Convulsive properties of d-tubocurarine and cortical inhibition

Acetylcholine receptors and thresholds for convulsions from flurothyl and 1,2-dichlorohexafluorocyclobutane

There are acetylcholine receptors throughout the central nervous system, and they may mediate some forms and aspects of convulsive activity. Most high-affinity binding sites on nicotinic acetylcholine receptors for nicotine, cytisine, and epibatidine in the brain contain the beta2 subunit of the receptor. Transitional inhaled compounds (compounds less potent than predicted from their lipophilicity and the Meyer-Overton hypothesis) and nonimmobilizers (compounds that do not produce immobility despite a lipophilicity that suggests anesthetic qualities as predicted from the Meyer-Overton hypothesis) can produce convulsions. The nonimmobilizer flurothyl [di-(2,2,2,-trifluoroethyl)ether] blocks the action of gamma-aminobutyric acid on gamma-aminobutyric acid(A) receptors, whereas the nonimmobilizer 1,2-dichlorohexafluorocyclobutane (2N, also called F6) does not. 2N can block the action of acetylcholine on nicotinic acetylcholine receptors. We examined the relative capacities of these compounds to cause convulsions in mice having and lacking the beta2 subunit of the acetylcholine receptor. The partial pressure causing convulsions in half the mice (the 50% effective concentration [EC(50)]) was the same as in control mice. For the knockout mice, the EC(50) for flurothyl was 0.00170 +/- 0.00030 atm (mean +/- SD), and for 2N, it was 0.0345 +/- 0.0041 atm. For the control mice, the respective values were 0.00172 +/- 0.00057 atm and 0.0341 +/- 0.0048 atm. The ratio of the 2N to flurothyl EC(50) values was 20.8 +/- 3.5 for the knockout mice and 21.7 +/- 7.0 for the control mice. These results do not support the notion that acetylcholine receptors are important mediators of the capacity of 2N or flurothyl to cause convulsions. However, we also found that both nonimmobilizers inhibit rat alpha4beta2 neuronal nicotinic acetylcholine receptors at EC(50) partial pressures (0.00091 atm and 0.062 atm for flurothyl and 2N, respectively) that approximate those that produce convulsions (0.0015 atm and 0.04 atm).

IMPLICATIONS

The results from the present study provide conflicting data concerning the notion that acetylcholine receptors mediate the capacity of nonimmobilizers to produce convulsions.

Cerebrospinal fluid concentrations of atracurium, laudanosine and vecuronium following clinical subarachnoid hemorrhage

BACKGROUND

Neuromuscular blocking agents may exert central nervous system effects when they reach the brain. This study assessed the concentrations and the time course of passage of vecuronium, atracurium, and its metabolite laudanosine in the cerebrospinal fluid (CSF) of patients undergoing intracranial aneurysm clipping.

METHODS

Twenty-five patients with subarachnoid hemorrhage were randomly allocated to receive an intravenous infusion of vecuronium (n=13) or atracurium (n=12). Arterial blood and lumbar CSF were sampled before and 1, 2, 3, 4 and 8 h after the start of the relaxant infusion. The samples were analyzed by liquid chromatography-electrospray ionization mass spectrometry (vecuronium) and high-pressure liquid chromatography (atracurium and laudanosine).

RESULTS

The data of 20 patients (10 in both groups) were analyzed. In 11 CSF samples from five patients atracurium was detected in concentrations from 10 to 50 ng/ml. Laudanosine was retrieved in all CSF samples at 1, 2, 3, 4 and 8 h; the highest CSF concentration of laudanosine occurred at 3 h [38 (18-63) ng/ml: median (range)]. Vecuronium was not found in any CSF sample.

CONCLUSION

Significant concentrations of atracurium and laudanosine but not of vecuronium were detected in the CSF of patients during and immediately after intracranial aneurysm surgery.

Modulation of synaptic transmission by nicotine and nicotinic antagonists in hippocampus

Using rat hippocampal slices, we studied the effects of nicotine and three antagonists of neuronal nicotinic receptors on excitatory and inhibitory transmission. We report that nicotine at concentrations between 0.5 and 100 microM enhanced excitatory synaptic responses and increased the size of the presynaptic fiber volley. This effect was reproduced by three neuronal nicotinic receptor antagonists: dihydro-beta-erythroidine, methyllycaconitine and mecamylamine. In contrast, nicotine, but not nicotinic antagonists, produced a dual effect on inhibition: nicotine enhanced gamma-aminobutyric-acid A (GABA(A)) receptor-mediated synaptic responses at low concentration (0.5 microM) and blocked them at high concentration (100 microM). We conclude that the excitatory effects of nicotine are reproduced by nicotinic receptor antagonists, thereby suggesting that these effects might be mediated through receptor desensitization. These results also indicate that nicotine differentially affects GABAergic inhibition at low and high concentrations-effects that are not reproduced by antagonists.

Glycine receptor immunoreactivity in rat and human cerebral cortex

The distribution of the inhibitory glycine receptor was studied in rat and human cerebral cortex using a monoclonal antibody (MAb 4a) directed against the ligand-binding subunit. Significant amounts of glycine receptor antigen were found in forebrain structures such as caudatum and neocortex, although cortical levels were significantly below those seen in spinal cord. Immunohistochemically, glycine receptors were preferentially localized to the apical dendrites of pyramidal neurons in layers III and V. Ultrastructurally, these sites corresponded to synaptic neuronal contacts. Immunoreactivity was found in neuronal perikarya, dendrites and postsynaptic membranes which may correspond to sites of intracellular synthesis, transport and membrane incorporation of the glycine receptor. These immunological data corroborate previous pharmacological studies suggesting the existence of glycinergic transmission in mammalian cerebral cortex.

Pharmacology of nicotinic receptor-mediated inhibition in rat dorsolateral septal neurones

1. Intracellular electrophysiological techniques were employed to investigate the effects of nicotinic receptor stimulation on rat dorsolateral septal nucleus (DLSN) neurones in a submerged rat brain slice preparation. 2. Acetylcholine (in the presence of the muscarinic antagonist, atropine), nicotine or dimethylphenylpiperazinium (DMPP), applied either by pressure ejection or superfusion, produced predominantly a membrane potential hyperpolarization. 3. Following concentration-response comparisons, DMPP appeared to exhibit fewer desensitizing properties and greater efficacy than nicotine with half-maximal hyperpolarizing responses attainable at 3 and 10 microM, respectively. 4. Pharmacological analyses revealed that the agonist-induced membrane hyperpolarization was sensitive to antagonism by mecamylamine (50-100 microM) and neuronal bungarotoxin (0.2-0.3 microM), but not alpha-bungarotoxin (0.5-1.0 microM), curare (10-50 microM) or dihydro-beta-erythroidine (50-100 microM). 5. Hyperpolarizing responses to DMPP were found to reverse near the equilibrium potential for potassium and were sensitive to changes in extracellular potassium concentration as predicted by the Nernst equation. Under single-electrode voltage clamp, application of DMPP produced an outward current (75-100 pA) which approached reversal at around -88 mV. These findings indicated that the hyperpolarizing response to nicotinic receptor stimulation was mediated by changes in membrane permeability to potassium. 6. DMPP-induced membrane hyperpolarization resulted from a direct action on postsynaptic DLSN neurones since the response persisted under conditions of superfusion with calcium-free/high-magnesium media or tetrodotoxin; both conditions blocked orthodromically induced neurotransmission. The hyperpolarizing response remained unaltered in TTX but was diminished in calcium-free/high-magnesium media. Further studies revealed blockade of the DMPP response following intracellular injection of EGTA. This response was also sensitive to antagonism by various calcium-dependent potassium channel blockers including apamin, barium and tetraethylammonium. 7. Our studies reveal a novel class of CNS nicotinic receptor whose action upon stimulation by an agonist results in a membrane hyperpolarization via a calcium-dependent increase in potassium ion conductance.

Characterization of GABA- and glycine-induced currents of solitary rodent retinal ganglion cells in culture

Ganglion cells were fluorescently labeled, dissociated from 7- to 11-day-old rodent retinas, and placed in tissue culture. Whole-cell recordings with patch electrodes were obtained from solitary cells lacking processes, which permitted a high-quality space clamp. Both GABA (1-200 microM) and glycine (10-300 microM) produced large increases in membrane conductance in virtually every ganglion cell tested, including ganglion cells from different size classes in both rats and mice. Taurine evoked responses similar to those of glycine, but considerably greater concentrations of taurine (150-300 microM) were necessary to observe any effect. Since 20 microM GABA produced approximately the same response as 100 microM glycine, the effects of these two concentrations were compared under various conditions. When recording with chloride distributed equally across the membrane, the reversal potential of the agonist-induced currents was approximately 0 mV. When the internal chloride was reduced by substitution with aspartate, the reversal potential shifted in a negative direction by about 42 mV, indicating that the current was carried mainly by chloride ions. Strychnine (1-5 microM) completely and reversibly blocked the actions of glycine (100 microM) but not those of GABA (20 microM); however, higher concentrations of strychnine (20 microM) nearly totally inhibited the current elicited by GABA (20 microM). The responses to glycine (100 microM) were not affected by bicuculline methiodide (20 microM) or picrotoxinin (20 microM). In contrast, bicuculline methiodide (10 microM) and picrotoxinin (10 microM) reversibly blocked the current evoked by GABA (20 microM); d-tubocurarine (100 microM) only slightly decreased the response to GABA (20 microM). The antagonists were effective over a wide range of holding potentials (-90 mV to +30 mV). The responses to a steady application of both GABA and glycine decayed in a few seconds when recorded under conditions of both symmetric and asymmetric chloride across the membrane. During this decay the current and conductance decreased simultaneously, reflecting receptor desensitization rather than a change in the driving force for chloride caused by agonist-induced ionic fluxes. The time-course of desensitization was usually described by a single exponential with time constants for GABA (20 microM) and glycine (100 microM) of 4.0 +/- 1.6 s and 4.4 +/- 1.9 s (mean +/- S.D.), respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

Nicotinic antagonists enhance process outgrowth by rat retinal ganglion cells in culture

Functional nicotinic cholinergic receptors are found on mammalian retinal ganglion cell neurons in culture. The neurotransmitter acetylcholine (ACh) can be detected in the medium of many of these retinal cultures, after release presumably from the choline acetyltransferase-positive amacrine cells. The postsynaptic effect of endogenous or applied ACh on the ganglion cells can be blocked with specific nicotinic antagonists. Here it is shown that within 24 hours of producing such a pharmacologic blockade, the retinal ganglion cells begin to sprout or regenerate neuronal processes. Thus, the growth-enhancing effect of nicotinic antagonists may be due to the removal of inhibition to growth by tonic levels of ACh present in the culture medium. Since there is a spontaneous leak of ACh in the intact retina, the effects of nicotinic cholinergic drugs on process outgrowth in culture may reflect a normal control mechanism for growth or regeneration of retinal ganglion cell processes that is exerted by ACh in vivo.

GABAA receptor blockers reverse the inhibitory effect of GABA on brain-specific [35S]TBPS binding

Thirteen substances previously reported to antagonize the electrophysiological effects of gamma-aminobutyric acid (GABA) on neurons also reversed the inhibitory effects of GABA on specific [35S]t-butylbicyclophosphorothionate ([35S]TBPS) binding to sites on rat brain membranes in vitro with a rank-order of potencies similar to those found in electrophysiological systems (R 5135 greater than pitrazepin greater than bicuculline greater than SR 95103 greater than securinine) confirming the earlier conclusion that GABA inhibits [35S]TBPS binding by acting allosterically on physiologically relevant GABAA receptors. Pitrazepin is the most potent of a series of mono N-aryl piperazines that block GABAA receptors. The new aryl amino pyridazine GABA derivative SR 95531 was about 3-fold more potent than bicuculline and 39-fold more potent than the structurally related SR 95103. Four known GABA antagonists have the same rank orders of potencies as convulsants and as reversers of GABA's inhibitory action on [35S]TBPS binding (bicuculline greater than securinine greater than theophylline greater than caffeine). Reversal of GABA-induced suppression of [35S]TBPS binding provides a simple method for further characterizing GABAA receptors linked to TBPS binding sites, and facilitates identification of convulsants and novel, perhaps selective, GABA antagonists.

Tubocurarine suppresses slow calcium-dependent after-hyperpolarization in guinea-pig inferior mesenteric ganglion cells

Intracellular recordings were made from neurones of the isolated guinea-pig inferior mesenteric ganglia. Single-spike potentials evoked by either depolarizing current pulses applied through the recording micro-electrode or stimulation of the hypogastric nerves were followed by an after-hyperpolarization (a.h.). The spike a.h. in 40% of the neurones, referred to herein as type I, had a relatively short duration (less than 50 ms) and exhibited a monophasic decay with a mean time constant (tau) of 11.4 ms. In the remaining cells (type II), the spike was followed by a long a.h. (greater than 100 ms) having a double-exponential decay; the fast and slow components of the a.h. are termed a.h.f and a.h.s, respectively, and they had mean tau values of 11.4 and 74 ms, respectively. A.h.f and a.h.s of type II neurones were reduced by membrane hyperpolarization and reversed their polarities between -80 and -90 mV. The reversal potentials shifted in a manner closely predicted by the Nernst equation as external K+ concentration was increased. Superfusion of low-Ca2+ high-Mg2+ solution to type II neurones reduced the a.h.f and a.h.s by 32 and 82%, respectively, indicating that a.h.s is largely Ca2+-dependent. Application of (+)-tubocurarine (10-100 microM) reversibly suppressed the a.h.s without affecting a.h.f in a concentration-dependent manner. Following a short train of action potentials evoked from type II neurones, the post-tetanic hyperpolarization (p.t.h.) was similarly depressed by (+)-tubocurarine in a dose-dependent manner. (+)-tubocurarine did not significantly change the amplitude of Ca2+-dependent spike potentials evoked in neurones bathed in Na+-free high-Ca2+ plus tetraethylammonium (5-10 mM) solution. The results indicate that (+)-tubocurarine selectively suppresses a.h.s, a slow Ca2+-dependent a.h., the consequence of which is a facilitation of repetitive discharges of the cells.

Diazotization and thiocyanate differentiate agonists from antagonists for the high- and low-affinity receptors of gamma-aminobutyric acid

The differentiation of high- and low-affinity postsynaptic gamma-aminobutyric acid (GABA) receptors was examined in a washed cortical membrane preparation of the rat. The selective elimination of the high- and low-affinity GABA sites by the chaotropic anion thiocyanate and diazotization by p-diazobenzenesulfonic acid (DSA), respectively, offered two model systems for the separate sites. The [3H]GABA displacing potencies of some GABA agonists [GABA, 4,5,6,7-tetrahydro- isoxazole [4,5c]pyridine-3-ol (THIP), and muscimol] and antagonists [bicuculline methiodide (BCM), 3-alpha-hydroxy-16-imino-5 beta-17-aza-androstan-11-one (R-5135), and d-tubocurarine] and their slope factors were examined in these model systems and in control membranes. The displacing potency of the agonists was increased in the DSA-pretreated membranes and decreased in the presence of thiocyanate. The displacing potency of the antagonists was shifted in an opposite manner. The chaotropic effect of thiocyanate was reversible and not additive with the inhibitory effect of diazotization on the specific binding of GABA. Inhibition of specific GABA binding by pyridoxal-5-phosphate (PLP) could not be protected by GABA antagonists (BCM and R-5135) but only by agonists. The results can be interpreted in the framework of a dual (agonist-antagonist) receptor model, postulating a hydrophobic accessory site at the low-affinity GABA receptor. The effect of thiocyanate on the GABA receptor may result in the exposure of the hydrophobic accessory sites.

A review of pharmacology and clinical use of piperine and its derivatives

Piperine and its derivatives are effective anticonvulsant drugs that antagonize convulsions induced by physical and chemical methods. Their major anticonvulsant activity as shown in animal tests lies in modification of the maximal electroshock seizure pattern. They also have sedative-hypnotic, tranquilizing, and muscle-relaxing actions and can intensify the depressive action of other depressants, when used in combination. Antiepilepsirine, one of the derivatives of piperine, is used as an antiepileptic drug in treating different types of epilepsy. It has been proved effective and is being widely used in China. The anticonvulsant action of 7446, 7448, and 7903 is more potent than that of antiepilepsirine. The chemical structure of piperine and its derivatives is different from that of prototype antiepileptic drugs, and, therefore, these may become a new group of antiepileptic drugs.

Classification of some GABA antagonists with regard to site of action and potency in slices of rat cuneate nucleus

Compounds reported to be GABA antagonists have been studied quantitatively on dorsal funiculus fibres and terminals in the rat cuneate nucleus in vitro. The potencies of the antagonists against the GABA analogue muscimol were determined as pA2 values. Distinction was made between three different sites of antagonist action within the GABA receptor and ionophore complex. Competitive antagonists, presumed to act at the GABA receptor, and their pA2 values were bicuculline (5.98), bicuculline methochloride (5.88), strychnine (5.29) and tubocurarine (4.95). Antagonists which were not competitive and acted predominantly at the 'picrotoxin site' on the ionophore were picrotoxin (6.19), picrotoxinin (6.03), isopropylbicyclophosphate (5.82) and leptazol (2.89). A third type of antagonism was shown by frusemide. Attention is drawn to the picrotoxin site and its likely importance in the regulation of GABA-mediated inhibition by drugs.

Chemoreceptors for serotonin (5-HT), acetylcholine (ACh), bradykinin (BK), histamine (H) and gamma-aminobutyric acid (GABA) on rabbit visceral afferent neurons

The somata of type 'C' neurons in rabbit nodose ganglion are endowed with receptor sites for 5-HT, BK, ACh, II and GABA. 5-HT and ACh application to type 'C' neurons in the nodose ganglion of rabbits produced a rapid depolarization associated with an increased membrane conductance, most likely to Na+ and K+. BK and H elicited slow depolarizations accompanied by a decreased membrane conductance probably to K+. GABA induced a rapid depolarization associated with an increased conductance to Cl-. In contrast, type 'A' neurons were insensitive to the four algesic agents but responded to GABA. d-Tubocurarine or picrotoxin at relatively low concentrations blocked ACh, 5-HT and GABA depolarizations without affecting membrane properties. Hexamethonium blocked ACh responses but not 5-HT responses. In addition, no desensitization occurred between the substances 5-HT, ACh or BK. The results suggest that the depolarizing effect of these agents on visceral neurons might be exerted via different receptors.

Receptors for gamma-aminobutyric acid (GABA) on Aplysia neurons

Aplysia neurons show 5 different types of response (three excitatory and two inhibitory) to iontophoretic application of gamma-aminobutyric acid (GABA). Four of these are associated with a membrane conductance increase, but one is associated with a conductance decrease. The most common response is a fast hyperpolarization which reverses at about--58 mV and is sensitive to manipulation of external Cl- concentration, and thus is due to a specific increase in Cl- conductance. There is an infrequent, slower hyperpolarizing response which does not reverse above about--80 mV and is insensitive to external Cl-. This response appears to result from a conductance increase to K+. Two types of depolarizing responses are associated with conductance increases. These responses differ in their latency, duration and sensitivity to curare. The more frequent is relatively rapid (peak at 1-2 sec) and is depressed by curare at high concentrations. In other neurons, GABA causes a slower response, peaking at 6-10 sec, which is not curare-sensitive. Usually for both types of response, the voltage and conductance changes are completely abolished by perfusion with Na+-free seawater, and the responses cannot be reversed with depolarization. In other neurons such as L11, the response can be reversed with depolarization, and appears to result from a conductance increase to both Na+ and Cl-. In neuron R15, GABA causes a slow depolarizing response (peak at about 9 sec) which is associated with a decreased membrane conductance, probably to K+. The classical GABA antagonists, picrotoxin and bicuculline, block Cl- responses but no others, while the fast Na+ and Cl- responses are depressed by curare. Strychnine does not affect any GABA response. The multiplicity of GABA responses, the specificity of their organization and the fact that only some neurons have receptors for GABA, argue that GABA may have a role as a neurotransmitter in Aplysia. Furthermore, the existence of several types of excitatory GABA response suggests that GABA may function both as an inhibitory and excitatory neurotransmitter.

Vasopressin release produced in anaesthetized cats by antagonists of gamma-aminobutyric acid and glycine

1 In cats anaesthetized with chloralose, the central excitatory substances, tubocurarine, picrotoxin, bicuculline, leptazol and strychnine, were applied to the exposed ventral surface of the brain stem through paired Perspex rings placed across the medulla and their effects on vasopressin release and arterial blood pressure were examined.2 The excitatory substances released large amounts of vasopressin when applied to an area 6-9 mm caudal to the trapezoid bodies. From this area vasopressin release was previously obtained with nicotine.3 With nicotine, the vasopressin release occurred almost instantaneously and tachyphylaxis developed rapidly. With the excitatory substances the release increased gradually and there was no tachyphylaxis. When these substances were applied for several minutes, the release reached its maximum a considerable time after their removal, except with leptazol when release diminished at once after removal.4 The excitatory substances had little or no effect on arterial blood pressure when applied to the vasopressin releasing area, but produced strong pressor responses when applied to a more rostrally situated area.5 It is concluded that the excitatory substances release vasopressin and raise arterial blood pressure because they are antagonists of gamma-aminobutyric acid and/or glycine and that numerous inhibitory neurones which release these amino-acids synapse at the ventral surface of the medulla. The physiological function of those which synapse at the vasopressin releasing area may be to act as a brake on vasopressin release, and of those which synapse at the more rostrally situated area to act as a brake on arterial blood pressure.

Effect of curare on responses to different putative neurotransmitters in Aplysia neurons

We have studied the effects of curare on responses resulting from iontophoretic application of several putative neurotransmitters onto Aplysia neurons. These neurons have specific receptors for acetylcholine (ACh), dopamine, octopamine, phenylethanolamine, histamine, gamma-aminobutyric acid (GABA), aspartic acid, and glutamic acid. Each of these substances may on different specific neurons elicit at least three types of response, caused by a fast depolarizing Na+, a fast hyperpolarizing Cl-, or a slow hyperpolarizing K+ conductance increase. All responses resulting from either Na+ or Cl- conductance increases, irrespective of which putative transmitter activated the response, were sensitive to curare. Most were totally blocked by less than or equal to 10-4 M curare. GABA responses were less sensitive and were often only depressed by 10-3 M curare. K+ conductance responses, irrespective of the transmitter, were not curare sensitive. These results are consistent with a model of receptor organization in which one neurotransmitter receptor may be associated with any of at least three ionophores, mediating conductance increase responses to Na+, Cl-, and K+, respectively. In Aplysia nervous tissue, curare appears not to be a specific antagonist for the nicotinic ACh receptor, but rather to be a specific blocking agent for a class of receptor-activated Na+ and Cl- responses.

Inhibitory effects of acetylcholine on neurones in the feline nucleus reticularis thalami

1. Short iontophoretic pulses of acetylcholine (ACh) inhibited almost every spontaneously active cell encountered in the nucleus reticularis thalami of cats anaesthetized with a mixture of halothane, nitrous oxide and oxygen. On 200 cells the mean current needed to eject an effective inhibitory dose of ACh was 67 +/- 2 nA. When the ACh-evoked inhibition was mimicked by gamma-aminobutyric acid (GABA) or glycine on the same cell, the current required to release ACh was found to be approximately twice as great as that required to release an equally effective dose of GABA or glycine. 2. ACh inhibitions developed with a latency which was very much shorter than that for ACh excitation in cells of the ventrobasal complex. The latency of the ACh-evoked inhibition was as rapid as the onset and offset of the excitation of the same cells glutamate and their inhibition by GABA or glycine. 3. The firing pattern of ACh-inhibited neurones in the nucleus reticularis was characterized by periods of prolonged, high frequency bursts, and their mean firing frequency was 22 Hz. Raster dot displays and interspike interval histograms showed that whereas ACh suppressed the spikes that occurred between bursts much more readily than those that occurred during bursts, all spikes were equally sensitive to the depressant action of GABA and glycine. Large doses of ACh provoked or exaggerated burst activity. 4. ACh-evoked inhibition was extremely sensitive to blockade by short iontophoretic applications of atropine, which had no effect on the inhibitions evoked on the same cell equipotent doses of GABA or glycine. The ACh-evoked inhibitions were also antagonized by dihydro-beta-erythroidine released with slightly larger currents. When tested on the same cell, small iontophoretic applications of picrotoxin and bicuculline methoiodide blocked the inhibition evoked by GABA but had no effect on that evoked by ACh. Iontophoretic strychnine only rarely affected the inhibition evoked by ACh, while readily blocking the inhibition evoked on the same cell by an equipotent dose of glycine. In two cats, intravenous strychnine (1-2 mg/kg) had no effect on the ACh-evoked inhibition, while greatly reducing the sensitivity of the cell under study to glycine. 5. Only four out of forty-eight ACh-inhibted cells tested were inhibited by iontophoretic applications of either guanosine or adenosine 3':5'-phosphate. 6. Cells of the nucleus reticularis have been shown to have an inhibitory action on the thalamic relay cells, which are excited by ACh. It is suggested that the presence of both ACh excited and inhibited cells in different nuclei of the thalamus could be of considerable functional significance in gating sensory transmission through the thalamus.

The action of acetylcholine antagonists on amino acid responses in the frog spinal cord in vitro

1 The isolated hemisected frog spinal cord has been used to study the action of acetylcholine antagonists on amino acid responses by means of sucrose gap recording. 2 Primary afferents and motoneurones were shown to contain few, if any, cholinoceptors, since acetylcholine and carbachol responses were essentially abolished when synaptic transmission was blocked with magnesium ions or when action potentials were blocked by tetrodotoxin. 3 Curare antagonized the gamma-aminobutyric acid (GABA) and beta-alanine depolarizations of primary afferents and hyperpolarizing action of these amino acids on motoneurones. Nicotine also antagonized beta-alanine depolarizations and to a small extent GABA depolarizations of primary afferents. These actions are similar to but weaker than those obtained previously with picrotoxin. 4 Atropine selectively antagonized beta-alanine depolarizations of primary afferents and blocked beta-alanine and glycine hyperpolarizations of motoneurones. GABA responses were entirely resistant to the action of atropine. These actions are similar to but 50 times weaker than those obtained previously with strychnine. 5 Dihydro-beta-erythroidine, tetraethylammonium, and gallamine were entirely ineffective in antagonizing amino acid responses. Since these agents are known to block the dorsal root potential elicited by ventral root stimulation but have no effect on the amino acid responses of primary afferents, it is evident that a cholinergic step is involved in this pathway.

Antagonism of inhibitory amino acid action by tubocurarine

A comparison has been made of the antagonism by microelectrophoretically administered (+)-tubocurarine, bicuculline methochloride and strychnine of the inhibition of spinal interneurones and Renshaw cells in the cat by glycine and gamma-aminobutyric acid. The results indicate that (+)-tubocurarine would be of little use in assessing which of these amino acids was the transmitter at central inhibitory synapses.

A comparative study of some convulsant substances as gamma-aminobutyric acid antagonists in the feline cerebral cortex

1. By the use of microiontophoretic techniques, quantitative estimates were obtained of the depressant effects of gamma-aminobutyric acid (GABA) on single feline cortical neurones.2. Picrotoxin, bicuculline, strychnine, (+)-tubocurarine, penicillin and leptazol were also applied microiontophoretically to single neurones. Sequential GABA applications were made before, during and after the microiontophoresis of these substances and any effects on the time course of the GABA depression were measured as an estimate of antagonism or potentiation of GABA.3. (+)-Tubocurarine was found to be a potent GABA antagonist. Picrotoxin and bicuculline were rather less potent and strychnine and penicillin only weakly active as GABA antagonists. Leptazol appeared to be inactive against GABA depressions.4. In addition, bicuculline and strychnine were found to be capable of potentiating the depressant action of GABA. This property was not shared by the other substances studied.5. All the substances studied produced changes in neuronal firing rate that did not correlate with GABA antagonism.6. In conclusion, several potent convulsants have been shown to be capable of GABA antagonism. It is not yet clear that this effect, rather than a direct effect on neuronal excitability, is the prime mechanism behind their convulsant properties.

Effect of penicillin on the increase in membrane conductance induced by gamma-aminobutyric acid at the crab neuromuscular junction

The effects of penicillin and picrotoxin on the increase in membrane conductance produced by gamma-aminobutyric acid (GABA) at the hermit crab neuromuscular junction were investigated. Penicillin failed to block the effects of GABA, while picrotoxin proved to be a potent antagonist.