Potentiation and inhibition of neuronal nicotinic receptors by atropine: competitive and noncompetitive effects

Atropine, the classic muscarinic receptor antagonist, inhibits ion currents mediated by neuronal nicotinic acetylcholine receptors expressed in Xenopus laevis oocytes. At the holding potential of -80 mV, 1 microM atropine inhibits 1 mM acetylcholine-induced inward currents mediated by rat alpha2beta2, alpha2beta4, alpha3beta2, alpha3beta4, alpha4beta2, alpha4beta4, and alpha7 nicotinic receptors by 12-56%. Inward currents induced with a low agonist concentration are equally inhibited (alpha3beta2, alpha3beta4), less inhibited (alpha2beta4, alpha7), or potentiated (alpha4beta2, alpha4beta4) by 1 microM atropine. Effects on the more sensitive alpha4beta4 nicotinic receptors were investigated in detail by systematic variation of acetylcholine and atropine concentrations and of membrane potential. At high agonist concentration, atropine inhibits alpha4beta4 nicotinic receptor-mediated ion current in a noncompetitive, voltage-dependent way with IC50 values of 655 nM at -80 mV and of 4.5 microM at -40 mV. At low agonist concentration, 1 microM atropine potentiates alpha4beta4 nicotinic receptor-mediated ion current. This potentiating effect is surmounted by high concentrations of acetylcholine, indicating a competitive interaction of atropine with the nicotinic receptor, and potentiation is also reversed at high atropine concentrations. Steady state effects of acetylcholine and atropine are accounted for by a model for combined receptor occupation and channel block, in which atropine acts on two distinct sites. The first site is associated with noncompetitive ion channel block. The second site is associated with competitive potentiation, which appears to occur when the agonist recognition sites of the receptor are occupied by acetylcholine and atropine. The apparent affinity of atropine for the agonist recognition sites of the alpha4beta4 nicotinic acetylcholine receptor is estimated to be 29.9 microM.     

Blockage of muscle and neuronal nicotinic acetylcholine receptors by fluoxetine (Prozac)

Fluoxetine (Prozac), a widely used antidepressant, is said to exert its medicinal effects almost exclusively by blocking the serotonin uptake systems. The present study shows that both muscle and neuronal nicotinic acetylcholine receptors are blocked, in a noncompetitive and voltage-dependent way, by fluoxetine, which also increases the rate of desensitization of the nicotinic receptors. Because these receptors are very widely distributed in the both central and peripheral nervous systems, the blocking action of fluoxetine on nicotinic receptors may play an important role in its antidepressant and other therapeutical effects. Our findings will help to understand the mode of action of fluoxetine, and they may also help to develop more specific medicinal drugs.     

Quantitative measurement of calcium flux through muscle and neuronal nicotinic acetylcholine receptors

A new approach was developed to determine quantitatively the fraction of current carried by Ca2+ through an ion channel under physiological conditions. This approach entails the simultaneous measurement of membrane current and intracellular Ca2+ for single cells. Whole-cell patch-clamp techniques were used to measure current, and intracellular Ca2+ was monitored with the fluorescent indicator fura-2. To obtain a quantitative measure of the fraction of current carried by Ca2+, a cell-by-cell calibration method was devised to account for differences among cells in such factors as cellular volume and Ca2+ buffering. The method was used to evaluate the Ca2+ flux through muscle and neuronal nicotinic ACh receptors (nAChRs). In a solution containing 2.5 mM Ca2+ at a holding potential of -50 mV, Ca2+ carries 2.0% of the inward current through muscle nAChRs from BC3H1 cells and 4.1% of the inward current through neuronal nAChRs from adrenal chromaffin cells. The Ca2+ flux through neuronal nAChRs of adrenal chromaffin cells is insensitive to alpha-bungarotoxin. The influx of Ca2+ is voltage dependent, and because of the Ca2+ concentration difference across the cellular membrane, there is Ca2+ influx into the cell even when there is a large net outward current. At both muscle and neuronal cholinergic synapses, activity-dependent Ca2+ influx through nicotinic receptors produces intracellular signals that may have important roles in synaptic development, maintenance, and plasticity.     

Arrest of subunit folding and assembly of nicotinic acetylcholine receptors in cultured muscle cells by dithiothreitol

In this study we have used cultured muscle cells to investigate the role of disulfide bond formation in the sequence of molecular events leading to nicotinic acetylcholine receptor (AChR) assembly and surface expression. We have observed that disulfide bond formation in newly synthesized AChR alpha-subunits occurs 5-20 min after translation and that this modification can be blocked by dithiothreitol (DTT), a membrane-permeant thiol-reducing agent. DTT treatment was found to arrest AChR alpha-subunit conformational maturation, assembly, and appearance on the cell surface, showing that these events are dependent on prior formation of disulfide bonds. Subunits prevented from maturation by the reducing agent do not irreversibly misfold or aggregate, since upon removal of DTT, AChR alpha-subunits undergo formation of disulfide bonds and resume folding, oligomerization, and surface expression. We have previously found that nascent alpha-subunits form transient complexes with the molecular chaperone calnexin immediately after subunit synthesis (Gelman, M.S., Chang, W., Thomas, D. Y., Bergeron, J. J. M., and Prives, J. M. (1995) J. Biol. Chem. 270, 15085-15092) and have now observed that both the formation and the subsequent dissociation of these complexes are unaffected by DTT treatment. Thus, alpha-subunits appear to dissociate from calnexin independently of their undergoing disulfide bond formation and achieving conformational maturation. This finding together with the absence of irreversible misfolding of DTT-arrested alpha-subunits suggests that calnexin may act to prevent misfolding by aiding in the initial folding events and is not an essential participant in the late stages of alpha-subunit maturation.     

d-Tubocurarine accentuates the burn-induced upregulation of nicotinic acetylcholine receptors at the muscle membrane

BACKGROUND: Increases in acetylcholine receptors (AChRs) at the muscle membrane, induced by burn injury, have been associated with a hyperkalemic response to succinylcholine and resistance to d-tubocurarine-like drugs. Muscle relaxants often are administered to burn-injured patients in the intensive care unit to facilitate mechanical ventilation. This study in rats tested whether continuous administration of d-tubocurarine in subparalytic doses exaggerates the upregulation of AChRs induced by burn trauma. Subparalytic doses were used to avoid the confounding effects of immobilization. METHODS: Three days after an approximate 50% body surface area burn or sham injury, the animals received an infusion of 3.03 +/- 0.05 micrograms/h of d-tubocurarine or equal volume of saline directly to the left gastrocnemius muscle via catheter connected to a subcutaneously implanted osmotic pump. After 7 days of d-tubocurarine or saline infusion, the AChRs were quantitated using 125I-alpha-bungarotoxin. The AChRs on the d-tubocurarine or saline-infused left gastrocnemius were compared to the contralateral gastrocnemius in the same group. The right or left gastrocnemius AChRs were compared to the ipsilateral muscles between groups. These intra- and intergroup comparisons allowed the delineation of the effects of catheter irritation, burns, or d-tubocurarine on AChRs. RESULTS: Daily examination of the withdrawal response to toe-pinch revealed no evidence of paralysis. Weight loss in the burn-injury animals receiving d-tubocurarine or saline was similar, confirming that the infusion of d-tubocurarine did not impair the mobility of the animals to move and feed. The plasma d-tubocurarine concentration after 7 days of infusion was 26.0 +/- 12 ng/ml (mean +/- SE). Regardless of burn or sham injury or of d-tubocurarine or saline infusion, the concentration of AChRs on the left was consistently greater than in the contralateral right gastrocnemius muscles within the same group, indicating that manipulation of the area alone can result in upregulation of AChRs. The AChRs in the right gastrocnemius of burn-injured animals were greater than those in the same muscle of sham-injured animals, regardless of saline (7.24 +/- 0.9 vs. 5.7 +/- 0.5 fmoles/mg protein, P = 0.06) or d-tubocurarine (7.3 +/- 0.4 vs. 5.7 +/- 0.5, P < 0.05) infusion to the burn-injury groups. AChRs in the left gastrocnemius of burn-injury animals receiving d-tubocurarine were significantly greater than those in burn- or sham-injury animals receiving saline (13.9 +/- 1.1 vs. 9.8 +/- 1.2 and 7.1 +/- 0.5 fmoles/mg protein, respectively, P < 0.05). CONCLUSIONS: Burn-induced upregulation of AChRs is accentuated by infusion of subparalytic doses of d-tubocurarine. Concomitant administration of d-tubocurarine to burn-injured patients may result in further exaggeration of the aberrant responses to neuromuscular relaxants.     

Epibatidine binds with unique site and state selectivity to muscle nicotinic acetylcholine receptors

Ligand binding sites in fetal (alpha2betagammadelta) and adult (alpha2betadeltaepsilon) muscle acetylcholine receptors are formed by alphadelta, alphagamma, or alphaepsilon subunit pairs. Each type of binding site shows unique ligand selectivity due to different contributions by the delta, gamma, or epsilon subunits. The present study compares epibatidine and carbamylcholine binding in terms of their site and state selectivities for muscle receptors expressed in human embryonic kidney 293 cells. Measurements of binding to alphagamma, alphadelta, and alphaepsilon intracellular complexes reveal opposite site selectivities between epibatidine and carbamylcholine; for epibatidine the rank order of affinities is alphaepsilon > alphagamma > alphadelta, whereas for carbamylcholine the rank order is alphadelta congruent with alphaepsilon > alphagamma. Because the relative affinities of intracellular complexes resemble those of receptors in the closed activable state, the results suggest that epibatidine binds with unique site selectivity in activating the muscle receptor. Measurements of binding at equilibrium show that both enantiomers of epibatidine bind to adult and fetal receptors with shallow but monophasic binding curves. However, when receptors are fully desensitized, epibatidine binds in a biphasic manner, with dissociation constants of the two components differing by more than 170-fold. Studies of subunit-omitted receptors (alpha2betadelta2, alpha2betagamma2, and alpha2betaepsilon2) reveal that in the desensitized state, the alphadelta interface forms the low affinity epibatidine site, whereas the alphagamma and alphaepsilon interfaces form high affinity sites. In contrast to epibatidine, carbamylcholine shows little site selectivity for desensitized fetal or adult receptors. Thus epibatidine is a potentially valuable probe of acetylcholine receptor binding site structure and of elements that confer state-dependent selectivities of the binding sites.     

Structure and function of glutamate and nicotinic acetylcholine receptors

The past year has seen remarkable progress in defining the structure of various ligand-gated ion channels. Images of opened and closed nicotinic acetylcholine receptors at 9 A resolution have now made it easier to identify the conformational changes underlying gating. In addition, recent studies on glutamate receptors have led to a radical revision of their postulated transmembrane topology: models for agonist-binding and allosteric domains now use sites previously thought to lie in cytoplasmic loops. Other areas that are being actively pursued include identification of the amino acids lining the ion channels, accurate measurements of Ca2+ fluxes, and tests of transmembrane topology in kainate receptor subunits.     

Immunohistochemical localization of nicotinic acetylcholine receptors in the guinea pig bowel and pancreas

Although nicotinic acetylcholine receptors (nAChRs) are known to be present on neural elements in both the bowel and the pancreas, the precise location of these receptors has not previously been determined. Immunocytochemistry, by using a rat monoclonal antibody (mAb35), which recognizes alpha-bungarotoxin (alpha-Bgt)-insensitive nAChRs, and a polyclonal antibody raised against the alpha-Bgt-sensitive receptor subunit, alpha7, was used to locate receptor protein in guinea pig gut and pancreas. mAb35-receptor (mAb35-R) immunoreactivity was abundant in both enteric plexuses, enterochromaffin cells, and pancreatic ganglia. Immunostaining was associated with the cell membrane, and clusters of mAb35-R were observed on cell somas and dendrites. Receptor immunoreactivity was also observed on terminals and axons, suggesting that a subset of nAChRs is presynaptic. Internal sites of mAb35-R were observed in permeabilized ganglia. Cells expressing the receptors were closely associated with ChAT-immunoreactive nerve fibers. In addition, the majority of ChAT-positive neurons expressed both cell surface and internal stores of mAb35-R. In the bowel, clusters of mAb35-R were present on the soma and dendrites of Dogiel type I motorneurons and secretomotor neurons. Receptors were detected at the plasma membrane of calbindin-immunoreactive myenteric neurons. In contrast, calbindin-immunoreactive submucosal neurons did not express cell surface mAb35-R, supporting the idea that they are sensory neurons. A subset of enteric neurons expressed both mAb35-R and glutamate receptor (GluR1) immunoreactivity. In the pancreas, mAb35-R immunoreactivity was only observed in ganglia. Alpha7-immunoreactivity was found on both enteric cell bodies and nerve fibers. Based on these results, it appears that visceral nAChRs are composed of at least four subunits and that both pre- and postsynaptic nAChRs are present in the gut and pancreas.     

alpha-Conotoxin ImI exhibits subtype-specific nicotinic acetylcholine receptor blockade: preferential inhibition of homomeric alpha 7 and alpha 9 receptors

Through a study of cloned nicotinic receptors expressed in Xenopus oocytes, we provide evidence that alpha-conotoxin ImI, a peptide marine snail toxin that induces seizures in rodents, selectively blocks subtypes of nicotinic acetylcholine receptors. alpha-Conotoxin ImI blocks homomeric alpha 7 nicotinic receptors with the highest apparent affinity and homomeric alpha 9 receptors with 8-fold lower affinity. This toxin has no effect on receptors composed of alpha 2 beta 2, alpha 3 beta 2, alpha 4 beta 2, alpha 2 beta 4, alpha 3 beta 4, or alpha 4 beta 4 subunit combinations. In contrast to alpha-bungarotoxin, which has high affinity for alpha 7, alpha 9, and alpha 1 beta 1 gamma delta receptors, alpha-conotoxin ImI has low affinity for the muscle nAChR. Related Conus peptides, alpha-conotoxins MI and GI, exhibit a distinct specificity, strictly targeting the muscle subtype receptor but not alpha 7 or alpha 9 receptors. alpha-Conotoxins thus represent selective tools for the study of neuronal nicotinic acetylcholine receptors.     

Fast synaptic signaling by nicotinic acetylcholine and serotonin 5-HT3 receptors in developing visual cortex

Cholinergic and serotonergic fiber systems invade the developing visual cortex several weeks before eye opening; both transmitters have been implicated in plasticity of neocortical circuits. These transmitters have been presumed to act predominantly through second messenger-coupled receptors, because fast cholinergic or serotonergic neurotransmission has never been observed in neocortex. However, acetylcholine and serotonin also act on ligand-gated ion channels; the nicotinic acetylcholine receptor and the serotonin 5-HT3 receptor, respectively. Here, using whole-cell patch-clamp techniques in developing ferret visual cortex, we pharmacologically isolated fast, spontaneous, and evoked cholinergic and serotonergic synaptic events in pyramidal cells and interneurons of all cortical layers. The number of cells receiving such inputs increased with the ingrowth of thalamic afferents, and the frequencies of the spontaneous events increased at eye opening. Thus, both acetylcholine and serotonin can mediate fast synaptic transmission in the visual cortex; the early onset of these mechanisms suggests a role during initial stages of circuit formation and during subsequent experience-dependent remodeling of cortical connections.     

Pharmacological properties of nicotinic acetylcholine receptors on adrenal chromaffin cells and their modification by hypoxic exposure

To characterize the properties of nicotinic acetylcholine receptors (nAChRs) in autonomic ganglia, we examined specific L-[3H]nicotine binding to membrane fraction prepared from cultured bovine adrenal chromaffin cells, using a modified filtration method. Binding of L-[3H]nicotine to non-treated glass fiber filters interfered with detection of specific binding to the membrane fraction. Presoaking the glass fiber filters in 3% or greater concentrations of polyethyleneimine solution (sixty times higher than the reported concentration) for more than 5 h could reduce the binding of L-[3H]nicotine to the filters to background level. Furthermore, specific L-[3H]nicotine binding to the membrane fraction was detected only when the membrane fraction was prepared in buffer containing no divalent cations such as Ca2+ and Mg2+ (EDTA and EGTA were added) and protease inhibitors. Specific binding of L-[3H]nicotine was saturable and reversible. Scatchard analysis revealed a single class of high affinity binding sites with an average Kd of 8.7 nM and a Bmax of 43.2 fmol/mg protein. Specific binding was sensitive to cholinergic agonists (carbamylcholine and L-nicotine) and ganglionic stimulating agents (lobeline and DMPP), but was resistant to neuromuscular blocking agents (alpha-bungarotoxin, d-tubocurarine) and hexamethonium. These results suggest that high-affinity nicotine binding sites on adrenal chromaffin cells are nAChRs of ganglion-type, which have properties different from nAChRs on the neuromuscular junction but similar to nAChRs in the brain.     

Critical elements determining diversity in agonist binding and desensitization of neuronal nicotinic acetylcholine receptors

To identify the molecular determinants underlying the pharmacological diversity of neuronal nicotinic acetylcholine receptors, we compared the alpha7 homo-oligomeric and alpha4beta2 hetero-oligomeric receptors. Sets of residues from the regions initially identified within the agonist binding site of the alpha4 subunit were introduced into the alpha7 agonist binding site, carried by the homo-oligomeric alpha7-V201-5HT3 chimera. Introduction of the alpha4 residues 183-191 into alpha7 subunit sequence (chimera C2) selectively increased the apparent affinities for equilibrium binding and for ion channel activation by acetylcholine, resulting in a receptor that no longer displays differences in the responses to acetylcholine and nicotine. Introduction of the alpha4 residues 151-155 (chimera B) produced a approximately 100-fold increase in the apparent affinity for both acetylcholine and nicotine in equilibrium binding measurements. In both cases electrophysiological recordings revealed a much smaller increase (three- to sevenfold) in the apparent affinity for activation, but the concentrations required to desensitize the mutant chimeras parallel the shifts in apparent binding affinity. The data were fitted by a two-state concerted model, and an alteration of the conformational isomerization constant leading to the desensitized state accounts for the chimera B phenotype, whereas alteration of the ligand binding site accounts for the chimera C2 phenotype. Point mutation analysis revealed that several residues in both fragments contribute to the phenotypes, with a critical effect of the G152K and T183N mutations. Transfer of alpha4 amino acids 151-155 and 183-191 into the alpha7-V201-5HT3 chimera thus confers physiological and pharmacological properties typical of the alpha4beta2 receptor.     

Pharmacology of the nicotinic acetylcholine receptor from fetal rat muscle expressed in Xenopus oocytes

BACKGROUND: Firefly luciferase is a 62 kDa protein that catalyzes the production of light. In the presence of MgATP and molecular oxygen, the enzyme oxidizes its substrate, firefly luciferin, emitting yellow-green light. The reaction proceeds through activation of the substrate to form an adenylate intermediate. Firefly luciferase shows extensive sequence homology with a number of enzymes that utilize ATP in adenylation reactions. RESULTS: We have determined the crystal structure of firefly luciferase at 2.0 A resolution. The protein is folded into two compact domains. The large N-terminal domain consists of a beta-barrel and two beta-sheets. The sheets are flanked by alpha-helices to form an alphabetaalphabetaalpha five-layered structure. The C-terminal portion of the molecule forms a distinct domain, which is separated from the N-terminal domain by a wide cleft. CONCLUSIONS: Firefly luciferase is the first member of a superfamily of homologous enzymes, which includes acyl-coenzyme A ligases and peptide synthetases, to have its structure characterized. The residues conserved within the superfamily are located on the surfaces of the two domains on either side of the cleft, but are too far apart to interact simultaneously with the substrates. This suggests that the two domains will close in the course of the reaction. Firefly luciferase has a novel structural framework for catalyzing adenylate-forming reactions.     

Calcium-dependent desensitizing function of the postsynaptic neuronal-type nicotinic acetylcholine receptors at the neuromuscular junction

Several subunits that commonly have been regarded as neuronal-type nicotinic acetylcholine receptor (nAChR) subtypes, have been found in the postjunctional endplate membrane of adult skeletal muscle fibres. The postsynaptic function of these neuronal-type nAChR subtypes at the neuromuscular junction has been investigated by using aequorin luminescence and fluorescence confocal imaging. A biphasic elevation of intracellular Ca2+ is elicited by prolonged nicotinic action at the mouse muscle endplates. The fast and slow Ca2+ components are operated by a postsynaptic muscle- and colocalized neuronal-type nAChR, respectively. Neuromuscular functions may be regulated by a dual nAChR system to maintain the normal postsynaptic excitability. Certain neuronal-type nAChR may be endowed with the same functional role in the central nervous system also.     

Effect of immobilization on skeletal muscle nicotinic cholinergic receptors in the rat

The effect of 4 weeks of hind limb immobilization on nicotinic acetylcholinergic receptors (nAChRs) in the neuromuscular junction of the soleus (SOL) and tibialis anterior (TIB) muscles was studied in rats. Quantitative measurements of the receptors was performed using [3H]alpha-bungarotoxin ([3H]alpha-BTx) receptor autoradiography. Junctional and extrajunctional nAChRs were significantly increased in the SOL and TIB after 4 weeks immobilization. However, a significant decrease in fiber cross-sectional area was observed only in the SOL muscle. Remobilization for 4 weeks reversed the changes in cholinergic receptors and muscle fibers but not in bone. Our findings suggested that lack of nerve impulses are of importance for the events that take place after immobilization leading to muscle atrophy and osteoporosis.