A study of desensitization of acetylcholine receptors using nerve-released transmitter in the frog

Regulation of nicotinic acetylcholine receptors by protein phosphorylation

Neurotransmitter receptors and ion channels play a critical role in the transduction of signals at chemical synapses. The modulation of neurotransmitter receptor and ion channel function by protein phosphorylation is one of the major regulatory mechanisms in the control of synaptic transmission. The nicotinic acetylcholine receptor (nAcChR) has provided an excellent model system in which to study the modulation of neurotransmitter receptors and ion channels by protein phosphorylation since the structure and function of this receptor have been so extensively characterized. In this article, the structure of the nAcChR from the electric organ of electric fish, skeletal muscle, and the central and peripheral nervous system will be briefly reviewed. Emphasis will be placed on the regulation of the phosphorylation of nAcChR by second messengers and by neurotransmitters and hormones. In addition, recent studies on the functional modulation of nicotinic receptors by protein phosphorylation will be reviewed.

Effects of chronic prednisolone treatment on postjunctional membrane responses to agonist

Using frogs treated 1 month with prednisolone, we studied responses of the muscle postjunctional membrane to acetylcholine and carbamylcholine. In control muscles following a bath application of 3 microM neostigmine or 30 microM pyridostigmine, there was an increased depolarization response to iontophoretically applied acetylcholine or carbamylcholine. Results with prednisolone-treated frog muscle were essentially identical. In some fibers of prednisolone-treated muscle there was a decrementing response to repetitive iontophoretic application of carbamylcholine. Prolonged administration of prednisolone may accelerate desensitization of acetylcholine receptors during repetitive application of agonist.

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

1. The equilibrium relationship between acetylcholine (ACh) concentration and response (fraction of channels open), corrected for the effects of desensitization, has been estimated by single-ion-channel recording at the adult frog skeletal neuromuscular junction. At high ACh concentration channel openings occur in well-defined clusters separated by long desensitized intervals. The response, po, was estimated as the proportion of time for which a single channel was open during a cluster. 2. At negative membrane potential (-120 mV) po reached a maximum value of 0.9 at 100 microM-ACh and was half-maximum at 15 microM with a Hill slope of 1.6 at this point. At concentrations higher than 200 microM-ACh, po declined as a result of open-channel block by free ACh itself. 3. At positive membrane potentials (+100 mV) there was little channel block by ACh; po reached a maximum value of 0.41 at 500 microM-ACh, with half-maximum activation at 50 microM and Hill slope of 1.2 at this point. 4. Particular mechanisms for channel activation by ACh were fitted to the data by the method of least squares. Fits were fully determinate only if the two binding sites for ACh were assumed to be equivalent with no co-operativity in the ACh binding reactions. At negative potential the microscopic equilibrium constant for binding was K1 = K2 = 77 microM and the equilibrium constant for channel opening (opening/closing rates, beta/alpha) was 32. At positive potential the affinity was slightly higher, K = 32 microM, which confirms the view that the binding sites for ACh are outside the membrane electric field. The equilibrium constant for channel opening was reduced to 0.7 mainly as a result of the much shorter open lifetime (increased closing rate alpha) at positive potentials. 5. The data were also fitted well by very high values of beta/alpha together with a high degree of negative co-operativity or non-equivalence in ACh binding affinity (K2 much greater than K1). A good fit could also be obtained with moderate positive co-operativity combined with non-equivalence of the binding sites. 6. A mechanism that postulates a receptor with two independent gating subunits provided a poor fit to the data at negative potential. 7. The rate constants for channel opening and ACh dissociation were estimated by constraining the fitted parameters so that the burst length for channel opening was equal to its observed value at low concentrations of ACh.(ABSTRACT TRUNCATED AT 400 WORDS)

Desensitization of the nicotinic acetylcholine receptor by diisopropylfluorophosphate

The interaction of diisopropylfluorophosphate (DFP) with the nicotinic acetylcholine (ACh) receptor of Torpedo electric organ was studied, using [3H]-phencyclidine ([3H]-PCP) as a reporter probe. Phencyclidine binds with different kinetics to resting, activated, and desensitized receptor conformations. Although DFP did not inhibit binding of [3H]-ACh or 125I-alpha-bungarotoxin (BGT) to the receptor recognition sites and potentiated in a time-dependent manner [3H]-PCP binding to the receptor's high-affinity allosteric site, it inhibited the ACh- or carbamylcholine-stimulated [3H]-PCP binding. This suggested that DFP bound to a third kind of site on the receptor and affected receptor conformation. Preincubation of the membranes with DFP increased the receptor's affinity for carbamylcholine by eightfold and raised the pseudo-first-order rate of [3H]-PCP binding to that of an agonist-desensitized receptor. Accordingly, it is suggested that DFP induces receptor desensitization by binding to a site that is distinct from the recognition or high-affinity noncompetitive sites.

Forskolin counteracts the effects of the organophosphate soman at the neuromuscular junction

When neuromuscular transmission had been blocked using an organophosphate, function could be restored by treatment of the muscle with forskolin which increases the rate of desensitization of the nicotinic acetylcholine receptor. This suggests that excess post-synaptic depolarization due to acetylcholinesterase inhibition might be reversed by procedures which promote receptor desensitization.

Acceleration of desensitization by agonist pre-treatment in the snake

1. The kinetics of carbachol-induced desensitization have been studied in snake twitch-muscle fibres maintained in an isotonic potassium propionate solution and voltage clamped to +50 mV. 2. Microperfusion of carbachol (162-756 microM) induces a transient outward current which peaks within a few seconds and then slowly decays towards the base line. The time course of current decay estimates the time course of desensitization onset. 3. Brief exposure (30 s) to a 'conditioning' concentration of agonist (10.8 microM) accelerates the desensitization onset produced by exposure to higher 'test' concentrations of agonist (162-756 microM). 4. The acceleration of desensitization by pre-treatment with 10.8 microM-carbachol was independent of the duration of exposure between 15 and 60 s. This observation indicated that the mechanism responsible for the alteration in desensitization kinetics by treatment with 10.8 microM-carbachol differed from that responsible for the time-dependent development of desensitization produced in the presence of higher carbachol concentrations. 5. Pre-treatment with the muscarinic agonists, methylcholine and bethanechol, did not accelerate 216 microM-carbachol-induced desensitization, suggesting that the alteration of desensitization kinetics by pre-treatment was specific for nicotinic agonists. 6. The conditioning concentrations of carbachol (5.4-10.8 microM) produced no measurable outward current in muscle fibres voltage clamped to +50 mV. Further, in patch-clamp recordings it was observed that, with these concentrations of carbachol, there was no channel activity in many successful patches voltage clamped to +50 mV and, when present, the frequency of channel activity was very low. These results demonstrated that the alteration in desensitization was not the consequence of significant amounts of either receptor activation or desensitization produced by the conditioning concentration. 7. Exposure to 10.8 microM-carbachol for periods of up to 150 s did not change the amplitude of miniature end-plate currents recorded at end-plates voltage clamped to +50 mV. These results also demonstrated that the acceleration of desensitization by pre-treatment with conditioning concentrations of agonist was not due to partial desensitization occurring during the pre-treatment period. 8. Our results are consistent with the view that there are distinct populations of agonist binding sites on the acetylcholine receptor which separately regulate desensitization and channel opening.(ABSTRACT TRUNCATED AT 400 WORDS)

Two distinct kinetic phases of desensitization of acetylcholine receptors of clonal rat PC12 cells

1. The desensitization of nicotinic acetylcholine receptors on the PC12 sympathetic cell line was investigated by using a 22Na+ influx assay to measure receptor activation. 2. The rate of desensitization was dependent on temperature and at 4 degrees C two distinct kinetic phases were readily discernible: a rapid phase that was characterized by rate constants that were dependent on the chemical nature and concentration of the agonist, and a slower phase that was characterized by rate constants that were less dependent on these. 3. For acetylcholine, carbamylcholine and l-nicotine, the equilibrium desensitization parameter, Kdes, the concentration that produces half-maximal desensitization, was determined and compared with the corresponding value for Kact, the concentration that results in a half-maximal increase in the permeability response. For each agonist, the value of Kdes was found to be lower than Kact, a result to be expected if desensitization is associated with a higher-affinity state of the receptor than that associated with ion channel activation. Thus, extensive receptor desensitization can occur even at agonist concentrations that do not produce appreciable channel activation. Both activation and desensitization functions exhibited positive cooperativity so that each function occurs over a narrow range of agonist concentrations. 4. Following removal of the agonist, recovery from desensitization was reversible and occurred by two distinct kinetic phases characterized by rate constants that were independent of the chemical nature and concentration of the agonist that produced the desensitization. The relative contribution of each kinetic phase of recovery was, however, dependent on the duration of prior exposure to agonist. Following short incubation periods with agonist, most of the receptors were in a rapidly recovering state. With increasing duration of exposure, progressively more of the receptors were converted to a desensitized state that recovered more slowly. 5. The rate constants associated with the two kinetic phases of recovery were dependent on the recovery temperature. Following the initial rapid phase of desensitization, recovery at 4 degrees C was characterized by a time constant, t1/2, of 1.9 min, a value that was about 3-fold greater than that observed at 22 degrees C. The rate of recovery of the desensitized state achieved following equilibrium exposures to agonists was considerably more temperature dependent: recovery of this desensitized state was characterized at 4 degrees C by a t1/2 of 62 min that was about 37-fold greater than that at 22 degrees C.(ABSTRACT TRUNCATED AT 400 WORDS)

A study on early post-denervation changes of non-quantal and quantal acetylcholine release in the rat diaphragm

The d-tubocurarine (dTC) induced hyperpolarization of antiesterase-treated muscles at the endplate zone, miniature endplate potentials (mepps), resting membrane potentials (RMPs) and the input resistances of single muscle fibres (Rin) were measured in rat diaphragm at various times after denervation. The dTC-induced hyperpolarization decreased in two phases: 2 h after denervation it decreased transiently to 25%, after 4 h it had partially recovered to 60% and from 6 h it progressively decreased up to 12 h after which time it changed to depolarization. The initial fall and recovery were also present in muscles from sham-operated animals. The frequency of mepps decreased by 25% and the amplitude diminished by 10% within the first 2-4 h. After 10 h the frequency had decreased by 35% and the amplitude by 65%. After 12 h no mepps were present. The RMP was not significantly changed during the first 16 h after denervation. From 16 to 24 h the membrane became depolarized at a rate of about 1 mV/h. The input resistance of a single muscle fibre was constant for 12 h after denervation and from 12 to 24 h it increased by 25%. It is concluded that the early decrease in the dTC-induced hyperpolarization is probably due to the desensitization of acetylcholine (ACh) receptors caused by stress-activated non-quantal ACh release. The later decrease of dTC-hyperpolarization reflects a fall in the non-quantal ACh release. The depolarization of the resting membrane after denervation is related to the decrease in passive membrane permeability which is a secondary consequence of transmission failure.(ABSTRACT TRUNCATED AT 250 WORDS)

Activation of acetylcholine receptors on clonal mammalian BC3H-1 cells by high concentrations of agonist

1. Currents were recorded through acetylcholine (ACh) receptor channels on clonal BC3H-1 cells in the presence of high concentrations of ACh (20-1000 microM) and carbamylcholine (180-1000 microM). 2. Channel openings at high agonist concentrations occur in clusters separated by long silent periods (seconds). Clusters, in turn, show groups of closely spaced openings separated by relatively long (hundreds of milliseconds) closed periods. The closed periods between clusters and between groups within clusters are thought to reflect two desensitized states (Sakmann, Patlak & Neher, 1980). 3. Openings within groups consist largely of long-duration openings. An excess of brief-duration openings is seen at all high agonist concentrations; most brief openings occur as isolated, solitary openings. 4. The distribution of closed periods within groups shows four exponential components with time constants separated by several fold over the range of 50 microseconds to 50 ms. 5. The distribution of closed periods within groups is analysed as a function of agonist concentration, to estimate rate constants for transitions in a hypothetical reaction scheme for receptor activation. One or two of these components (depending on agonist and agonist concentration) appear to reflect agonist binding and channel gating. It is hypothesized that the other closed-period components within groups at high agonist concentrations result from additional states of doubly liganded receptors which have closed ion channels. 6. With ACh as agonist the data indicate that binding and activation saturate at concentrations above 130 microM. The data are quantitatively consistent with measurements made at low concentrations of ACh (Sine & Steinbach, 1986b), and indicate that a four-state linear scheme is able to describe major features of ACh-receptor activation on BC3H-1 cells. The channel opening rate is estimated to be about 450 s-1 and the closing rate about 35 s-1 (-70 mV, 11 degrees C). The concentration dependence of closed durations suggests that some positive co-operativity exists in agonist binding. The dissociation constant with one ACh molecule bound is about 50 microM, and that with two bound is about 10 microM (for an ACh receptor with a closed channel). 7. Saturation is not observed with carbamylcholine, even at 1 mM. The data are consistent with data obtained at low concentrations of carbamylcholine, and are in over-all agreement with the interpretation of data obtained with ACh. The affinity for carbamylcholine is estimated to be about 20-fold lower than with ACh.(ABSTRACT TRUNCATED AT 400 WORDS)

Chronic nicotine and locomotor activity: influences of exposure dose and test dose

Repeated exposure to nicotine increases both the number of central nicotinic receptors and the behavioral stimulant effect of nicotine. In the present experiments, the behavioral response to nicotine was examined in photocell activity cages. Groups of rats were tested using doses from 0.1 to 1.6 mg/kg both before and after all rats were exposed for 5 days to a common dose of 0.2 mg/kg/day. Prior to the 5-day exposure, there was a dose-related stimulant response to nicotine, with a maximum response seen at 0.4 mg/kg. After the 5-day exposure, the dose-effect curve was shifted upward, so that greater stimulation was produced at each test dose of nicotine. Other groups of rats were exposed for 5 days to doses of nicotine ranging from 0.01 to 0.30 mg/kg/day. On the 6th day all rats received a common test dose of 0.2 mg/kg and their response was measured in the activity cages. In animals exposed to 0.01 mg/kg/day, the test day response was not different from saline controls, but the groups exposed to higher doses showed increased stimulation in response to the common test dose. Measurements of nicotinic receptor binding using [3H]-acetylcholine found increased binding in groups receiving 0.03 mg/kg/day or more, but not in the group that received 0.01 mg/kg/day. The correspondence between the doses that increase behavioral stimulant reactions to nicotine and the doses that increase nicotinic binding suggest that increased receptor numbers may be responsible for the increased behavioral stimulation. However, rats given high doses (1.6 mg/kg, twice per day) did not show increased behavioral stimulation to a test dose of 0.2 mg/kg.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of chlorpromazine and phencyclidine on mouse C2 acetylcholine receptor kinetics

Patch-clamp techniques were used to record acetylcholine- (ACh) activated single-channel currents in cell-attached membrane patches from myotubes of the mouse cell line, C2. The effects of the phenothiazine derivative chlorpromazine (CPZ) and of the hallucinogen phencyclidine (PCP) on ACh-activated single-channel properties were studied under conditions where both compounds are positively charged (pH 7.2). The single-channel conductance was unaffected by either CPZ or PCP at concentrations ranging from 10 to 500 nM. 10-200 nM-CPZ and PCP led to shortened mean burst times. CPZ and PCP effects on mean burst times were voltage independent and did not vary in a simple linear manner with concentration. 10-200 nM-CPZ and PCP did not reduce channel opening frequencies, suggesting that the fraction of non-conducting state (occupied, blocked or desensitized) favoured at equilibrium was not significant at these concentrations. On the other hand, concentrations of CPZ and PCP higher than 300 nM did lead to depressed channel opening frequencies. In addition, we observed that, at these concentrations, the shortened burst duration reverses to the longer values found at lower effector concentrations. The effects of CPZ and PCP on ACh-activated single-channel kinetics are interpreted in terms of current models of ACh-receptor structure and conformational transitions.

Forskolin increases the rate of acetylcholine receptor desensitization at rat soleus endplates

We have studied the function of acetylcholine (AcCho) receptors (AcChoRs) in rat soleus endplates before and after exposing the muscles to forskolin, a potent activator of adenylate cyclase. AcChoR function was tested by recording the membrane depolarization evoked by pulses of ionophoretically applied AcCho. Brief (2 msec) AcCho pulses delivered at 7 Hz evoked constant responses at untreated endplates. In contrast, after 10-100 microM forskolin was added to the bath, responses to similar pulse trains fell by as much as 80% within 1 sec. AcCho sensitivity recovered completely in less than 1 min after the pulses were stopped but fell again when the pulses were resumed. Similarly, longer (1 sec) ionophoretic AcCho pulses evoked roughly constant responses at control endplates, but after forskolin treatment the depolarization fell by one-half within less than 200 msec. These results indicate that forskolin increases the rate at which AcChoRs desensitize when exposed to agonist. Focal extracellular recordings showed that 20-100 microM forskolin also increased the decay rate of miniature endplate currents, indicating that forskolin may decrease AcChoR channel open time. Inhibitors of cAMP phosphodiesterase increased the potency of forskolin. When used alone, these inhibitors had effects similar to those of forskolin but smaller. Patch-clamp experiments indicated that forskolin at 100 microM may also interact with AcChoR channels directly, but at 20 microM this effect is negligible. Therefore, it is likely that the forskolin effects were mediated primarily by increased levels of intracellular cAMP.

Changes in miniature end-plate potentials due to moderate hypertonicity at the frog neuromuscular junction

The effect of an increase in tonicity on the amplitude and frequency of miniature end-plate potentials (m.e.p.p.s) following superfusion of 50 mM- or 100 mM-sucrose-Ringer solution was determined from intracellular recording at end-plates of the frog cutaneous pectoris muscle, in the absence of drugs and using on-line statistical analysis. An immediate decrease in mean amplitude of the order of 20% control was associated with a marked increase in mean frequency. A delayed increase in mean amplitude, independent of frequency, followed the initial response in the majority of end-plates exposed to 100 mM-sucrose-Ringer solution. The net gain was of the order of 34% and was attained over 20-40 min. This was not reversible over at least 20 min. There was an increase in the variability of m.e.p.p. amplitudes associated with the increase of mean amplitude but this was reversible. A moderate increase in tonicity is considered to induce two kinds of presynaptic changes. First, an immediate increase in the probability of release of smaller quantal packets and secondly, an increased loading of transmitter into vesicles within the readily releasable store.

Functional domains of the nicotinic acetylcholine receptor

The nicotinic acetylcholine receptor is a multisubunit, membrane-spanning protein that contains a gated, cation-conducting channel. Our approach to the understanding of the function of this receptor in molecular terms has been to locate its functionally significant sites in the sequences of its subunits and in its three-dimensional structure. In addition, we have tried to correlate transitions in the properties of these sites with functional transitions of the receptor. On binding acetylcholine, the nicotinic acetylcholine receptor enters at least two transient states, the open state and the rapid-onset desensitized state, and, in the continued presence of agonist, finally subsides into the slow-onset desensitized state. The transitions of the receptor between these various states are susceptible to regulation by acetylcholine and its congeners acting at one type of site and by a broad class of noncompetitive inhibitors (NCIs), including local anesthetics, acting at other sites. The chain composition of the receptor is alpha 2 beta gamma delta. The two acetylcholine binding sites are on the alpha chains, and two residues contributing to these sites, Cys-192 and Cys-193, have been identified. Furthermore, these adjacent Cys residues are cross-linked by a disulfide bond. In the quaternary structure of the receptor, the chains appear to be arranged in the order alpha gamma alpha beta delta around a central channel. Both the alpha and beta chains contribute to functionally significant NCI binding sites. The addition to receptor-rich membrane from Torpedo electric tissue of agonists (but not competitive antagonists) renders these NCI sites susceptible to photolabeling by the NCI quinacrine azide (QA). Furthermore, this susceptibility is transient, arising in milliseconds and subsiding in hundreds of milliseconds. These transiently susceptible sites are protected by other NCIs against photolabeling by QA. The time-course of the susceptibility and its dependence on agonist-concentration suggest that it might be the transient, rapid-onset desensitized state of the receptor that is most susceptible to photolabeling by QA.

The effect of repetitive neuromuscular activity on the sensitivity of acetylcholine receptors

If skeletal frog muscle is indirectly stimulated at 10 Hz first an increase and later a decrease of the amplitude of miniature end-plate currents (m.e.p.cs) is observed (Ruzzier and Scuka 1979). The underlying mechanism can be a presynaptic change of the quantal size or a postsynaptic change. To distinguish between these possibilities, the neurally evoked end-plate current (e.p.c.n), the ionophoretically evoked end-plate current (e.p.c.i) and the extracellularly recorded miniature end-plate potential (m.e.p.p.e) were studied. It was found that the time constant of decay of m.e.p.p.e did not change during the experiment. The amplitude of the e.p.c.i changed in the same way as the amplitude of the m.e.p.c., it first increased and then decreased. Similar changes of the amplitude of e.p.c.i were observed in the experiments with increased frequency of the nerve stimulation and in those with different increases of the quantal content. It is concluded that during prolonged repetitive stimulation the sensitivity of the end-plate receptors to the released transmitter is modified, probably as a consequence of the cooperative binding of acetylcholine to the receptors.

Some properties of acetylcholine receptors in human cultured myotubes

The distribution and single channel properties of acetylcholine (ACh) receptors in human myotubes grown in tissue culture have been examined. Radioautography of myotubes labelled with [125I]alpha-bungarotoxin showed that ACh receptors are distributed uniformly over the myotube surface at a density of 3.9 +/- 0.5 receptors per square micrometre. Accumulations of ACh receptors (hot spots) were found rarely. The conductance and kinetics of ACh-activated channels were investigated with the patch-clamp technique. Cell-attached membrane patches were used in all experiments. A single channel conductance in the range 40-45 pS was calculated. No sublevels of conductance (substates) of the activated channel were observed. The distribution of channel open-times varied with ACh concentration. With 100 nM ACh, the distribution was best fitted by the sum of two exponentials, whereas with 1 microM ACh a single exponential could be fitted. The mean channel open-time at the myotube resting potential (ca. -70 mV, 22 degrees C) was 8.2 ms. The distribution of channel closed-times was complex at all concentrations of ACh studied (100 nM to 10 microM). With desensitizing doses of ACh (10 microM), channel openings occurred in obvious bursts; each burst usually appeared as part of a 'cluster' of bursts. Both burst duration and mean interval between bursts increased with membrane hyperpolarization. Individual channel open-times and burst durations showed similar voltage dependence (e-fold increase per 80 mV hyperpolarization), whereas both the channel closed-times within a burst and the number of openings per burst were independent of membrane potential.

Effects of neuronal activity on inositol phospholipid metabolism in the rat autonomic nervous system

The effect of nerve stimulation on inositol phospholipid hydrolysis in autonomic tissue was assessed by direct measurement of [3H]inositol phosphate production in ganglia that had been preincubated with [3H]inositol. Within minutes, stimulation of the preganglionic nerve increased the [3H]inositol phosphate content of the superior cervical sympathetic ganglion indicating increased hydrolysis of inositol phospholipids. This effect was blocked in a low Ca2+, high Mg2+ medium. It was also greatly reduced when nicotinic and muscarinic antagonists were present together in normal medium. However, neither the nicotinic antagonist nor the muscarinic antagonist alone appeared to be as effective as both in combination. In other experiments, stimulation of the vagus nerve caused dramatic increases in [3H]inositol phosphate in the nodose ganglion but did not increase [3H]inositol phosphate in the nerve itself. This effect was insensitive to the cholinergic antagonists. Thus, neuronal activity increased inositol phospholipid hydrolysis in a sympathetic ganglion rich in synapses, as well as in a sensory ganglion that contains few synapses. In the sympathetic ganglion, synaptic stimulation activated inositol phospholipid hydrolysis and this was primarily due to cholinergic transmission; both nicotinic and muscarinic pathways appeared to be involved.

Changes in miniature end-plate potentials after brief nervous stimulation at the frog neuromuscular junction

The amplitude of miniature end-plate potentials (m.e.p.p.s), recorded at the frog neuromuscular junction in a normal ionic environment and in absence of drugs, was examined following 10-450 nerve impulses using conventional electrophysiological techniques and on-line computational analysis. In both contracting preparations and non-contracting preparations pre-treated with glycerol, 100 or more nerve impulses resulted in a maximal fall in mean amplitude of about 20% with recovery apparent over the next 10-20 min. In an altered ionic environment with a lowered Ca and raised Mg concentration, 450 nerve impulses did not produce a decrease in mean amplitude but a similar reduction was seen following a larger number of impulses. The reduction in amplitude was estimated to follow the release of the order of 5000-10000 quanta at end-plates in a normal ionic environment and on average 17000 quanta in the presence of a lowered Ca and raised Mg concentration. Changes in the mean size of the spontaneous quantal response is considered to be a presynaptic event and to reflect the loss and slow recovery of larger packets of transmitter from a vesicular store that is readily released by nerve impulses.

Acetylcholine receptor: an allosteric protein

The nicotine receptor for the neurotransmitter acetylcholine is an allosteric protein composed of four different subunits assembled in a transmembrane pentamer alpha 2 beta gamma delta. The protein carries two acetylcholine sites at the level of the alpha subunits and contains the ion channel. The complete sequence of the four subunits is known. The membrane-bound protein undergoes conformational transitions that regulate the opening of the ion channel and are affected by various categories of pharmacologically active ligands.

End-plate currents evoked by paired stimuli in frog muscle fibres

Using voltage-clamp techniques spontaneously occurring miniature end-plate currents (mepc) and nerve-evoked end-plate currents (epc) were recorded in frog glycerol-treated or cut muscle preparations. Epcs were induced by pairs of stimuli (the delay of the 2nd stimulus, delta t being 6 ms-30 s; one pair was delivered every 60-90 s). The decay time constant of the epc (tau epc) was longer, the larger its quantal content despite the presence of active acetylcholinesterase (AChE). After treatment with anticholinesterases (prostigmine or armin, an irreversible inhibitor) this increase in tau epc became more pronounced. When AChE was fully active the decay of the 1st epc (tau 1) was slightly faster than the decay of the 2nd epc (tau 2) only when the interstimulus interval was rather short (delta t less than 20 ms). Following treatment with anticholinesterases this difference between tau 2 and tau 1 could be determined even when delta t was as long as 30 s. In anticholinesterase-treated preparations delta tau was found to be inversely proportional to log delta t: a 50% increase in the decay time-constant of the 2nd epc occurred with delta t = 120 ms. During continuous stimulation (10 impulses/s) tau epc increased from the 1st to the 5-6th responses, but then decreased in parallel with the fall in the epc amplitude. The phenomenon of postsynaptic potentiation we observed could be readily abolished when quantal content was decreased by the presence of magnesium ions, but it was relatively unaffected when the receptor density was decreased by alpha-bungarotoxin (alpha-BuTX).(ABSTRACT TRUNCATED AT 250 WORDS)

Comparison of cholinergic activation and desensitization at snake twitch and slow muscle fibre end-plates

Characteristics of receptor-channel activation and desensitization have been compared at voltage-clamped snake slow and twitch fibre end-plates maintained in an isotonic potassium propionate solution. Miniature end-plate current (m.e.p.c.) decay was slower and less voltage dependent at slow fibre end-plates than at twitch fibre end-plates. The peak m.e.p.c. amplitude versus voltage relationship and reversal potential were similar at the two end-plate types. Acetylcholine-induced noise and m.e.p.c.s were recorded at slow fibre end-plates. At most slow fibres the spectral density was not adequately fitted by a single Lorentzian function. Rather, the observed spectral density was greater at high frequencies than the values predicted using the m.e.p.c. decay rate. The noise could be well described by the sum of two Lorentzian functions, one of which corresponded to a single Lorentzian function with the corner frequency determined by the m.e.p.c. decay rate. The shape of the carbachol concentration-peak end-plate current relationship was similar at both slow and twitch fibre end-plates. However, for all concentrations tested, the peak carbachol-induced end-plate current (e.p.c.carb.) value was markedly less at slow fibre end-plates than at twitch fibre end-plates. The onset of desensitization was determined using two methods. The first concerned analysis of the time course of decay of the e.p.c.carb. from a peak value during the sustained application of agonist. The second involved a double-perfusion technique in which a 'desensitizing' dose was applied for varying intervals before the application of a second 'test' dose of carbachol. With both methods the development of desensitization at both end-plate types was dependent on carbachol concentration and duration of exposure. At each end-plate type the time course of desensitization onset often exhibited two components; one with a time constant of seconds and a slower component having time constants in the range of tens to hundreds of seconds. The slope of the relationship between carbachol concentration and equilibrium desensitization at slow and twitch fibre end-plates was close to two, suggesting that two molecules of agonist are probably bound during the development of desensitization. However, for all concentrations tested, desensitization developed more rapidly and to a greater extent at twitch fibre end-plates than at slow fibre end-plates. The voltage dependence of the 3 min steady-state desensitization produced by 108 microM-carbachol was very similar (approximately -0.0250 mV-1) at both fibre types.(ABSTRACT TRUNCATED AT 400 WORDS)

Substance P modulation of acetylcholine-induced currents in embryonic chicken sympathetic and ciliary ganglion neurons

Substance P has been identified by combined immunohistochemical and radioimmunological techniques to be present in preganglionic cholinergic and sensory nerve fibers of amphibian, mammalian, and avian autonomic ganglia. The peptide has been shown to depolarize sympathetic neurons of frog and guinea pig and to decrease the cholinergic activation of Na+ influx and catecholamine release from chromaffin cells. The aim of this study was to examine the interaction of acetylcholine and substance P on autonomic neurons. This report demonstrates a direct effect of substance P on acetylcholine-induced inward currents in both sympathetic and parasympathetic neurons clamped near resting membrane potential. Under these conditions, substance P dramatically enhances the rate of decay of the inward current in the continued presence of agonist without substantially affecting peak inward current. This effect is consistent with an enhancement of acetylcholine-receptor desensitization. Since substance P-containing cell bodies have been demonstrated in the avian (preganglionic) column of Terni as well as in fibers from the nucleus of Edinger-Westphal, the observed peptide inhibition of cholinergic activation of the neurons may function physiologically to modulate synaptic function in autonomic ganglia.

Substance P reduces acetylcholine-induced currents in isolated bovine chromaffin cells

Patch-clamp techniques were used to examine the effect of substance P on acetylcholine-induced current in bovine chromaffin cells. Cells had been enzymatically isolated and kept in short-term culture. Experiments were performed at 22 degrees C. Under whole-cell voltage-clamp conditions substance P alone (2-10 microM) did not induce ionic currents. Acetylcholine (ACh, 20 microM) at -60 mV induced an inward current that desensitized in the continued presence of ACh. The time course of desensitization was somewhat variable from cell to cell. In most cases it could be fitted by a single exponential with time constant of 8-10 s. Substance P (2-50 microM) applied simultaneously with ACh induced what appeared to be an acceleration of the desensitization process. The time course in the presence of 10 microM-substance P (20 microM-ACh) was best fitted by the sum of two exponentials with time constants of 0.6 s and 5 s respectively. The effect was reversible. The recovery of ACh-induced current from desensitization was not affected by substance P. The time constant for recovery was approximately 7 s in the presence or absence of substance P. Single-channel records showed that the conductance of individual channels was not changed by substance P. The mean open time of single channels was shortened by substance P both at high (20 microM) and at low (0.5 microM) concentrations of ACh. The inverse mean open time varied linearly with substance P concentration. Single-channel responses appeared in bursts and clusters after almost complete desensitization at 20 microM-ACh, as was previously observed in frog skeletal muscle. Substance P dramatically reduced ACh current by increasing interburst intervals while decreasing burst duration and the number of openings per burst. We conclude that substance P inhibits ACh-induced depolarization of chromaffin cells either by increasing the rate of desensitization or by inducing channel blockade, which indirectly enhances desensitization. Possible models of desensitization in the absence and presence of substance P are discussed.

Two-component desensitization of three types of responses of acetylcholine in Aplysia

Both the onset of and recovery from desensitization of three types of responses to acetylcholine in Aplysia californica occurred by biphasic kinetics. The fast component of onset recovered at a slower rate than the slow component of onset. The rates of onset and recovery were widely different when the three response types were compared. These data suggest that receptor properties determine two components in the desensitization process that are similar for all three responses, while the channel determines the rates of these processes.

Effects of concanavalin A on glutamate operated postsynaptic channels in crayfish muscle

Small crayfish muscle fibres were voltage clamped, and synaptic current noise induced by bath application of glutamate was measured. Desensitization of the glutamate receptors was blocked by preincubating the fibres with 0.3-1.0 mumol/l concanavalin A (Con A) for at least 30 min. The power density spectra of the glutamate current noise could be fitted by single component Lorentz curves. The lectin Con A did not influence significantly the conductance gamma of the glutamate channels but increased their mean open time, tau noise. The respective mean values found at T = 8 degrees C and E = -60 mV were gamma = 23.5 +/- 7.0 pS and tau noise = 1.5 +/- 0.2 ms. Both the conductance gamma and the closing rate alpha = tau -1 noise increased with temperature (Q10 approximately 1.9). This temperature dependence was characterized by the activation energies E gamma = 35.2 +/- 7.1 kJ/mol and E alpha = 46.9 +/- 2.1 kJ/mol. The potential dependence of tau noise was almost completely abolished by Con A.

Recent advances in the molecular mechanisms of human and animal models of myasthenia gravis

The receptor-channel molecule is a dynamic system which exists in multiple conformations and that is the way we should think of it when we study antibody interaction with the molecule. The results presented here suggest that some antibodies may affect receptor function by occupying sites other than the receptor site. Some of these sites may by exposed only in certain conformations, and occupation of some site by antibodies may effect conformational changes. These small but perhaps important differences in cholinergic channel properties of the myasthenic muscle from the normal one are revealed by studying the effect of myasthenic sera on drug interactions with the channel sites. The sera of myasthenics are able to react with certain channel conformations and are able to affect the interaction of channel antagonists such as H12HTX and QNB. The sera appear to act preferentially with the open conformation of the channel. As a consequence of such an effect, important conformational changes of the channel may fail to occur upon activation.