Desensitization onset and recovery at the potassium-depolarized frog neuromuscular junction are voltage sensitive

Kinetic evidence that desensitized nAChR may promote transitions of active nAChR to desensitized states during sustained exposure to agonists in skeletal muscle

During prolonged exposure of postjunctional nicotinic acetylcholine receptors (nAChR) of skeletal muscle to acetylcholine (ACh), agonist-activated nAChR (nAChRa) gradually fall into a refractory "desensitized" state (nAChRd), which no longer supports the high-conductance channel openings characteristic of the initially active nAChRa. In the present study, the possibility was examined that nAChRd, rather than simply constituting a passive "trap" for nAChRa, may actively promote further conversions of nAChRa to nAChRd in a formally autocatalytic manner. Single-ion whole-cell voltage-clamp currents (Na+ and Li+ in separate trials) were measured using two KCl-filled capillary electrodes (5-10 MOmega) implanted at the postjunctional locus of single frog skeletal muscle fibers (Rana pipiens) equilibrated in 30 mM K+ bath media to eliminate mechanical responses. Various nAChR agonists (carbamylcholine, acetylcholine, suberyldicholine) at different concentrations were delivered focally by positive pressure microjet. It was found that the decline of postmaximal agonist-induced currents under these different conditions (driven by the growth of the subpool of nAChRd) consistently followed an autocatalytic logistic rule modified for population growth of fixed units in a planar array: [Formula: see text] (where y represents the remaining agonist-induced current at time t, A=initial maximum current, and n is a constant). Some further experimental features that might result from a self-promoting growth of nAChRd were also tested, namely, (1) the effect of increased nAChRa and (2) the effect of increased nAChRd. Increase in agonist concentration of the superfusate, by increasing the planar density of active nAChRa at the outset, should enhance the probability of autocatalytic interactions with emerging nAChRd, hence, the rate of decline of agonist-induced current, and this was a consistent finding under all conditions tested. Raising the initial level of desensitized nAChRd by pretreatment of fibers with very low concentrations of agonist would be another way to increase autocatalytic interactions with active nAChRa, and this was also found to produce increased rates of decline of agonist-induced currents when tested in additional trials. It is concluded that several kinetic features of nAChR desensitization in skeletal muscle are consistent with an action of nAChRd to promote further transitions of nAChRa to desensitized forms. This could occur by a direct effect of nAChRd on contiguous nAChRa or perhaps through some intermediary membrane component or local intracellular pathway.

Effects of lanthanum at snake twitch and tonic muscle fibre endplates

1. The effects of 1 mM lanthanum on miniature endplate current (MEPC) frequency, amplitude, and decay time course were studied in voltage-clamped twitch and tonic muscle fibres in the garter snake, Thamnophis. 2. Lanthanum produced a marked increase in MEPC frequency in both fibre types. The maximum frequency in lanthanum was greater at twitch endplates than at tonic endplates although the increase in frequency relative to control levels was as great in tonic fibres as in twitch fibres. 3. In twitch fibres continually exposure to lanthanum, the frequency of MEPCs reached a peak value and then declined progressively until, after approximately 6 h, no MEPCs were recorded. In contrast, at tonic endplates exposed to 1 mM lanthanum, MEPC frequency remained elevated above control levels for periods greater than 20 h. 4. Lanthanum decreased the mean amplitude of MEPCs, skewed the amplitude distribution and increased MEPC duration at both twitch and tonic fibre endplates. 5. Ultrastructural analysis showed that after a 15 min exposure to 1 mM lanthanum, approximately half of the boutons innervating a twitch fibre contained fewer synaptic vesicles than boutons at control endplates, whereas nerve terminals innervating tonic fibre endplates were similar in appearance to those in control preparations. At endplates on both fibres, the postsynaptic membrane was more electron dense than that of control preparations. 6. Following a 6 h exposure to lanthanum, all nerve terminals innervating twitch endplates contained only a few synaptic vesicles and numerous intracellular deposits of electron dense material. The nerve terminals innervating tonic endplates still contained many synaptic vesicles, but the number appeared to be less than that of tonic terminals in untreated preparations. 7. The results demonstrate that lanthanum stimulates spontaneous quantal transmitter release from nerve terminals innervating either twitch or tonic fibres. However, the terminals innervating twitch fibres become depleted of synaptic vesicles, whereas this does not occur as readily in nerve terminals innervating tonic fibres.

Staurosporine inhibits the extent of acetylcholine receptor recovery from carbachol-induced desensitization in snake twitch fibres

1. The effect of the protein kinase inhibitor, staurosporine, on the extent and time course of recovery following carbachol-induced desensitization was studied in snake twitch-muscle fibres maintained in an isotonic potassium propionate solution and voltage-clamped to +30 mV. 2. Pretreatment with staurosporine (0.5 microM) decreased the extent of recovery of spontaneous miniature endplate current (m.e.p.c.) amplitudes following desensitization by a sustained application of 540 microM carbachol. Recovery was inhibited by approximately 50% without altering the time course of m.e.p.c. recovery. 3. Staurosporine also produced a concentration-dependent (10 nM to 0.5 microM) decrease in the amplitude of a second carbachol-induced current, following a wash period, as compared to the amplitude of the current produced by the initial carbachol application. Pretreatment with 0.5 microM K252a, another wide spectrum protein kinase inhibitor, also decreased the extent of recovery of the response to a second carbachol application following desensitization. 4. Staurosporine pretreatment (0.5 microM) had no effect on either the kinetics of receptor-channel gating or the initial endplate sensitivity to agonist. This was determined by comparing the amplitude of the carbachol (540 microM)-induced currents and the amplitude and decay rate of m.e.p.cs in control and staurosporine-treated fibres. 5. Staurosporine had no effect on the time course of desensitization onset produced during the initial application of 540 microM carbachol or the depth of desensitization produced by the end of a 2-3 min exposure to 540 microM carbachol.6. Elevation of the external calcium concentration from 1 to 10mM during the 540 microM carbachol application completely antagonized the decreased extent of recovery of m.e.p.c. amplitude produced by pretreatment with 0.5 microM staurosporine.7. We suggest that phosphorylation of a population of acetylcholine receptors is required for complete recovery from desensitization, and that staurosporine inhibits the protein kinases responsible for this phosphorylation.8. We further propose that a transient increase in intracellular calcium, produced by an increase in calcium influx through agonist-activated endplate channels, stimulates additional protein kinase activity, which in turn, antagonizes the effect of staurosporine-treatment on recovery.

Acetylcholine-activated ionic currents in isolated paratracheal ganglion cells of the rat

The electrophysiological property of acetylcholine (ACh)-induced current (IACh) was studied in paratracheal ganglion cells freshly isolated from rat trachea under whole-cell voltage-clamp condition. IACh consisted of an initial transient peak component and a successive steady-state plateau one. The peak component increased in a sigmoidal fashion with increasing ACh concentration. The IACh was mimicked by nicotine. The current-voltage relationship for the IACh showed inward rectification at the positive membrane potentials beyond the reversal potential (EACh). In a K(+)-free solution, the EACh was close to the Na+ equilibrium potential. The IACh was blocked by either D-tubocurarine or atropine. The ion selectivity of ACh-activated channels to various monovalent cations was weak, and similar to those of other preparations. It was concluded that the IACh in rat paratracheal ganglion cells was mediated by nicotinic receptor activation.

Direct measurement of the concentration- and time-dependent open probability of the nicotinic acetylcholine receptor channel

Using the outside-out patch clamp recording technique together with a rapid solution exchange system, we measured ionic currents through nicotinic acetylcholine (ACh) receptor channels from BC3H-1 cells in response to rapid applications of 0.3-1,000 microM ACh. We used nonstationary fluctuation analysis of ensembles of responses to deduce the number of channels in the patch, the maximum open channel probability as a function of ACh concentration and the time course of a fast desensitization process. We found that: (a) Excised patches from BC3H-1 cells typically contain between 50 and 150 functional ACh receptor ion channels. (b) The open channel probability is proportional to [ACh]1.95 at low concentrations of ACh, is half-maximal at 20 microM ACh and saturates above 100 microM ACh. (c) ACh is a very efficacious agonist; 100 microM ACh opens at least 90% of the available channels. This estimate of efficacy is model-independent. (d) The rate of decay of the agonist-induced current is concentration-dependent. In the presence of 100 microM ACh the current decays with a time constant of 50-100 ms. It decays more slowly in the presence of lower concentrations of agonist but is relatively insensitive to voltage.

Desensitization kinetics of a chloride acetylcholine response in Aplysia

The kinetics of desensitization of acetylcholine-evoked Cl conductance increased response of Aplysia RC neurons of the abdominal ganglion were studied under voltage-clamp conditions for comparison with results of similar studies on acetylcholine Na and K responses. The response evoked by acetylcholine on RC neurons was an outward current at resting potential (about -45 mV) that reversed at about -65 mV and was blocked by D-tubocurarine and strychnine but not hexamethonium and was not activated by arecoline. From the current-voltage relation this response can be ascribed to a pure conductance increase to Cl. The apparent KD was 40.6 microM. Upon prolonged exposure to acetylcholine the response peaked within 200-400 ms, and then decayed to a plateau current in the continued presence of the agonist. The peak and plateau currents reversed at the same potential, indicating that there had not been significant redistribution of Cl. The current decay in every cell was best fit by a double exponential function plus a constant, and the average time constants were tau fast = 1.8 +/- 0.2 s and tau slow = 16.2 +/- 1.0 s. Both components were slowed by cooling. While tau fast did not change with dose, tau slow increased with dose. Both components accelerated with hyperpolarization and upon application of trifluoperazine (2 microM). These results are consistent with the interpretation that desensitization of the acetylcholine Cl response is composed of two independent processes. This conclusion is the same as that derived from studies of the acetylcholine Na and K responses, and is in general consistent with desensitization being a property of a common acetylcholine receptor, and independent of the ionic selectivity of the associated channel. There are, however, significant differences in voltage, temperature and trifluoperazine dependence of the two components of the three ionic responses which may reflect influence of the different ion channels and/or transduction mechanisms.

Desensitization of the acetylcholine receptor of frog end-plates measured in a Vaseline-gap voltage clamp

1. Desensitization of the nicotinic acetylcholine receptor of the frog end-plate was investigated in dissociated frog muscle fibres using the Vaseline-gap clamp method so that a wide range of well-defined agonist concentrations could be used without having to use alpha-bungarotoxin to reduce currents, and so that the intracellular medium could be controlled. 2. Acetylcholine (ACh) concentrations between 1 and 1000 microM were used, after inactivation of acetylcholinesterase. The intracellular calcium concentration was usually kept near zero by using 80 mM-K2EGTA as the intracellular solution. 3. When using the low intracellular calcium solution, desensitization proceeded as a biphasic process with estimates of fast and slow time constants of about 8 and 80 s at 4 degrees C and 20 microM-ACh (the rates increased with concentration). In contrast, only one (fast) component of desensitization was detected when the intracellular calcium concentration was allowed to increase during ACh application. 4. Despite rapid application of ACh the time to peak response was 0.2 s (with 400 microM-ACh) to 2 s (with 1 microM-ACh); this slow rise was shown to result from diffusion delays. Nevertheless the peak current with 200 microM-ACh corresponded to opening of most of the channels present, so there is probably not much desensitization in the millisecond time range. 5. Both fast and slow time constants for onset of desensitization showed only slight dependence on membrane potential when [Ca2+]i was buffered with 80 mM-K2EGTA. 6. Increasing the intracellular cyclic AMP concentration directly, or indirectly with forskolin and IBMX, had no effect on the time course of desensitization. 7. Intracellular application of submicromolar concentrations of phorbol-12,13-dibutyrate (PDBu) and phorbol-12-myristate-13-acetate (PMA) yielded a small but reproducible reduction of the peak response to ACh. The time course of desensitization was, however, not modified by these substances. 8. The implications of these observations for the mechanism of desensitization, and their relationship to single-channel observations, are discussed.

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)

Two ATP-activated conductances in bullfrog atrial cells

Currents activated by extracellular ATP were studied in single voltage-clamped bullfrog atrial cells. Rapid application of ATP elicited currents carried through two different conductance pathways: a rapidly desensitizing conductance reversing near -10 mV, and a maintained, inwardly rectifying conductance reversing near -85 mV. ATP activated the desensitizing component of current with a K 1/2 of approximately 50 microM and the maintained component with a K 1/2 of approximately 10 microM. Both types of current were activated by ATP but not by adenosine, AMP, or ADP. The desensitizing current was selectively inhibited by alpha, beta-methylene ATP, and the maintained, inwardly rectifying current was selectively suppressed by extracellular Cs. The desensitizing component of current was greatly reduced when extracellular Na was replaced by N-methylglucamine, but was slightly augmented when Na was replaced by Cs. GTP, ITP, and UTP were all ineffective in activating the desensitizing current, and of a variety of ATP analogues, only ATP-gamma-S was effective. Addition of EGTA or BAPTA to the intracellular solution did not obviously affect the desensitizing current. Fluctuation analysis of currents through the desensitizing conductance suggested that current is carried through ionic channels with a small (less than pS) unitary conductance.

'Concentration-clamp' study of gamma-aminobutyric-acid-induced chloride current kinetics in frog sensory neurones

Kinetics of the activation and desensitization phases of gamma-aminobutyric acid (GABA)-induced Cl- current (ICl) were studied in single frog sensory neurones using the 'concentration-clamp' technique which enables perfusion of drugs with the time constant of about 3 ms. Both activation and desensitization phases of GABA response consisted of a single exponential at low concentrations and a double exponential at high concentrations. The time constant of the fast kinetic component in each phase was relatively stable, about 5 ms for activation and 3 s for desensitization over concentrations from 3 X 10(-5) to 3 X 10(-4) M, whereas those of the slow kinetic component decreased with increasing concentrations. The two kinetic components in both phases showed the same reversal potential. The slow and fast activation components recovered sensitivity from desensitization with different time courses: the recovery rate of the fast activation component was slow and that of the slow one, rapid. The peak ICl elicited at GABA concentrations below 10(-5) M increased disproportionally at more negative membrane potentials, thereby suggesting that the activation kinetics is voltage dependent. The steady-state ICl-voltage relationship obtained with less than 10(-5) M-GABA showed a non-linearity, probably due to voltage dependence of activation rather than that of desensitization kinetics. These results suggest the presence of at least two different GABA receptor-Cl- ionophore complexes with a different affinity and kinetics.

Delay of desensitization onset by potassium ion in voltage-clamped frog muscle fibers

Increase in extracellular K+ concentration causes delay in desensitization onset during prolonged application of carbamylcholine to the postjunctional membrane in muscle. This could be due to a direct action of K+ on acetylcholine receptors or to some change in the receptors related to K+-induced effects on transmembrane potential. The question of direct vs. voltage-dependent action of K+ was investigated in frog muscle (Rana pipiens) using a point-source voltage clamp. In conductance measurements first without voltage control, desensitization rate in bath media containing 33 mM K+ was -0.198 s-1 among fibers showing an average potential of -30 mV and -0.104 s-1 in 165 mM K+ where the average potential was -2 mV, a decrease of 47%. By comparison, in voltage-clamp tests at a nominal holding potential of +20 mV, increasing extracellular K+ from 33 to 165 mM caused a decrease of 61% in desensitization rate from -0.151 to -0.059 s-1. Another series in 165 mM K+ at a holding level of +10 mV showed a decrease of 67% to a rate of 0.047 s-1. It is concluded that increases in extracellular K+ can delay desensitization onset independently of effects on transmembrane potential. It is suggested that this could result from a direct interaction of K+ with sites on the outer receptor moiety or within channels, but probably not at the inner membrane face, if the latter are considered in equilibrium with bulk intracellular K+.

Trifluoperazine and calcium antagonists accelerate cholinergic desensitization in Aplysia neurons

The onset of desensitization of excitatory acetylcholine responses in isolated, voltage clamped Aplysia RB neurons to microperfused agonist was accelerated by trifluoperazine and the calcium antagonists SKF-525A and D-600. In the absence of these drugs the time course of desensitization is described as the sum of two exponentials plus a constant. All 3 compounds accelerated the fast exponential component of desensitization, but had opposite effects on the slow component: trifluoperazine and SKF-525A accelerated the slow component, whereas this phase was greatly slowed by D-600. These results provide further evidence that the two components of cholinergic desensitization may be independent and influenced by agents which may affect calcium binding to the acetylcholine receptor.

Two-component desensitization of nicotinic receptors induced by acetylcholine agonists in Lymnaea stagnalis neurones

The kinetics of desensitization induced by different agonists of acetylcholine (ACh) as well as the kinetics of recovery from densensitization, have been studied using the voltage-clamp technique in isolated, identified Lymnaea stagnalis neurones. Desensitization follows the sum of two exponentials: one fast and one slow. The time constant of the fast desensitization component (tau Ids) under ACh application is in the range of seconds at room temperature (18-23 degrees C). It increases upon cooling (Q10 = 2.8 +/- 0.9), decreases with increasing ACh concentration and is independent of membrane voltage. The time constant of the slow component of densensitization (tau Ids) is in the range of tens of seconds. It decreases with increasing drug concentration and is weakly dependent upon temperature (Q10 = 1.3 +/- 0.4). The relative amplitude of the fast component, estimated by back extrapolation to the position of the peak current, increases with agonist concentration and decreases upon cooling. Recovery from desensitization follows the sum of two exponentials with time constants (tau Ir and tau IIr) of the order of seconds and minutes, respectively. Cooling prolongs the slow component (Q10 of tau IIr is approx. 3) and reduces its contribution during recovery. A comparison of the desensitization induced by various agonists indicates that for the small monoquaternary agonists the onset and recovery of desensitization resemble the onset and recovery observed with ACh. For more bulky agonists, like ethoxysebacylcholine, sebacylcholine and suberylcholine, the decay of the response during prolonged application of the agonist may involve an additional blocking process.

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)

Activation of acetylcholine receptors causes the partition of hydrophobic cations into postsynaptic membrane vesicles

In the continued presence of cholinergic ligands, the acetylcholine receptor-channel complex (AChR) in postsynaptic membranes undergoes a sequence of conformational changes. On addition of the ligand, the receptor rapidly changes from a closed channel to an open channel conformation, then slowly changes to a nonconducting state termed desensitization. The lifetime of the open channel conformation and the rate of desensitization are both dependent on the magnitude of the membrane potential, suggesting that the ligand-induced conformational changes in AChR may involve the movement of electrical charges within the membrane. Measurements of charge redistribution in AChR-containing membranes following ligand binding have not been reported. Recently, measurements of changes in the membrane partition coefficient of hydrophobic ions have been used to detect electrostatic changes in both biological and model membranes. We report here that cholinergic ligands induce changes in the partition coefficient of the hydrophobic cation tetraphenylphosphonium (TPP) into AChR-enriched membranes. The extent and time course of these changes in TPP partition coefficient are accounted for in a kinetic model. We conclude that TPP movement is a monitor of a molecular event which may be associated with the slow component of AChR desensitization.

Magnesium increases rate of onset of desensitization in frog muscle

The effect of changes in extracellular and intracellular magnesium content on desensitization rate in frog (Rana pipiens) sartorius muscle was studied using measurements of input conductance of single fibers during local superperfusion of the postjunctional region with carbamylcholine chloride (0.27-2.7 mM). Two intracellular KCl-filled glass capillary microelectrodes were used for current injection and recording in fibers equilibrated in high-K+ media (33-165 mM). In low-ionic strength solutions (33 mM K), time to half-decline of conductance during desensitization to carbamylcholine (T1/2) was decreased by increasing extracellular Mg2+ concentration throughout range 0-100 mM. Equivalent effects on T1/2 were produced by increased extracellular Ca2+ in lower concentrations (0-10 mM). Increase in K+ concentration or decrease of carbamylcholine concentration resulted in increased T1/2 in both Mg2+ and Ca2+ media. Increase of intracellular Mg2+ by soaking in high-Mg2+ solutions (100 mM) or by intracellular iontophoresis caused decrease in T1/2. It is concluded that Mg2+, when introduced either in the extracellular or intracellular phase, can promote increased desensitization rate and that this action is similar to but weaker than that of calcium.

Influence of sodium and calcium ions and membrane potential on glutamate receptor desensitization

1. The effects of Na, Ca and membrane potential on desensitization of postjunctional glutamate receptors on locust muscle were investigated. 2. The kinetics of desensitization were measured ionophoretically. 3. Replacement of Na by equimolar concentrations of the permeant cations Li, NH4 and guanidine and the impermeant cation choline accelerated desensitization onset, increased the steady-state leve of desensitization and reduced the rate of recovery from desensitization. 4. Desensitization onset rates and steady-state levels of desensitization were not significantly altered either by changing the extracellular Ca concentration or by changing the membrane potential of voltage clamped muscle fibres.

Desensitization at the frog neuromuscular junction: a biphasic process

1. The desensitization of the cholinergic receptor has been investigated at the frog neuromuscular junction. The agonist was either perfused or applied by ionophoresis.2. In all situations, desensitization develops in two phases: a fast one, experimentally in the second range but likely to be briefer, and a slower one, which extends over tens of seconds.3. When the presence of the agonist is prolonged, desensitization approaches a steady state, estimated through the amplitude of a test response. In steady-state conditions, this amplitude depends upon the desensitizing agonist concentration. The dose-response curve for desensitization induced by carbachol (CCh) indicates that half of the receptors can be desensitized at room temperature in the presence of 2.3 mum-CCh. The shape of the curve suggests that one desensitized receptor can bind two CCh molecules.4. The recovery from desensitization, estimated with a repetitive test pulse, displays two exponential phases. The time constant of the fast phase is 11-12 sec, and 4-5 min for the slow phase, regardless of the concentration or the nature of the agonist (acetylcholine or carbachol).5. The factor which most strikingly affects the relative amplitudes of the fast and slow phases of recovery is the duration of the (desensitizing) agonist application. Desensitizations lasting a few seconds are followed by a ;fast' recovery, whereas the slow phase of recovery is prominent when the agonist has been applied for more than 2 min.6. The fast and slow phases of desensitization onset and offset are not due to independent causes but are coupled: in given conditions, the onset can be essentially fast, and the recovery slow.7. All our findings can fit in a cyclic scheme of desensitization, derived from the one of Katz & Thesleff (1957) with two modifications: whether activatable or desensitized, one receptor molecule would have two agonist binding sites; moreover, the desensitized receptor would exist in two distinct and interconverting conformations: D(1), giving rise to the fast phases of onset and offset, and D(2), responsible for the existence of the slow components of desensitization.

The influence of concanavalin A on glutamate-induced current fluctuations in locust muscle fibres

1. The influence of the plant lectin Concanavalin A (ConA) on the properties of membrane channels opened by 25-200 microM-L-glutamate in voltage-clamped locust muscle fibres has been studied. Power spectral density plots of membrane current fluctuations were used to estimate the mean lifetime and conductance of glutamate-induced channels. 2. Exposure to ConA (10 micrograms/ml.) increased the amplitude of the mean current evoked by 200 microM-glutamate from 7.7 +/- 4.7 nA (mean +/- S.D.) to 81 +/- 57 nA (membrane potential -60 mV, temperature 16 degrees C). The mean conductance of glutamate-induced channels (65 +/- 16.8 pS at 16 degrees C) was negligibly affected by the lectin. 3. In normal saline the mean lifetime of glutamate-induced channels tau noise decreased on membrane hyperpolarization. After treatment with ConA (70 micrograms/ml.), tau noise become totally independent of membrane voltage when studied at potentials in the range -60 to -120 mV. The value of tau noise at the resting potential was little altered by the lectin.

The effects of external Ca++ and Mg++ on the voltage sensitivity of desensitization in Electrophorus electroplaques

Desensitization onset was studied in voltage-clamped Electrophorus electroplaques during prolonged exposure to bath-applied carbamylcholine. The time-course of desensitization was described by a first-order rate constant kappa obs, which increased exponentially with membrane hyperpolarization from -20 to -90 mV. When Ca++ was increased from 2 to 10 mM, the voltage sensitivity of kappa obs decreased; kappa obs decreased for voltages more negative than -40 mV, and increased slightly at voltages more positive than -40 mV. 10 mM Mg++ had a less pronounced effect and the voltage sensitivity of kappa obs was unchanged. The equilibrium level of desensitization, estimated from the carbamylcholine-dependent conductance which remained after desensitization was apparently complete, also increased with hyperpolarization.

Voltage dependence of desensitization. Influence of calcium and activation kinetics

The voltage dependence of carbachol-induced desensitization has been analyzed in potassium-depolarized frog sartorius muscle preparations with voltage clamp techniques over a wide voltage range (-120 to +40 mV). Desensitization developed exponentially at all voltages with tau, the time constant of desensitization onset, varying as a logarithmic function of membrane voltage. The voltage dependence of tau remained in calcium-deficient solutions and was not altered by elevating either the level of extracellular or intracellular calcium. We have analyzed our results according to a simple sequential kinetic scheme in which the rate-limiting step in the development of desensitization is a transition of the receptor channel complex from the activated conducting state to a desensitized, nonconducting state. We conclude (a) that the observed voltage sensitivity of desensitization primarily resides in the voltage dependence of this transition, and (b) the kinetics of activation appear to have a greater influence on the observed rate of desensitization than on its voltage dependence. The magnitude of the voltage dependence suggests that a greater change in free energy is required for the transition to the desensitized state than for the transition between the open and closed states of the receptor channel complex.

Interaction between nerve-related acetylcholine and bath applied agonists at the frog end-plate

1. The interaction between acetylcholine (ACh) and carbachol (CCh) has been studied at the frog end-plate. The conditioning agonist, CCh, can cause desensitization (reduction of the ACh test response) and potentiation (increase of the test response). 2. Nerve-evoked end-plate currents (e.p.c.s), minature e.p.c.s and "slow" responses to ACh ionophoresis can all be potentiated by bath or ionophoretically applied CCh. 3. Since potentiation was found to be particularly visible at low temperatures, most experiments were performed at 5-8 degrees C. Potentiation results in an increase of both e.p.c. amplitude and e.p.c. decay time. Potentiated e.p.c.s teminate with a slow tail, the amplitude of which shows a high voltage sensitivity. Potentiation increases with CCh concentration (range studied 0-100 microM). It appears to persist throughout the application of CCh, even when desensitization is apparently the dominant phenomenon. 4. It is suggested that cross-potentiation of ACh by CCh results from the formation of intermediate non-conducting CCh-receptor complexes which have a high probability of being subsequently activated by ACh, yielding a conducting ACh-CCh-receptor complex. 5. Desensitization induced by fast bath application of CCh (or ACh) develops in two phases and can be fitted by the sum of two exponentials. Their time constants are in the second and the minute range, respectively. 6. The possibility that the slow phase is linked to the presence of agonist inside the cell is rejected.

Voltage clamp analysis of acetylcholine receptor desensitization in isolated mollusc neurones

1. Desensitization produced by acetylcholine (ACh) in completely isolated Limnaea stagnalis neurones with chloride-selective membrane channels was studied using a voltage-clamp technique. 2. A difference in the time course of the neurone responses to ACh, depending on whether the measured parameter was voltage or current, was observed and explained on the basis of an equivalent electric scheme of the neurone soma membrane. 3. Desensitization onset was shown not to depend on membrane potential in the range of -30 to -120 mV. 4. Variation of external Ca2+, Na+ and Cl- concentrations over a wide range had little influence on the onset of desensitization and recovery from it. 5. An obvious difference is shown to exist between features of desensitization in mollusc neurone and frog muscle end-plate ACh receptors.