. alpha subunit residues, 187-199, which are part of overlapping ACh and alpha-bungarotoxin (Bgt) binding sites on AChRs, were assayed using a monoclonal antibody (mAb) specific for these residues. We found that this region was inaccessible to the mAb early during AChR assembly but became accessible as the first of two Bgt binding sites formed later during assembly, indicating that the region changes conformation as the Bgt binding site appears. Without previous reduction, 20% of the alpha subunits could be alkylated by bromoacetylcholine bromide as the first ACh binding site formed, which further indicated that the disulfide bond between cysteines 192 and 193 does not form until the first ACh binding site appears soon after Bgt binding site formation. When alpha subunits were mutated to add a glycosylation site at residue 187, the number of Bgt binding sites increased threefold, AChRs assembled more efficiently, and 2.5-fold more AChRs reached the cell surface. Our results indicate that binding site formation involves a rate-limiting rearrangement of the alpha subunit that exposes the 187-199 region to the endoplasmic reticulum lumen and determines when cysteines 192 and 193 disulfide bond.

Human α6 AChR subtypes: subunit composition, assembly, and pharmacological responses

Many nicotinic acetylcholine receptor (AChR) subunits are known to be co-expressed with the α6 subunit in neurons. Because α6β4 AChRs assemble inefficiently and α6β2 AChRs not at all, more complex mixtures of human subunit cDNAs were tested for their abilities to form functional AChRs when expressed in Xenopus oocytes. α6β4β3 AChRs produced the largest and most consistent responses. α6α3β2 AChRs exhibited reduced potency for ACh and increased potency and efficacy for nicotine compared to α3β2 AChRs, but similar resistance to functional inactivation after prolonged exposure to nicotine. α6α4β2 AChRs differed little in potency or efficacy for ACh or nicotine compared to α4β2 AChRs, and had similarly high sensitivity to inactivation by prolonged exposure to nicotine. Co-expression of α6 and β2 cRNAs resulted in large numbers of 3H-epibatidine binding sites in the form of large aggregates but not in functional pentameric AChRs. Co-expression of α6, β2, and α5 resulted in assembly of some functional pentameric AChRs. Chimeras with the large extracellular domain of α6 and the rest from either α3 or α4 efficiently formed functional AChRs. Thus, the extracellular domain of α6 efficiently assembles with β2 to form ACh binding sites, but more C-terminal domains cause difficulties in forming pentameric AChRs. Chimeric α6/α3 and α6/α4 AChRs containing either β2 or β4 subunits were blocked by α-conotoxin MII which had previously been reported to be specific for α3β2 AChRs.

Nicotinic receptor fourth transmembrane domain: hydrogen bonding by conserved threonine contributes to channel gating kinetics.

The fourth transmembrane domain (M4) of the nicotinic acetylcholine receptor (AChR) contributes to the kinetics of activation, yet its close association with the lipid bilayer makes it the outermost of the transmembrane domains. To investigate mechanistic and structural contributions of M4 to AChR activation, we systematically mutated alphaT422, a conserved residue that has been labeled by hydrophobic probes, and evaluated changes in rate constants underlying ACh binding and channel gating steps. Aromatic and nonpolar mutations of alphaT422 selectively affect the channel gating step, slowing the rate of opening two- to sevenfold, and speeding the rate of closing four- to ninefold. Additionally, kinetic modeling shows a second doubly liganded open state for aromatic and nonpolar mutations. In contrast, serine and asparagine mutations of alphaT422 largely preserve the kinetics of the wild-type AChR. Thus, rapid and efficient gating of the AChR channel depends on a hydrogen bond involving the side chain at position 422 of the M4 transmembrane domain.

Nicotinic receptors at the amino acid level.

nAChRs are pentameric transmembrane proteins into the superfamily of ligand-gated ion channels that includes the 5HT3, glycine, GABAA, and GABAC receptors. Electron microscopy, affinity labeling, and mutagenesis experiments, together with secondary structure predictions and measurements, suggest an all-beta folding of the N-terminal extracellular domain, with the connecting loops contributing to the ACh binding pocket and to the subunit interfaces that mediate the allosteric transitions between conformational states. The ion channel consists of two distinct elements symmetrically organized along the fivefold axis of the molecule: a barrel of five M2 helices, and on the cytoplasmic side five loops contributing to the selectivity filter. The allosteric transitions of the protein underlying the physiological ACh-evoked activation and desensitization possibly involve rigid body motion of the extracellular domain of each subunit, linked to a global reorganization of the transmembrane domain responsible for channel gating.

Photoaffinity labeling of Torpedo nicotinic receptor with the agonist [3H]DCTA: identification of amino acid residues which contribute to the binding of the ester moiety of acetylcholine.

Torpedo marmorata acetylcholine binding sites were photolabeled using 360 nm light, at equilibrium in the desensitized state, with the agonist [3H]DCTA utilizing the CeIV/glutathione procedure described previously (Grutter, et al. (1999) Biochemistry 38, 7476-7484). Photoincorporation of [3H]DCTA was concentration-dependent with a maximum of 7.5% specific labeling on the alpha-subunit and 1.2% on the gamma-subunit. The apparent dissociation constants for labeling of the alpha- and gamma-subunits were 2.2 +/- 1.1 and 3.6 +/- 2.8 microM, respectively. The alpha-chains isolated from receptor-rich membranes photolabeled in the absence or in the presence of carbamylcholine were cleaved with CNBr using an efficient "in gel" procedure. The resulting peptide fragments were purified by HPLC and further submitted to trypsinolysis. The digest was analyzed by HPLC leading to a single radioactive peak which, by microsequencing, revealed two sequences extending from alpha Lys-179 and from alpha His-186, respectively. Radioactive signals could be unambiguously attributed to positions corresponding to residues alpha Tyr-190, alpha Cys-192, alpha Cys-193, and alpha Tyr-198. These four identified [3H]DCTA-labeled residues, which have been also labeled with other affinity and photoaffinity probes including the agonist [3H]nicotine, belong to loop C of the ACh binding site. The chemical structure of [3H]DCTA, together with its well-defined and powerful photochemical reactivity, provides convincing evidence that loop C-labeled residues are primarily involved in the interaction with the ester moiety of acetylcholine.

Alpha neurotoxins and their relatives: foes and friends?

Alpha neurotoxins and their relatives: foes and friends?

Kinetic parameters for the vesicular acetylcholine transporter: two protons are exchanged for one acetylcholine.

The vesicular acetylcholine transporter (VAChT) mediates ACh storage in synaptic vesicles by exchanging cytoplasmic ACh with vesicular protons. This study sought to determine the stoichiometry of exchange by analysis of ligand binding and transport kinetics. The effects of different pH values inside and outside, external ACh concentrations, and electrical potential gradients on ACh transport by vesicles isolated from the electric organ of Torpedo were determined using a pH-jump protocol. The equilibrium binding of a high-affinity analogue of ACh is inhibited by protonation with a pKa of 7.4 +/- 0.3. A two-proton model fits the transport data much better than a one-proton model does, and uptake increases at more positive internal electrical potential, as expected for the two-proton model. Thus, the results support the two-proton model. The transport cycle begins with binding of external ACh to outwardly oriented site 2 (KACho = 20 mM) and protonation of inwardly oriented site 1 (pKa1 = 4.73 +/- 0.05). Loaded VAChT reorients quickly (73 000 min-1) and releases ACh to the inside (KAChi = 44 000 mM) and the proton to the outside. Unloaded, internally oriented site 2 binds a proton (pKa2 = 7.0), after which VAChT reorients (150 +/- 20 min-1) in the rate-limiting step and releases the proton to the outside to complete the cycle. Rate constants for the reverse direction also were estimated. Two protons provide a thermodynamic driving force beyond that utilized in vivo, which suggests that vesicular filling is regulated. Other phenomena related to VAChT, namely the time required to fill synaptic vesicles, the fractional orientation of the ACh binding site toward cytoplasm, orientational lifetimes, and the rate of nonquantal release of ACh from cholinergic nerve terminals, were computer-simulated, and the results are compared with physiological observations.

Formation of the Nicotinic Acetylcholine Receptor Binding Sites

Nicotinic acetylcholine receptors (AChRs) are activated by ACh binding to two sites located on different alpha subunits. The two alpha subunits, alpha gamma and alpha delta, are distinguished by their interface with gamma and delta subunits. We have characterized the formation of the ACh binding sites and found, contrary to the current model, that the sites form at different times and in a set order. The first site forms on alpha gamma subunits during the process of subunit assembly. Our data are consistent with the appearance of this site on alpha beta gamma delta subunit tetramers soon after the site for the competitive antagonist alpha-bungarotoxin has formed and delta subunits have assembled with alpha beta gamma trimers. The second site is located on alpha delta subunits and forms after AChR subunits have assembled into alpha2 beta gamma delta pentamers. By determining the order in which the ACh binding sites form, we have also identified the sites in which the delta and second alpha subunits associate during subunit assembly.

Neostigmine competitively inhibited nicotinic acetylcholine receptors in sympathetic neurons

The present experiment investigates the effect of neostigmine on nicotinic acetylcholine receptors (nAChRs) in the cultured neurons from neonatal rat superior cervical ganglia (SCG). Using whole-cell patch clamp techniques, we found that the amplitudes of the currents induced by 50 μM dimethylphenylpiperazinium (DMPP) were 21.5 ± 10.7%, 52.9 ± 9.2% and 86.9 ± 4.9% depressed at the increased concentrations of neostigmine 100, 200 and 400 μM, respectively. The inhibition of neostigmine decreased gradually with the increased concentration of nicotine from 10 to 160 μM. Lineweaver-Burk's double-reversible plot illustrated that neostigmine blocked neuronal nAChRs in a competitive manner. Hyperpolarization of membrane potential from −40 mV to −100 mV did not significantly influence the blockade of neostigmine. Neostigmine could not accelerate the decay of the DMPP-induced currents, neither evoke any detectable currents in SCG neurons. The results indicate that neostigmine depress neuronal nAChRs in a competitive, concentration-dependent and voltage-independent manner, and can not facilitate desensitization of the receptors. The present data suggest that neostigmine blocks neuronal nAChRs by interacting with the ACh binding sites of the receptors.

Interaction of d-Tubocurarine Analogs with the Mouse Nicotinic Acetylcholine Receptor

The binding of d-tubocurarine and several of its analogs to the mouse nicotinic acetylcholine receptor (AChR) was measured by competition against the initial rate 125I-alpha-bungarotoxin binding to BC3H-1 cells. The changes in affinity due to methylation or halogenation at various functional groups on d-tubocurarine was measured to both the high affinity (alphagamma-site) and the low affinity site (alphadelta-site). We show that quaternization by methylation of the 2'-N ammonium group enhances the affinity for both the acetylcholine binding sites of mouse AChR, whereas this change does not affect affinity for the Torpedo AChR sites. The effect of N-methylation suggests the presence of interactions with the ammonium moiety that cannot be readily attributed to the known conserved residues thought to stabilize this functional group. Methylation of both the 7'- and 12'-phenols produced net affinity changes at both sites. The changes resulted from contributions at both the 7'- and the 12'-positions; however, these effects were dependent on whether the ammoniums were also methylated. Substitution of bromine or iodine at the 13'-position decreased the affinity considerably to the high affinity alphagamma-site of mouse AChR, whereas the affinity for the Torpedo alphagamma-site was slightly increased. Furthermore, binding to the mouse AChR was unaffected by the conformational state, whereas these ligands strongly preferred the desensitized conformation of the Torpedo AChR. Comparison of binding changes upon 13'-halogenation to the changes in amino acid residues at the ACh binding sites of the mouse and Torpedo AChR shows mouse residue Ile-gamma116 as likely to be involved in interacting with the 13'-position of d-tubocurarine. It is predicted that this residue is involved in the conformational equilibrium between the resting and desensitized conformations.

Mutations in Different Functional Domains of the Human Muscle Acetylcholine Receptor Subunit in Patients with the Slow-Channel congenital Myasthenic Syndrome

Congenital myasthenic syndromes are a group of rare genetic disorders that compromise neuromuscular transmission. A subset of these disorders, the slow-channel congenital myasthenic syndrome (SCCMS), is dominantly inherited and has been shown to involve mutations within the muscle acetylcholine receptor (AChR). We have identified three new SCCMS mutations and a further familial case of the alpha G153S mutation. Single channel recordings from wild-type and mutant human AChR expressed in Xenopus oocytes demonstrate that each mutation prolongs channel activation episodes. The novel mutations alpha V156M, alpha T254I and alpha S269I are in different functional domains of the AChR alpha subunit. Whereas alpha T254I is in the pore-lining region, like five of six previously reported SCCMS mutations, alpha S269I and alpha V156M are in extracellular domains. alpha S269I lies within the short extracellular sequence between M2 and M3, and identifies a new region of muscle AChR involved in ACh binding/channel gating. alpha V156M, although located close to alpha G153S which has been shown to increase ACh binding affinity, appears to alter channel function through a different molecular mechanism. Our results demonstrate heterogeneity in the SCCMS, indicate new regions of the AChR involved in ACh binding/channel gating and highlight the potential role of mutations outside the pore-lining regions in altering channel function in other ion channel disorders.

Allosteric regulation of the binding of [ 3H]acetylcholine to m2 muscarinic receptors

Muscarinic receptors of the m2 subtype expressed in Chinese hamster ovary cells were labeled with [ methyl- 3H]acetylcholine([ 3H]ACh), and the rate of dissociation in the presence and absence of several compounds known to exert allosteric effects on labeled antagonist binding was observed. At 25 °, [ 3H]ACh bound to the receptors with a K d of 1.2 nM and dissociated with a half-time of 1.6 min. This binding was sensitive to appropriate concentrations of guanine nucleotide and the muscarinic antagonist N-methylscopolamine (NMS). Gallamine, tetrahydroaminoacridine, physostigmine, obidoxime, and 3,4,5-trimethoxybenzoic acid 8-(diethylamino)octyl ester (TMB-8) all inhibited the binding of [ 3H]ACh and all slowed the rate of dissociation of [ 3H]ACh in a concentration-dependent manner. However, the nature of some of the allosteric effects differed from previous studies that used other labeled ligands. In particular, TMB-8, which is very effective in slowing the dissociation of the antagonist [ 3H]NMS, had much weaker effects on the dissociation of [ 3H]ACh. Furthermore, TMB-8 was able to partially reverse the stronger effects of gallamine on the dissociation of [ 3H]ACh, consistent with the possibility that TMB-8 and gallamine share a common site on the receptor. In summary, the binding of ACh to muscarinic receptors is subject to allosteric regulation, and assays using [ 3H]ACh may be especially useful in the evaluation of potential allosteric regulators of muscarinic systems.

Cloning and sequence analysis of the candidate nicotinic acetylcholine receptor alpha subunit gene tar-1 from Trichostrongylus colubriformis

A T. colubriformis genomic library in lambda EMBL3 was screened for sequences homologous to the Caenorhabditis elegans unc-38 nicotinic acetylcholine receptor (nAChR) α-subunit gene. The candidate gene tar-1 (for Trichostrongylus acetylcholine receptor subunit gene 1) comprising 13 704 base pairs was thus identified. BLAST comparison of the sequenced clone with GenBank, followed by comparison of translated regions in six reading frames with protein databases, identified clearly defined tracts corresponding to 12 putative exons sharing high sequence homology to other nAChR genes and able to code for sequential regions of a putative nAChR α-subunit protein (tar-1). Tar-1 shares sequence similarities with over 40 nAChR subunit proteins. The highest similarity (91.6%) is with unc-38, suggesting that nAChR sequences from nematodes are closely related. The sequence includes motifs typical of these molecules including adjacent cysteine residues at the ACh binding site and four transmembrane regions. The DNA sequence presents the longest genomic tract described for this organism and should prove useful as a probe source in the search for nAChR genes from this and other nematodes and for studying the molecular mechanism of resistance to levamisole, a drug which is known to act on nAChRs of worms and which is widely used for parasite control.

B-cell activation in vitro by helper T cells specific to region alpha 146-162 of Torpedo californica nicotinic acetylcholine receptor.

We have previously mapped the T and B cell epitopes on the alpha-subunit of acetylcholine receptor (AChR) in human myasthenia gravis (MG) and in experimental autoimmune MG-susceptible (C57BL/6 (B6)) and nonsusceptible mouse strains. In addition to regions recognized by both T and B cells, the AChR alpha-subunit has regions that are recognized solely by T cells. An exclusive T cell epitope within residues alpha 146-162 of Torpedo californica (t), tAChR, plays an important role in experimental autoimmune MG pathogenesis in B6 mice. To study its function, we established, from tAChR-primed B6 mice, two t alpha 146-162-specific T cell lines (P14Th) which comprised Th2-type cells because they secreted IL-4 but not IL-2. P14Th did not recognize the corresponding region on mouse (m) AChR (m alpha 146-162). They caused in vitro differentiation of tAChR-primed B cells into plasma cells that secreted anti-AChR Abs directed, in decreasing order, against the following tAChR alpha regions: t alpha 122-138 > t alpha 134-150 > t alpha 45-60 > t alpha 170-186 > t alpha 56-71. Little or no Ab response could be detected against peptides t alpha 182-198 or t alpha 146-162 itself. The major enhancement was in the Abs against region t alpha 122-150 (spanning the t alpha 122-138/t alpha 134-150 overlap) that is involved in ACh binding. These Abs cross-reacted completely with m alpha 122-150, the corresponding region on mAChR. Therefore, t alpha 146-162-specific T cells, although unable to recognize m alpha 146-162, are nevertheless pathogenic because they help B cells responding to a tAChR region that is conserved in mAChR and involved in ACh binding. These Abs cross-react with the corresponding effector-binding region of mAChR, thereby disrupting the normal physiologic function of the mouse receptor.

The simulated binding of (+/-)-2,3-dihydro-5,6-dimethoxy-2-[[1-(phenylmethyl)-4-piperidinyl]meth yl] -1H-inden-1-one hydrochloride (E2020) and related inhibitors to free and acylated acetylcholinesterases and corresponding structure-activity analyses.

The simulated binding profiles of acetylcholine, ACh, and the inhibitor (+/-)-2,3-dihydro-5,6- dimethoxy-2-[[1-(phenylmethyl)-4-piperidinyl]methyl]-1H-inden-1-on e hydrochloride (E2020), 1, and some of its analogs to acetylcholinesterase, AChE, were determined using full force field energetics and allowing complete conformational flexibility in both the ligand and receptor. A new mode of binding of ACh to AChE was found which involves the carboxyl oxygen of ACh interacting with Gly 118 and 119. Multiple modes of binding of 1 and some of its analogs were found which include alignment models observed in previous more restricted modeling studies. The key ligand-receptor interactions identified, and the corresponding energetics, are consistent on a relative basis, with observed binding constants for both the individual isomers of each of the inhibitors, as well as among the inhibitors themselves. The multiple modes of binding of 1 to AChE arises from small changes in binding at a single subsite and also from multiple subsite changes. Thus, an independent subsite model for ligand-receptor binding holds for some modes of binding, but not for others. A comparison of the simulated AChE-1 (and analog inhibitors) binding models to the receptor-independent 3D-QSARs previously developed for this class of inhibitors reveals extensive mutual consistency. The findings from these two modeling studies provides greater guidelines for inhibitor design than can be realized from either one. The combined docking and 3D-QSAR studies permit a detailed understanding of the SAR of more than 100 compound 1 analog inhibitors. A simple molecular recognition model can also be gleaned from the docking studies. A cylindrical "plug" (the inhibitor) having a large dipole moment must sterically fit into a cylindrical hole (the active site gorge of AChE), the lining of which also has a large dipole moment. Our simulations suggest that the dynamic "back door" to the active site of AChE does not form a large enough opening for sufficiently long time periods so as to be an effective entrance/exit pathway.

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.

Mutation of the acetylcholine receptor α subunit causes a slow-channel myasthenic syndrome by enhancing agonist binding affinity

In five members of a family and another unrelated person affected by a slow-channel congenital myasthenic syndrome (SCCMS), molecular genetic analysis of acetylcholine receptor (AChR) subunit genes revealed a heterozygous G to A mutation at nucleotide 457 of the α subunit, converting codon 153 from glycine to serine (αG153S). Electrophysiologic analysis of SCCMS end plates revealed prolonged decay of miniature end plate currents and prolonged activation episodes of single AChR channels. Engineered mutant AChR expressed in HEK fibroblasts exhibited prolonged activation episodes strikingly similar to those observed at the SCCMS end plates. Single-channel kinetic analysis of engineered αG153S AChR revealed a markedly decreased rate of ACh dissociation, which causes the mutant AChR to open repeatedly during ACh occupancy. In addition, ACh binding measurements combined with the kinetic analysis indicated increased desensitization of the mutant AChR. Thus, ACh binding affinity can dictate the time course of the synaptic response, and αG153 contributes to the low binding affinity for ACh needed to speed the decay of the synaptic response.

Cholinergic signaling in the rat pineal gland.

1. Innervation of the mammalian pineal gland is mainly sympathetic. Pineal synthesis of melatonin and its levels in the circulation are thought to be under strict adrenergic control of serotonin N-acetyltransferase (NAT). In addition, several putative pineal neurotransmitters modulate melatonin synthesis and secretion. 2. In this review, we summarize what is currently known on the pineal cholinergic system. Cholinergic signaling in the rat pineal gland is suggested based on the localization of choline acetyltransferase (ChAT) and acetylcholinesterase (AChE), as well as muscarinic and nicotinic ACh binding sites in the gland. 3. A functional role of ACh may be regulation of pineal synaptic ribbon numbers and modulation of melatonin secretion, events possibly mediated by phosphoinositide (PI) hydrolysis and activation of protein kinase C via muscarinic ACh receptors (mAChRs). 4. We also present previously unpublished data obtained using primary cultures of rat pinealocytes in an attempt to get more direct information on the effects of cholinergic stimulus on pinealocyte melatonin secretion. These studies revealed that the cholinergic effects on melatonin release are restricted mainly to intact pineal glands since they were not readily detected in primary pinealocyte cultures.

A correlation between quantal content and decay time of endplate currents in frog muscles with intact cholinesterase.

1. The relationship between quantal content and prolongation of endplate currents (EPC) was studied in the frog sartorius with intact synaptic acetylcholinesterase. 2. The prolongation of EPC was more pronounced in endplates with a higher quantal content both before and after potentiation of quantal release by 4-aminopyridine (4-AP). When the quantal content of EPC was lowered, either by high Mg2+ or repetitive stimulation, the EPC decay constant was reduced. 3. A certain critical value of about 120 quanta per nerve impulse was found, at which point the decay of EPC remained constant even through the quantal content was reduced further. 4. The reduction in both density and number of postsynaptic receptors, produced by alpha-bungarotoxin and (+)-tubocurarine led to a profound reduction in EPC decay during the progressive fall in EPC amplitude in both 4-AP-treated and -untreated endplates. Both drugs are known to produce a shortening of EPC in anti-cholinesterase (anti-ChE)-treated muscles, due to a decrease in receptor density and less frequent repetitive binding of ACh. 5. It is assumed that the prolongation of multiquantal EPC is caused by an increased ACh concentration near the receptors, which may provide the opportunity for repetitive binding even with full cholinesterase activity. The critical quantum content of about 120 might be the number of quanta at which the probability of multiple release at single active zones is increased above zero.