Differences in synaptic GABA(A) receptor number underlie variation in GABA mini amplitude.

In many neurons, responses to individual quanta of transmitter exhibit large variations in amplitude. The origin of this variability, although central to our understanding of synaptic transmission and plasticity, remains controversial. To examine the relationship between quantal amplitude and postsynaptic receptor number, we adopted a novel approach, combining patch-clamp recording of synaptic currents with quantitative immunogold localization of synaptic receptors. Here, we report that in cerebellar stellate cells, where variability in GABA miniature synaptic currents is particularly marked, the distribution of quantal amplitudes parallels that of synaptic GABA(A) receptor number. We also show that postsynaptic GABA(A) receptor density is uniform, allowing synaptic area to be used as a measure of relative receptor content. Flurazepam, which increases GABA(A) receptor affinity, prolongs the decay of all miniature currents but selectively increases the amplitude of large events. From this differential effect, we show that a quantum of GABA saturates postsynaptic receptors when <80 receptors are present but results in incomplete occupancy at larger synapses.

Estimated conductance of glutamate receptor channels activated during EPSCs at the cerebellar mossy fiber-granule cell synapse.

We have analyzed the variance associated with the decay of the non-NMDA receptor component of synaptic currents, recorded from mossy fiber-granule cell synapses in cerebellar slices, to obtain a conductance estimate for the synaptic channel. Current fluctuations arising from the random channel gating properties were separated from those arising from the fluctuations in the population of channels by subtracting the mean excitatory postsynaptic current (EPSC) waveform scaled to the EPSC peak amplitude. A weighted mean single-channel conductance of approximately 20 pS was determined from the relationship between the mean current and the variance around the mean during the decay of evoked and spontaneous synaptic currents. This result suggests that high conductance non-NMDA channels, such as the 10-30 pS glutamate receptor channel previously characterized in granule cells, carry the majority of the fast component of the EPSC at this synapse. In addition, our data are consistent with the activation of surprisingly few (approximately 10) non-NMDA channels by a single packet of transmitter.

Neurotransmitters. NMDA receptors: do glia hold the key?

NMDA receptor stimulation requires binding of a 'co-agonist' and the neurotransmitter glutamate at separate sites. Are ligands for the co-agonist site liberated by glia, following activation of glial glutamate receptors?

Neurotransmitters. Elusive glutamate receptors.

Kainate-preferring glutamate receptors appear to be abundant in the central nervous system. We have recently begun to understand their properties, but their functions remain to be described.

NMDA receptor subunits: diversity, development and disease.

N-methyl-D-aspartate receptors (NMDARs) are present at many excitatory glutamate synapses in the central nervous system and display unique properties that depend on their subunit composition. Biophysical, pharmacological and molecular methods have been used to determine the key features conferred by the various NMDAR subunits, and have helped to establish which NMDAR subtypes are present at particular synapses. Recent studies are beginning to address the functional significance of NMDAR diversity under normal and pathological conditions.

CNQX increases GABA-mediated synaptic transmission in the cerebellum by an AMPA/kainate receptor-independent mechanism.

GABA(A) receptor-mediated inhibitory synaptic transmission within the CNS is often studied in the presence of glutamate receptor antagonists. However, for nearly a decade it has been known that, in the hippocampus, one of the most commonly used alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/kainate receptor antagonists, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), can increase the frequency of spontaneous GABA(A) receptor-mediated postsynaptic currents (sIPSCs). In the present study we examined the effect of CNQX and related compounds on GABA-mediated synaptic transmission in the cerebellum. At various stages of development, low concentrations of CNQX increased the frequency of sIPSCs recorded from granule cells. This effect was independent of the blocking action of CNQX on ionotropic glutamate receptors, as it was not observed with the broad-spectrum glutamate receptor antagonist kynurenate. No increase in sIPSC frequency was observed with the NMDA receptor antagonists D-AP5 or 7-ClK, the selective AMPA receptor antagonists GYKI 52466 or GYKI 53655, or the kainate receptor antagonist NS-102. In contrast, two other quinoxaline derivatives, NBQX and DNQX, were capable of increasing sIPSC frequency. These results demonstrate that the novel excitatory action of CNQX, unrelated to blockade of ionotropic glutamate receptors, is not restricted to the hippocampus and can be observed with structurally related compounds.

NMDA receptor diversity in the cerebellum: identification of subunits contributing to functional receptors.

Recent studies of N-methyl-D-aspartate (NMDA) receptors have led to the suggestion that there are two distinct classes of native NMDA receptors, identifiable from their single-channel conductance properties. 'High-conductance' openings arise from NR2A- or NR2B-containing receptors, and 'low-conductance' openings arise from NR2C- or NR2D-containing receptors. In addition, the low-conductance channels show reduced sensitivity to block by Mg2+. The readily identified cell types and simple architecture of the cerebellum make it an ideal model system in which to determine the contribution of specific subunits to functional NMDA receptors. Furthermore, mRNA for all of these four NR2 subunits are represented in this brain region. We have examined NMDA channels in Purkinje cells, deep cerebellar nuclei (DCN) neurons and Golgi cells. First we find that NR2D-containing NMDA receptors give rise to low-conductance openings in cell-attached recordings from Purkinje cells. The characteristic conductance of these events cannot, therefore, be ascribed to patch excision. Second, patches from some DCN neurons exhibit mixed populations of high- and low-conductance openings. Third, Golgi cells also exhibit a mixed population of high- and low-conductance NMDA receptor openings. The features of these low-conductance openings are consistent with the presence of NR2D-containing NMDA receptors, as suggested by in situ hybridization data. On the other hand the existence of high-conductance channels, with properties typical of NR2B-containing receptors, was not expected. Our results provide new evidence about the subunit composition of NMDA receptors in identified cerebellar cells, and suggest that examination of single-channel properties is a potentially powerful approach for determining the possible subunit composition of native NMDA receptors.

The effects of taipoxin and notexin on the function and fine structure of the murine neuromuscular junction.

The isolated neurotoxins taipoxin and notexin from the venoms of the Elapidae, Oxyuranus scutellatus and Notechis scutatus scutatus respectively cause a neuromuscular block when administered to the mouse in vivo or to the phrenic nerve-hemidiaphragm preparation in vitro. The block is preceded by a latency period during which the toxins bind irreversibly to the nerve. The period is shortened by nerve activity. The frequency of the miniature end-plate potentials is gradually reduced, almost to zero, and their amplitude distribution is altered; small and very large miniature endplate potentials appearing. Ultrastructurally the endplates are altered in the presynaptic portion but not in the postsynaptic part. In an early stage of poisoning the axolemma has an increased number of omega-shaped indentations similar in size to synaptic vesicles. At a later stage, when the animals die of respiratory paralysis, the axolemmal indentations are more numerous and the synaptic vesicles greatly reduced in number, the remaining vesicles having a variable and frequently larger than normal size. When impulse activity in the phrenic nerve is stopped by cutting the nerve before the administration of toxin there is no reduction in the number of synaptic vesicles, only the appearance of an increased number of axolemmal indentations. It is suggested that taipoxin and notexin irreversibly interfere with the formation of synaptic vesicles by arresting vesicle membrane recycling at the level of the axolemma. When the pre-existing store of vesicles is depleted, by nerve activity, a neuromuscular block results.

Excitatory amino acid receptor-channels in Purkinje cells in thin cerebellar slices.

Glutamate receptors of the N-methyl-D-aspartate (NMDA) and non-NMDA type serve different functions during excitatory synaptic transmission. Although many central neurons bear both types of receptor, the evidence concerning the sensitivity of cerebellar Purkinje cells to NMDA is contradictory. To investigate the receptor types present in Purkinje cells, we have used whole-cell and outside-out patch-clamp methods to record from cells in thin cerebellar slices from young rats. At a holding potential of -70 mV (in nominally Mg(2+)-free medium, with added glycine) NMDA caused a whole-cell current response which consisted of a dramatic increase in the frequency of synaptic currents. In the presence of tetrodotoxin (TTX) and the gamma-aminobutyric acidA (GABAA) receptor antagonist bicuculline, spontaneous synaptic currents and responses to NMDA were inhibited. In a proportion of cells a small polysynaptic response to NMDA persisted, which was further reduced by the non-NMDA receptor antagonist 6-cyano-2,3-dihydro-7-nitroquinoxalinedione (CNQX). The non-NMDA glutamate receptor agonists kainate (KA), quisqualate (QA) and s-alpha-amino-3-hydroxy-5-methyl-4-isoazolepropionic acid (s-AMPA), evoked large inward currents due to the direct activation of receptors in Purkinje cells. NMDA applied to excised membrane patches failed to evoke any single-channel currents, whereas s-AMPA and QA caused small inward currents accompanied by marked increases in current noise. Spectral analysis of the s-AMPA noise in patches gave an estimated mean channel conductance of approximately 4 pS.(ABSTRACT TRUNCATED AT 250 WORDS)

Glutamate and aspartate activated channels and inhibitory synaptic currents in large cerebellar neurons grown in culture.

Patch-clamp methods were used to examine large (greater than 30 microns) cerebellar neurons of the rat, maintained in cell culture. Cells possessed voltage-activated transient inward Na+ currents which were sensitive to tetrodotoxin. Spontaneous synaptic currents, present in whole-cell recordings, were abolished by bicuculline and picrotoxin and were carried by Cl-. Cells produced inward currents in response to the transmitter candidates glutamate and aspartate and also to the glutamate agonists kainate, quisqualate, N-methyl-D-aspartate and ibotenate. Analysis of glutamate and aspartate-current noise has been used to derive characteristics of the excitatory channels. Single channel currents have also been observed directly in whole-cell and outside-out patches. Both glutamate and aspartate are able to activate channels which were blocked by Mg2+ and had a maximum conductance of 50 pS.

Ion channels activated by acetylcholine and gamma-aminobutyric acid in freshly dissociated sympathetic neurones of the rat.

Transmitter-activated channels in freshly isolated neurones from sympathetic ganglia of young rats have been examined using the patch-clamp technique. Acetylcholine (ACh), gamma-aminobutyric acid (GABA) and (in about one third of cells) glycine produced an inward current and an increase in current noise when perfused onto voltage-clamped neurones. The ACh noise was fitted with a single Lorentzian spectrum with a time constant of 13.1 ms at -70 mV. Outside-out membrane patches allowed high-resolution measurements of single ACh- and GABA-activated channels. The ACh-channels had a conductance of 30 pS.

Transmembrane AMPA receptor regulatory proteins and AMPA receptor function in the cerebellum.

Heterogeneity among AMPA receptor (AMPAR) subtypes is thought to be one of the key postsynaptic factors giving rise to diversity in excitatory synaptic signaling in the CNS. Recently, compelling evidence has emerged that ancillary AMPAR subunits-the so-called transmembrane AMPA receptor regulatory proteins (TARPs)-also play a vital role in influencing the variety of postsynaptic signaling. This TARP family of molecules controls both trafficking and functional properties of AMPARs at most, if not all, excitatory central synapses. Furthermore, individual TARPs differ in their effects on the biophysical and pharmacological properties of AMPARs. The critical importance of TARPs in synaptic transmission was first revealed in experiments on cerebellar granule cells from stargazer mice. These lack the prototypic TARP stargazin, present in granule cells from wild-type animals, and consequently lack synaptic transmission at the mossy fibre-to-granule cell synapse. Subsequent work has identified many other members of the stargazin family which act as functional TARPs. It has also provided valuable information about specific TARPs present in many central neurons. Because much of the initial work on TARPs was carried out on stargazer granule cells, the important functional properties of TARPs present throughout the cerebellum have received particular attention. Here we discuss some of these recent findings in relation to the main TARPs and the AMPAR subunits identified in cerebellar neurons and glia.

Two types of extrajunctional L-glutamate receptors in locust muscle fibres.

L-glutamate applied iontophoretically to the extrajunctional membrane of locust muscle produced a biphasic response, depolarization followed by hyperpolarization (i.e. DH-response). Applying L-glutamate and DL-ibotenate from multibarrel micropipettes allowed comparison of their extrajunctional responses. While glutamate produced a two component response, ibotenate produced a single component H-response. 2. The equilibrium values for the H-responses to L-glutamate and DL-ibotenate applied at the same extrajunctional site were very similar. The equilibrium value was 59-5 +/- 5-4 mV indicating an increased Cl- conductance. The H-response was reversed and abolished in Cl- free medium. Picrotoxin 10(-3) M selectively blocked the H-component of the DH-response in a reversible manner. 3. The possibility that the D- and H-responses arose from the activation of two distinct types of extrajunctional glutamate receptors was investigated. Desensitization of the glutamate H-response by ibotenate and vice versa indicated the presence of an extrajunctional H-receptor sensitive to glutamate and ibotenate and an extrajunctional D-receptor sensitive to glutamate and insensitive to ibotenate. The junctional depolarizing response to glutamate was insensitive to ibotenate. 4. The presence of junctionally occurring H-receptors could not be discounted, although, if present, they were not measurably activated by the excitatory transmitter. 5. Double logarithmic plots (coulomb dose vs. response) for the actions of glutamate and ibotenate on H-receptors had values of 0-75, indicating that both drugs act on the same receptors with similar mechanisms. The value for the action of glutamate on the D-receptors was 1-5. 6. While the extrajunctional D-receptors show analogies to the extrajunctional ACh receptors in vertebrate muscle, the significance of the extrajunctional H-receptors remains speculative.

Inhibitory synaptic currents in voltage-clamped locust muscle fibres desensitized to their excitatory transmitter.

Inhibitory junctional currents (i.j.c.s) have been examined in locust muscle fibres to give properties of GABA-channels activated by the neurally released transmitter. A nerve-muscle preparation is described which has proved suitable for voltage-clamp analysis of inhibitory transmission. I.j.c.s were recorded from fibres in which excitatory synapses had been desensitized with glutamate, to abolish excitatory junctional currents. This procedure had no apparent effect on inhibitory channel properties. The time constant of decay of the i.j.c. was 7.7 +/- 0.3 ms, slightly exceeding the time constant of the membrane noise induced by externally applied GABA. Peak i.j.c. conductance decreased with hyperpolarization. I.j.c.s showed measurable fluctuations permitting an estimate of the mean size of the quantal events composing the i.j.c. Their mean size coincided with the spontaneously occurring miniature inhibitory junctional currents that could be directly recorded in some fibres. The inhibitory nerve-impulse released an average of 35 transmitter packets at sites distributed along the muscle fibre length. Since each m.i.j.c. produced a current of about 0.6 nA (at Vm = -80 mV, ECl = -40 mV) the single quantum of inhibitory transmitter opens 600-1000 postsynaptic chloride channels. This is roughly three to four times the number of channels opened by the excitatory transmitter packet at glutamate synapses in the same fibres.

Glutamate sensitivity and distribution of receptors along normal and denervated locust muscle fibres.

1. Factors influencing the glutamate sensitivity of extrajunctional regions of innervated and denervated locust muscle fibres have been investigated. Properties of the two types of extrajunctional glutamate receptors, D- and H-receptors, have been studied in regions of high and low sensitivity. 2. The low level of extrajunctional sensitivity which is normally present in innervated fibres was 20-30 times higher at the muscle-tendon junction than at other sites; increased sensitivity extended about 20-40 micron from the tendon. After denervation or localized damage the entire extrajunctional sensitivity was increased approximately 100 times above control levels. 3. Applying L-glutamate (which activates D- and H-receptors) and DL-ibotenate (which activates H-receptors) from multibarrelled micropipettes showed that increased extrajunctional sensitivity resulted from an increase in D-receptors while H-receptors were apparently unchanged. 4. Coulomb dose vs. response relationships for the action of glutamate on D-receptors were similar when obtained at the muscle-tendon junction and nerve-muscle junction of innervated fibres or at extrajunctional regions in denervated fibres. 5. Time course of onset and percentage desensitization of D- and H-receptors in innervated fibres were similar. The percentage desensitization of D-receptors in extrajunctional regions of high sensitivity was greatly reduced. 6. It is suggested that D- and H-receptors are independent and that the trigger for increased receptor sensitivity acts specifically on D-receptors. In all respects so far studied, the D-receptors resemble extrajunctional ACh-receptors in vertebrate muscle.

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.