Membrane-potential effects on an inhibitory post-synaptic conductance in Aplysia buccal ganglia

Inhibition of afferent transmission in the feeding circuitry of aplysia: persistence can be as important as size

We are studying afferent transmission from a mechanoafferent, B21, to a follower, B8. During motor programs, afferent transmission is regulated so that it does not always occur. Afferent transmission is eliminated when spike propagation in B21 fails, i.e., when spike initiation is inhibited in one output region-B21's lateral process. Spike initiation in the lateral process is inhibited by the B52 and B4/5 cells. Individual B52 and B4/5-induced inhibitory postsynaptic potentials (IPSPs) in B21 differ. For example, the peak amplitude of a B4/5-induced IPSP is four times the amplitude of a B52 IPSP. Nevertheless, when interneurons fire in bursts at physiological (i.e., low) frequencies, afferent transmission is most effectively reduced by B52. Although individual B52-induced IPSPs are small, they have a long time constant and summate at low firing frequencies. Once IPSPs summate, they effectively block afferent transmission. In contrast, individual B4/5-induced IPSPs have a relatively short time constant and do not summate at low frequencies. B52 and B4/5 therefore differ in that once synaptic input from B52 becomes effective, afferent transmission is continuously inhibited. In contrast, periods of B4/5-induced inhibition are interspersed with relatively long intervals in which inhibition does not occur. Consequently, the probability that afferent transmission will be inhibited is low. In conclusion, it is widely recognized that afferent transmission can be regulated by synaptic input. Our experiments are, however, unusual in that they relate specific characteristics of postsynaptic potentials to functional inhibition. In particular we demonstrate the potential importance of the IPSP time constant.

Evidence that sensitivity to steroid anesthetics appears late in evolution

The effects of pregnanolone, a steroid anesthetic, were compared with diethyl ether and short chain alkanols in 21 aquatic species from 7 phyla. Loss of righting reflex and escape response were used as indicators of anesthesia. All organisms were anesthetized by diethyl ether and short chain alkanols, but pregnanolone affected only organisms belonging to the phylum Chordata. It is probable that pregnanolone exerts its effect on the gamma-aminobutyric acid (GABA) receptor. Because many invertebrates do possess GABA receptors, our results suggest that a binding site at which steroid binding causes organismal anesthesia appeared early in chordate evolution on a previously existing GABA receptor. The results also appear to exclude a primary lipid bilayer site for steroid anesthetic action.

Some characteristics of the functioning of membrane receptor-channel complexes of Limnaea stagnalis neurones

1. Limnaea stagnalis neurones have been used to study the functioning of membrane receptor-channel complexes. The experiments were performed using a fixed membrane potential (E) and the intracellular perfusion technique. The cells employed responded to acetylcholine (ACh) by changing only their Cl- conductance. 2. ACh-induced currents, their fluctuations and relaxations resulting from a jump of E were studied. 3. The following facts have been established based on analysis of ACh currents, their fluctuations and relaxations: (1) the characteristic time of the exponential decay of the autocorrelation function, tau N, is in the range of 15-20 ms; (2) the characteristic relaxation time, tau R, equals 50-60 ms (ACh concentration = 0.25 microM, desensitization is not observed); (3) E does not exert any functionally significant effect upon tau N or tau R which could have governed the non-linearity of the membrane voltage-current characteristic; (4) variation of ACh concentration from 0.25 to 1 microM has a significant effect on tau R but not on tau N; (5) lowering of the ACh solution temperature from 22 to 8.5 degrees C results in a 20% increase of the ACh current, a 3- to 4-fold decrease of the single-channel conductance (gamma), a 20% increase in tau N and a 3- to 4-fold increase in tau R. 4. The suberylcholine (SCh)-induced membrane current has approximately the same value as the ACh-induced current at equal concentrations of ACh and SCh (0.25 microM); the tau N and gamma values were also quite close, but tau R was 2.3 times lower for SCh than for ACh. 5. An essentially two-stage scheme of functioning of membrane receptor-channel complexes is proposed. The scheme has two distinguishable and measurable stages and involves five closed states and one open state; it offers an explanation for our experimental data as well as the results of other workers.

Outward rectification of inhibitory postsynaptic currents in cultured rat hippocampal neurones

1. Inhibitory postsynaptic potentials (IPSPs) and currents (IPSCs) were recorded from cultured hippocampal neurones of the embryonic rat at 22 degrees C, using the whole-cell patch-clamp technique with a low-Cl-, 145 mM-potassium gluconate solution in the patch pipette. Individual synaptic events were elicited at low frequency (0.05-0.1 Hz) by stimulating a presynaptic neurone either by direct intracellular current injection, or by applying a brief pulse of L-glutamate. 2. In target neurones voltage clamped at -40 mV, outwardly directed IPSCs of mean amplitude 0.23 nA were recorded. The IPSCs were depressed by the GABA antagonist bicuculline, and reversed polarity between -50 and -80 mV (mean -64 mV), as did current responses to gamma-aminobutyric acid. The IPSPs and IPSCs reversed as a single phase; no bicuculline-resistant 'late' synaptic event was observed. 3. The IPSCs had variable kinetics, with rise times between 1 and 5 ms (mean 2.9 ms) at -40 mV, and slower, monoexponential, decay phases (decay time constant, tau IPSC, 10-40 ms at -40 mV). In some cells, tau IPSC clearly increased with depolarization. 4. The IPSC reversal potential was -64 +/- 9 mV (n = 23) under the experimental conditions used; this suggests that the synaptically activated channels are approximately 25 times more permeable to Cl- than to the gluconate anion. 5. The peak conductance associated with the IPSC showed outward rectification. The synaptic conductance measured at -40 mV was 1.7 times greater than that measured at -100 mV; at -20 mV, synaptic conductance was 2.5 times greater than at -100 mV. This outward rectification can be explained by a constant field model under these experimental conditions of asymmetric Cl- concentrations.

A test for modulation of synaptic efficacy by induced membrane potential variance

A modification of Klopf's heterostatic adaptive neuron hypothesis is proposed, in which membrane potential variance, rather than depolarization, has adaptive influence on individual nerve cells. Recordings from each of two configurations of three-cell networks of Aplysia buccal ganglia test for either nonspecific or associative effects of excess membrane potential and current variance, in the form of noise injection into voltage-clamped postsynaptic neurons. No effects of noise are reported, suggesting either that the hypothesis is incorrect, or else that the frequency spectrum or duration of recording were inappropriate to produce the adaptive modulation.

Kinetic analysis of acetylcholine-induced chloride current in isolated Aplysia neurones

(1) Kinetics of activation and desensitization phases of the ACh-induced chloride current (ICl) were studied in isolated single neurones of Aplysia kurodai, using the 'concentration clamp' technique which combines internal perfusion and rapid exchange of the external solution within a few milliseconds (2) The dose-response curve for the peak ICl gave a dissociation constant of 6.7 X 10(-6) M and a Hill coefficient of 1.7. (3) The current-voltage relationship was linear in the voltage range examined (-70 to +30 mV). The reversal potential (EACh) was -7.1 +/- 1.8 mV (n = 14). The value was close to the calculated equilibrium potential for chloride ions (ECl). (4) The activation phase of the ICl was single exponential and the desensitization proceeded double exponentially to a steady state level. The time constants of both phases decreased with increasing concentrations of ACh but showed no potential dependency. The desensitizing component of the ICl was generated by activation of a single population of the receptor-channel complex. (5) The recovery from desensitization of the ICl induced by 6 X 10(-6) M ACh proceeded double exponentially, with time constants of 6.5 and 43 s at a holding potential of -30 mV. (6) Noise analysis performed on the steady state of ICl induced by low concentrations of ACh (3 X 10(-7) M to 3 X 10(-6) M) showed that the steady ICl was due to activation of a single population of the receptor-channel complex with a single channel conductance of 23.3 +/- 4.3 pS (n = 9).(ABSTRACT TRUNCATED AT 250 WORDS)

Miniature and evoked inhibitory junctional currents and gamma-aminobutyric acid-activated current noise in locust muscle fibres

gamma-Aminobutyric acid (GABA) current noise and inhibitory junctional currents (i.j.c.s) have been examined to give properties of the GABA receptor and its associated synaptic channel. Various procedures were used to identify muscle bundles receiving inhibitory innervation. In normal bathing medium the decay time constant of the i.j.c. was tau i.j.c. = 7.6 +/- 0.7 ms (clamp potential, Vm = -80 mV; temperature, T = 21 degrees C). Most muscle fibres were sensitive to ionophoretically applied GABA, irrespective of the presence of inhibitory innervation. GABA current noise obtained at junctional sites gave spectra which were fitted usually with a single Lorentzian component, or occasionally with the sum of two Lorentzians. The conductance of the single inhibitory channel was, gamma (GABA) = 21.6 +/- 0.9 pS (Vm = -80 mV; T = 21 degrees C). The mean 'burst length' of the openings produced by a single receptor activation was tau noise = 4.0 +/- 0.8 ms, at Vm = -80 mV. This decreased exponentially with hyperpolarization. On average tau i.j.c. exceeded tau noise although good agreement was found in some fibres. I.j.c.s were examined in greater detail after excitatory synaptic receptors had been desensitized with 10(-3) M-L-glutamate to abolish all excitatory synaptic activity. Their decay time constant was tau i.j.c. = 7.2 +/- 0.4 ms, and their rise time was 3.3 +/- 0.12 ms, at Vm = -80 mV. An e-fold decrease in tau i.j.c. resulted from a 103 +/- 7.9 mV hyperpolarization; time to peak showed a smaller dependence on Vm. The mean size of the inhibitory quantal event (i.e. response to a single transmitter packet) was estimated from fluctuations in i.j.c. amplitude. Mean quantal content of the i.j.c. was about 30 at normal levels of release. Mean amplitude of the directly measured miniature i.j.c. = 0.65 +/- 0.08 nA at Vm = -80 mV (V eq approximately equal to -40 mV). The amplitude of the quantal event showed a non-linear dependence on Vm. The burst length of the inhibitory channel, produced by a single receptor activation, is longer in duration (at -80 mV) and exhibits greater voltage dependence than the burst length of the excitatory glutamate-activated channel in these fibres. It is estimated that a single quantum of GABA opens about 600-1000 post-synaptic chloride channels.

Postsynaptic currents at the Mauthner fiber giant synapse of the hatchetfish

Postsynaptic currents (PSCs) at the giant synapse between Mauthner and giant fibers of the hatchetfish Gasteropelecus were studied under voltage clamp. This axo-axonic synapse lies in the central nervous system beneath the floor of the 4th ventricle where electrodes can be closely positioned both pre- and postsynaptically. Transmission is nicotonic cholinergic. The PSCs produced by Mauthner fiber impulses rise rapidly to a peak and decay in two phases; an early more rapid phase is followed by a late slower phase. The slope conductance of the peak amplitude of the PSCs declines at more inside positive potentials. The late phase of decay is exponential and voltage dependent, becoming faster for PSCs evoked at more inside positive potentials. At potentials positive to about -40 mV the late phase merges with the early phase. The decay rate constant of the slowest phase is exponentially related to voltage for potentials negative to about -10 mV, but becomes less voltage dependent for more positive potentials. The peak current is independent of whether it is evoked during inward or outward active currents of the electrically excitable membrane, and two phase decays are observed in PSCs of reduced quantal content. Thus, changes in slope conductance and two phase decays are not due to series resistance or interactions between quanta. PSCs can be modeled by a 3 state reaction scheme in which closed channels open when they bind transmitter and then can pass to a second closed state with receptor still bound such that they must return through the open state before losing their transmitter and returning to the resting, closed state.

Acetylcholine responses of identified neurons in Helix pomatia--II. Pharmacological properties of acetylcholine responses

A pharmacological separation of depolarizing and hyperpolarizing mechanisms involved in the generation of acetylcholine (ACh) depolarizations was attempted in the identified neurons B1 and B3 of the buccal ganglia of Helix pomatia. The selectivity of the drugs employed was assayed in non-identified buccal neurons in which ACh increased a hyperpolarizing Cl- conductance. Voltage clamp techniques were used. Under control conditions the depolarizing ACh currents increased non-linearly with more negative membrane potentials. The hyperpolarizing ACh currents showed a linear potential dependence. The buffer substance Tris (5 mmol/l) depressed the depolarizing ACh currents. The effect was accentuated with more negative membrane potentials. Tris failed to affect hyperpolarizing ACh responses. HEPES (5 mmol/l) did not change depolarizing or hyperpolarizing ACh responses. d-Tubocurarine (0.02-0.2 mmol/l), hexamethonium (0.5-5.0 mmol/l) and atropine (0.1 mmol/l) blocked the depolarizing and hyperpolarizing ACh responses. Arecoline (0.1 mmol/l) had neither an agonistic nor an antagonistic effect on the identified and on the non-identified neurons. It displayed an anticholinesterase activity. Anthracene-9-carbonic acid (0.5 mmol/l) depressed selectively the hyperpolarizing ACh responses. In the neurons B1 and B3 no pharmacologically separable hyperpolarizing ACh responses were detected to be superimposed on the ACh depolarizations.

Distribution of receptors for acetylcholine and 5-hydroxytryptamine on identified leech neurones growing in culture

The spatial distribution of receptors on identified leech neurones removed from the C.N.S. and grown in culture has been studied by applying acetylcholine (ACh) and 5-hydroxytryptamine (5-HT) ionophoretically and by pressure. Two cells were selected: a neurone called anterior Pagoda (Ap), that shows responses to ACh, and the pressure sensory neurone (P cell), upon which 5-HT synapses form in culture. ACh receptors of Ap neurones in culture had properties similar to those of their counterparts in situ. Thus, ACh responses of Ap cells were mediated by Cl- and were blocked by curare and alpha-bungarotoxin. The cell bodies of these neurones in culture had low (10 mV/nC) and uniform sensitivity to ACh over the surface of the soma. When a sprout grew out from the Ap cell, a region of increased sensitivity appeared at its base, with a gradient of sensitivity decreasing toward the tip of the neurite. Characteristically, the base was 3-5 times more sensitive to ACh than the soma or the growth cone. Cells with multipolar processes developed a similar pattern of sensitivity for each sprout. P sensory neurones in culture showed similar distributions of sensitivity to 5-HT and ACh. Experiments made with voltage clamp suggested that the non-uniform responses to transmitter represent true differences in sensitivity. Together these findings suggest that the receptors for ACh and 5-HT have a greater density at the base of each neurite compared to that of the soma and the tip.

The pharmacology of molluscan neurons

It is commonly accepted that the basic physiological properties of the neurons as well as the nature of transmitter substances have remained relatively unchanged through evolution, while brain size and neuron number have greatly increased. Among invertebrates the molluscs, due to the large size of their neurons and lesser complexity of the neural networks controlling specific behavior, have proved to be especially useful for studying elementary properties of single neurons, network organization as well as various forms of learning and memory. The study of putative neurotransmitters has indicated that molluscs use the same low molecular-weight substances and peptides or their metabolites and cyclic nucleotides as transmitters and second messengers as the other species of various phyla. At the same time the receptors of neurotransmitters were found to have certain characteristic properties in the molluscs. The large molluscan neurons have permitted the isolation of individual identifiable nerve cells, and the subsequent analysis of quantities of the transmitters and their metabolic enzymes. These studies have demonstrated that single neurons frequently can contain more than one putative neurotransmitter. It can be expected that this model will contribute to an understanding of the role of multiple transmitters within a single neuron assuring the plasticity of the nervous system. The cellular mechanisms of plasticity have been demonstrated first in molluscan nervous systems. It was proved in identified Aplysia neurons that the same transmitter (ACh) can be released from an interneuron onto two or more follower neurons and can excite one and inhibit another or evoke a biphasic response on a third type of cell. The biphasic response of the molluscan neurons to neurotransmitters was the first demonstration of the plastic synaptic changes. The discovery of individual neurons with their groups of follower cells acting as chemical units has provided an insight into the organization of various behavioral acts. Study of the gastropod molluscs has also shown that the giant serotonergic cells can act as peripheral modulator neurons, as well as interneurons, and in this way they can affect their target organs at more than one level. The molluscan studies have provided more information on transmitter receptors as it was shown that molluscan neurons have at least six different 5HT receptors, three Ach receptors which can be separated pharmacologically. This type of study has led to the discovery of numerous new antagonists and poisons.(ABSTRACT TRUNCATED AT 400 WORDS)

A cholinergic chloride conductance in neurones of Helix aspersa

Inhibitory Cl- -mediated currents through cholinergic channels on the soma of identified neurones from the right parietal ganglion of Helix aspersa were studied under voltage clamp. Voltage-jump relaxation analysis showed that these currents decreased with hyperpolarization. In 3 microM-acetylcholine (ACh), the normalized fraction of channels in the open configuration (rho) decreased e-fold with each 191 mV of membrane hyperpolarization. The steady-state membrane conductance, G(infinity), decreased e-fold with each 128 mV of membrane hyperpolarization. The difference in the voltage sensitivities of rho and G(infinity) arose because of the voltage sensitivity of the instantaneous membrane conductance, G(0). G(0) rectified in the direction predicted by the Goldman-Hodgkin-Katz conductance model. The degree of rectification decreased when the internal Cl- concentration was raised. The relaxing currents were composed of two exponential components. At membrane potential (Vm) = -160 mV, 12 degrees C, the time constants of the two components were 4.1 ms and 21 ms in 3 microM-ACh, and 3.6 ms and 18 ms in 100 microM-tetramethylammonium (TMA). Fluctuation analysis in neurones loaded with Cl- yielded spectra which were composed of two Lorentzian components. In 3 microM-ACh the mean single-channel conductance (gamma) appeared to rise from a low value observed in cells with normal intracellular Cl- to 2.7 pS in cells whose internal Cl- concentration was raised four-fold. The voltage sensitivity of rho was attributed to the conformational change step of a gating mechanism having three kinetically distinguishable states.

Analysis of glycine-activated inhibitory post-synaptic channels in brain-stem neurones of the lamprey

Voltage-clamp techniques were used to measure fluctuations in membrane current produced by the application of glycine to Müller cells in the brain stem of the lamprey. The power density spectrum of the glycine-induced current 'noise' was consistent with the hypothesis that glycine activated a single population of conductance channels with open times determined by first-order kinetics. In normal bathing solution the channel conductance was 73 +/- 12 pS (mean +/- S.D.) and the channel open time 34 +/- 6 msec at 5 degrees C. The reversal potential for the response was 66 +/- 5 mV. Neither channel conductance nor mean open time was voltage-dependent. Replacement of Cl- in the bathing solution by isethionate and sulphate reversibly abolished the response to glycine. Increasing intracellular Cl-, either by using Cl- -filled micropipettes or by raising extracellular K+, decreased channel conductance. This unexpected decrease was a direct effect of intracellular Cl- and was not related to coincident changes in reversal potential. Channel open time was unaffected by intracellular Cl- concentration. Reducing extracellular Cl- concentration from 126.5 to 31 mM reduced channel conductance at all levels of intracellular Cl- without affecting open time. Increasing the temperature of the preparation resulted in increase in channel conductance and a decrease in mean open time. Q10S for the effects were of the order of 1.3 and -2.3 respectively in the range 4-14 degrees C.

Comparison of excitatory currents activated by different transmitters on crustacean muscle. I. Acetylcholine-activated channels

The properties of acetylcholine-activated excitatory currents on the gm1 muscle of three marine decapod crustaceans, the spiny lobsters Panulirus argus and interruptus, and the crab Cancer borealis, were examined using either noise analysis, analysis of synaptic current decays, or analysis of the voltage dependence of ionophoretically activated cholinergic conductance increases. The apparent mean channel open time (tau n) obtained from noise analysis at -80 mV and 12 degrees C was approximately 13 ms; tau n was prolonged e-fold for about every 100-mV hyperpolarization in membrane potential; tau n was prolonged e-fold for every 10 degrees C decrease in temperature. Gamma, the single-channel conductance, at 12 degrees C was approximately 18 pS and was not affected by voltage; gamma was increased approximately 2.5-fold for every 10 degrees C increase in temperature. Synaptic currents decayed with a single exponential time course, and at -80 mV and 12 degrees C, the time constant of decay of synaptic currents, tau ejc, was approximately 14-15 ms and was prolonged e-fold about every 140-mV hyperpolarization; tau ejc was prolonged about e-fold for every 10 degrees C decrease in temperature. The voltage dependence of the amplitude of steady-state cholinergic currents suggests that the total conductance increase produced by cholinergic agonists is increased with hyperpolarization. Compared with glutamate channels found on similar decapod muscles (see the following article), the acetylcholine channels stay open longer, conduct ions more slowly, and are more sensitive to changes in the membrane potential.

Inhibitory postsynaptic currents at Aplysia cholinergic synapses: effects of permeant anions and depressant drugs

Inhibitory postsynaptic potentials (i.p.s.ps) and, under voltage-clamp conditions, inhibitory postsynaptic currents (i.p.s.cs) were recorded in neurons in buccal ganglia of Aplysia juliana. The decay of i.p.s.cs was exponential with a single time constant, tau, which decreased with membrane depolarization. In external solutions containing iodide or bromide ions instead of chloride ions, tau varied according to the sequence tau (I) greater than tau (Br) greater than tau (Cl), and the voltage sensitivity of tau was altered. In iodide solution, the voltage sensitivity of tau was reversed. Furthermore, the foreign halides depressed the peak current amplitude and shifted the reversal (zero-current) potential to more positive membrane potentials. In low concentrations of sodium pentobarbitone (100-200 microns), the decay of i.p.s.cs became biphasic. Increasing drug concentration and membrane hyperpolarization had differential effects on the rates and relative amplitudes of the two components of i.p.s.c. decay. Octanol (0.5-1 mM) reduced the amplitude of i.p.s.ps and increased the rate of decay of i.p.s.cs without changing the voltage sensitivity of tau. The effect of foreign halides and barbiturates on i.p.s.c. decay were interpreted in terms of a reaction between the anion and an ion-binding site(s) associated with the anion-selective channel, which affects the probability of anions entering the channel and normal channel closure.

Inhibition of acetylcholine responses by intracellular calcium in Lymnaea stagnalis neurones

1. Acetylcholine (ACh)-induced currents were studied in completely isolated Lymnaea stagnalis neurones using the voltage-clamp technique. 2. The ACh-activated pathways were shown to be selective for Cl- ions. 3. It was shown that membrane depolarization inhibits ACh-induced conductance. This phenomenon was called 'ACh response inactivation'. 4. Inactivation decreases after lowering the extracellular Ca2+ concentration or after blockade by Mn2+ of the electrically excitable Ca2+ channels. 5. In dialysed neurones an increase of the intracellular Ca2+ concentration inhibits the ACh-induced conductance. 6. The conclusion is made that the inactivation of ACh response by depolarization is initiated by Ca2+ entering the neurone through the electrically excitable Ca channels. 7. The onset and the decay of the ACh response inactivation were studied by analysing the relaxations of the ACh-induced current during and after the application of depolarizing pulses. The most conspicuous relaxation is a slow relaxation observed at the end of a long depolarizing pulse, which appears to reflect the return of the system from the inactivated state to the non-inactivated one. 8. The slow relaxations observed during and after a depolarizing pulse appear correlated with variations of the intracellular Ca2+ concentration, and are distinct from faster relaxations observed in the hyperpolarizing range and attributed to the voltage dependence of the channel open-time.

Time integral of synaptic conductance

1. Inhibitory post-synaptic currents (i.p.s.c.s) were recorded under voltage clamp from neurones of Aplysia buccal ganglia. 2. The synaptic charge, Q, transferred by each i.p.s.c. was calculated as the time integral of the synaptic current, approximated by numerical integration. For typical i.p.s.c.s recorded at or near resting potential, Q = -100 to -500 pC. The majority of the charge is transferred during the interval between the peak and a time one time constant later. 3. In order to characterize an alternative measurement of synaptic efficacy, the slope of the Q vs. membrane potential curve was calculated and defined as the time integral of conductance, b. Values of b ranged from 2.6 to 51 pC/mV, averaging 14 pC/mV. For i.p.s.c.s recorded in thirty-one cells at room temperature, b was well correlated with Gpeak, the peak synaptic conductance (r = 0.86). 4. In most synapses, the time integral of conductance, which incorporates both amplitude and duration, may be a more revealing measure of synaptic efficacy than peak conductance. 5. Size of synaptic response was determined as a function of temperature, T. While Gpeak decreases with decreasing temperature over the range 9-22 degrees C, b peaks at 12-18 degrees C and decreases at higher and lower values of T. The data permit the speculation that lengthening average channel lifetime, and therefore time constant of decay, with decreasing temperature, may have adaptive significance in maintaining synaptic efficacy.

Rate-limiting step of inhibitory post-synaptic current decay in Aplysia buccal ganglia

1. In neurones BL and BR 3, 6, 8, 9, 10 and 11 of Aplysia buccal ganglia, cholinergic inhibitory post-synaptic potentials are produced by activity in either of two presynaptic cells. In order to analyse the synaptic conductance change, neurones were voltage-clamped inhibitory post-synaptic currents (i.p.s.c.) recorded. 2. The synaptic conductance change rises to an average peak value of 0.65 micromho and decays exponentially with single time constant tau of 19 msec. 3. We have attempted to identify the rate-limiting step responsible for i.p.s.c. decay from among the following possibilities: (1) acetylcholine (ACh) supply, (2) ACh removal by diffusion, (3) ACh removal by hydrolysis or (4) a slow unbinding or conformational change closing open synaptic current channels. 4. Cooling prolongs tau, with Q10 of 5.2. Cooling and eserine treatment together produce greatly prolonged, exponentially decaying i.p.s.c.s with tau > 150 msec. These results suggest that ACh removal, either by diffusion or hydrolysis, is not the rate-limiting step. 5. Prolonging synaptic action potential time course with intracellular injection of tetraethylammonium broadens the i.p.s.c. peak but does not affect the decay tail, suggesting that the rate-limiting step is not ACh release. 6. The spectrum of ACh-induced current fluctuations is fitted by a double Lorentzian with cut-off frequencies of 7.8 and 47 Hz. The frequency of the slower component corresponds to the macroscopic i.p.s.c. decay tau. 7. We conclude that a slow conformational change closing open synaptic current channels is likely to determine i.p.s.c. decay. We cannot, however, exclude either delayed diffusion or a late tail of slow ACh release as possibilities.