Membrane Depolarization In Neurons Research Articles

Effects of ketamine on neuronal epileptiform responses in the cat neocortex

The effects of ketamine, an antagonist of NMDA receptors, on the neuronal epileptiform responses evoked by applications of strychnine, penicillin, or bicuculline to the suprasylvian gyrus were studied in cats. Ketamine either exerted no effect, or slightly decreased interictal high-amplitude depolarizing shifts of the membrane potential and depolarizing afterpotentials, which appeared spontaneously or were evoked by intracortical stimulation. Repetitive electrical stimulation of the epileptogenic cortical regions resulted in the appearance of autogenerated ictal activity lasting up to several tens of seconds; this activity was produced against the background of a depolarization of neuronal membranes. After ketamine injections, such stimulations evoked no ictal activity in the neurons, or the discharges became much shorter. The results of our study show that the NMDA-dependent postsynaptic components play a more important role in the development of neocortical ictal activity compared with the interictal activity.

Inhibitory effect of YM060 on 5-HT 3 receptor-mediated depolarization in colonic myenteric neurons of the guinea pig

We used conventional intracellular recording methods to examine the effects of YM060 [(-)-(R)-5-[(1-methyl-1H-indol-3-yl)carbonyl]-4,5,6,7- tetrahydro-1H-benzimidazole monohydrochloride), a novel 5-HT3 receptor antagonist, on 5-hydroxytryptamine (5-HT, serotonin)-evoked fast membrane depolarization in myenteric neurons of the guinea pig distal colon, and compared its potency to that of other 5-HT3 receptor antagonists. Microapplication of 5-HT from fine-tipped pipettes evoked both fast and slowly activating depolarizing responses in 78% and 40% of colonic myenteric neurons, respectively. The selective 5-HT3 receptor agonist 2-methyl-5-HT applied with short pressure pulses (100-300 ms) mimicked the fast but not the slow response. The 5-HT3 receptor antagonists YM060, granisetron and ondansetron suppressed the 5-HT-evoked fast response in 98% of colonic myenteric neurons in a concentration-dependent manner with pIC50 values of 8.62, 7.77 and 6.90, respectively. Methysergide and GR113808 did not affect the fast responses at concentrations sufficient to block 5-HT1, 5-HT2 and 5-HT4 receptors, respectively. YM060 did not affect the slowly activating response to 5-HT or any other electrophysiological parameter of the neurons including resting membrane potential, input resistance and the amplitude of action potentials evoked by injection of depolarizing current. Stimulus-evoked fast excitatory postsynaptic potentials were unchanged by YM060 at concentrations up to 10(-8) M, excluding any possible local anesthetic or anticholinergic effects of YM060. The results confirm that the fast component of the two depolarizing responses to 5-HT in colonic myenteric neurons is mediated by 5-HT3 receptors.(ABSTRACT TRUNCATED AT 250 WORDS)

Regulation of a potassium conductance in rat midbrain dopamine neurons by intracellular adenosine triphosphate (ATP) and the sulfonylureas tolbutamide and glibenclamide

The presence of adenosine triphosphate-regulated potassium channels (K-ATPs) in midbrain dopamine neurons is currently in dispute. This was investigated using whole-cell patch-clamp recordings from dopamine neurons in slices of midbrain from 9-12-d-old rats. Intracellular dialysis with Mg2+ ATP-free solutions resulted in a membrane hyperpolarization (14 +/- 6 mV), or outward current (102 +/- 27 pA) in voltage clamp, which developed over 14 +/- 1.6 min. These hyperpolarizations and outward currents were reversed by the K-ATP-blocking sulfonylureas tolbutamide (100 microM) and glibenclamide (3 microM). This sulfonylurea-sensitive outward current was associated with an increase in a nonrectifying (between -50 and -130 mV) conductance of approximately 2 nS, with a reversal potential of -100 mV (in 2.5 mM extracellular potassium), consistent with a potassium conductance increase. When the dialyzate contained Mg2+ATP (2 mM), no slowly developing hyperpolarization or outward current occurred, and tolbutamide (200 microM) and glibenclamide (10 microM) did not affect membrane potential or current. Additionally, the "potassium channel activators" (KCAs) lemakalim (200 microM) and pinacidil (50 microM) were also without effect on the membrane potential or holding current in these cells. The hyperpolarizations and outward currents caused by baclofen and quinpirole, agonists at GABAB and D2 receptors, respectively, were neither blocked by sulfonylureas nor occluded by the current resulting from depletion of intracellular ATP. Thus, these K-ATPs appear independent of the potassium channels coupled to GABAB and D2 receptors in these cells. This ATP-regulated potassium conductance may constitute a protective mechanism during anoxia or hypoglycemia, by restricting membrane depolarization of dopamine neurons when intracellular ATP levels fall.

On the mechanisms underlying hypoxia-induced membrane depolarization in striatal neurons.

Clinical and experimental evidence has shown that the striatal neurons are particularly vulnerable to hypoxia and ischaemia. An excessive excitatory action of glutamate, released by the corticostriatal terminals, has been implicated in this peculiar vulnerability of striatal neurons. We have studied the effects of hypoxia on the membrane properties of striatal neurons intracellularly recorded from a corticostriatal slice preparation. Brief (2-10 min) periods of hypoxia produced reversible membrane depolarizations. During the initial phase of the hypoxia-induced depolarization the frequency of action potential discharge was transiently increased; 2-3 min after the onset of hypoxia the firing activity was fully abolished. Brief periods of hypoxia also caused a reversible reduction of the amplitude of the excitatory postsynaptic potentials (EPSPs) evoked by cortical stimulation. Longer period of hypoxia (12-20 min) produced irreversible membrane depolarizations. In voltage-clamp experiments hypoxia caused an inward current coupled with an increased membrane conductance. Tetrodotoxin (TTX) or low calcium (Ca2+)-high magnesium containing solutions blocked synaptic transmission, but they did not reduce the hypoxia-induced electrical changes. Antagonists of excitatory amino acid receptors failed to affect the electrical effects caused by oxygen deprivation. Hypoxia-induced inward currents were reduced either by the potassium (K+) channel blockers, barium and tetraethyl ammonium (TEA) cations, or by lowering external sodium (Na+) concentration. Blockade of ATP-dependent Na(+)-K+ pump by both ouabain and strophanthidin enhanced hypoxia-induced membrane depolarization/inward current. Our findings indicate that the release of excitatory amino acids does not seem to be required for the acute hypoxia-induced electrical changes in striatal neurons. Moreover, TTX-resistant Na+ influx and K+ currents seem to play an important role in the generation of hypoxia-induced electrical changes. These data also suggest that the selective vulnerability of striatal neurons to oxygen deprivation may be caused by their peculiar sensitivity to energy metabolism failure.

Membrane depolarization and calcium influx stimulate MEK and MAP kinase via activation of Ras

A pathway by which calcium influx through voltage-sensitive calcium channels leads to mitogen-activated protein kinase (MAPK) activation has been characterized. In PC12 cells, membrane depolarization leading to calcium influx through L-type calcium channels activates the dual specificity MAPK kinase MEK1, which phosphorylates and activates MAPK. Calcium influx leads within 30 s to activation of the small guanine nucleotide-binding protein Ras. Moreover, activation of MAPK in response to calcium influx is inhibited by the dominant negative mutant RasAsn17, indicating that Ras activity is required for calcium signaling to MAPK. Ras is also activated by release of calcium from intracellular stores and by membrane depolarization of primary cortical neurons. The pleiotropic regulatory potential of both Ras and the MAPK pathway suggests that they may be central mediators of calcium signaling in the nervous system.

Depressant insect selective neurotoxins from scorpion venom: Chemistry, action, and gene cloning

The present study examines the similarity in the symptoms and binding properties between the depressant and excitatory insect-selective neurotoxins, derived from scorpion venom. A comparison of their primary structures and neuromuscular effects is presented. A new depressant toxin (LqhIT2) was purified from the venom of the scorpion Leiurus quinquestriatus hebraeus. The effects of this toxin on a prepupal housefly neuromuscular preparation mimic its effects on the intact insect, i.e, a brief period of repetitive bursts of regular junction potentials (JPs) is followed by reduced amplitude JPs ending with a block of the neuromuscular transmission. "Loose" patch clamp recordings indicate that the repetitive activity has a presynaptic origin (the motor nerve) and resembles the effect of the excitatory toxin AaIT. The final synaptic block is supposed to be the end result of neuronal membrane depolarization. Such an effect is not caused by an excitatory toxin, which induces long "trains" of repetitive firing. The amino acid sequences of three depressant toxins were determined by automatic Edman degradation indicating a high degree of sequence homology. This conservation differs from those of other groups of scorpion toxins. The opposing pharmacological effects of depressant toxins are discussed in light of the above neuromuscular effects and sequence analysis. A genetic approach in the study of the structure-function relationships of the depressant toxins was initiated by isolating cDNA clones encoding the LqhIT2 and BjIT2 toxins. Their sequence analysis revealed the precursor form of these toxins: A 21 amino acid residue signal peptide followed by a 61 amino acid region of the mature toxin, and three additional amino acids at the carboxy terminus.

Effects of phenobarbital on leukocyte activation: membrane potential, actin polymerization, chemotaxis, respiratory burst, cytokine production, and lymphocyte proliferation.

Leukocyte activation is known to involve cell membrane potential changes. Phenobarbital, an anesthetic and anticonvulsant that can inhibit neuronal membrane depolarization, may also affect leukocyte activation. Measuring membrane potential, actin polymerization, chemotaxis, superoxide production, lymphocyte proliferation, intracellular calcium concentration, and cytokine production, we found that phenobarbital at a concentration of 15-30 micrograms/ml, which is considered a therapeutic serum level for controlling seizures, did not affect polymorphonuclear neutrophil (PMN) activation. At levels higher than 100 micrograms/ml, phenobarbital significantly suppressed formylmethionyl-leucyl-phenylalanine (fMLP)-induced chemotaxis. Concentrations greater than 300 micrograms/ml also inhibited phorbol myristate acetate-stimulated membrane potential change. In contrast, 30 micrograms/ml phenobarbital significantly inhibited lymphocyte proliferation stimulated by phytohemagglutinin (PHA) and pokeweed mitogen. This concentration of phenobarbital also suppressed the increase of intracellular free calcium induced by PHA. However, only a higher concentration of phenobarbital (300 micrograms/ml) was able to inhibit PHA-induced interleukin-2 (IL-2) production and suppress the proliferation of PHA-induced IL-2 receptor-bearing lymphocytes. These results suggest that concentrations of phenobarbital associated with anticonvulsive levels do not affect PMN activation but suppress lymphocyte activation, possibly by affecting intracellular signal transduction.

Functional duality and structural uniqueness of the depressant insect-selective neurotoxins

Depressant insect-selective neurotoxins derived from scorpion venoms (a) induce in blowfly larvae a short, transient phase of contraction similar to that induced by excitatory neurotoxins followed by a prolonged flaccid paralysis and (b) displace excitatory toxins from their binding sites on insect neuronal membranes. The present study was undertaken in order to examine the basis of these similarities by comparing the primary structures and neuromuscular effects of depressant and excitatory toxins. A new depressant toxin (LqhIT2) was purified from the venom of the Israeli yellow scorpion. The effects of this toxin on a prepupal housefly neuromuscular preparation mimic the effects on the intact animal; i.e., a brief period of repetitive bursts of junction potentials is followed by suppression of their amplitude and finally by a block of neuromuscular transmission. Loose patch clamp recordings indicate that the repetitive activity has a presynaptic origin in the motor nerve and closely resembles the effect of the excitatory toxin AaIT. The final synaptic block is attributed to neuronal membrane depolarization, which results in an increase in spontaneous transmitter release; this effect is not induced by excitatory toxin. The amino acid sequences of three depressant toxins were determined by automatic Edman degradation. The depressant toxins comprise a well-defined family of polypeptides with a high degree of sequence conservation. This group differs considerably in primary structure from the excitatory toxin, with which it shares identical or related binding sites, and from the two groups of scorpion toxins that affect sodium conductance in mammals. The two opposing pharmacological effects of depressant toxins are discussed in light of the above data.

Mast cells in the guinea pig superior cervical ganglion: a functional and histological assessment

We have previously found that antigenic stimulation of mast cells in the guinea pig superior cervical ganglion leads to membrane depolarization of principal neurons and a long-term increase in the efficacy of ganglionic transmission. In this study experiments were conducted to discern the histological, immunological and pharmacological characteristics of the mast cells within the superior cervical ganglion. Mast cells within the superior cervical ganglion could be stained with toluidine blue or berberine sulfate, the latter indicating that heparin-like molecules were present in the granules. Stainable mast cells were distributed throughout the ganglion with no gross evidence of regional localization. The number of mast cells stained with toluidine blue was reduced significantly (P less than 0.01) in contralateral ganglia that had been exposed to the sensitizing antigen (ovalbumin), indicating antigen-induced degranulation. The superior cervical ganglion contained 208 +/- 6 picomole of histamine (mean +/- SEM, n = 66). Ovalbumin evoked the release of histamine from the superior cervical ganglion in a concentration-dependent fashion. At maximally effective concentrations, ovalbumin released 33 +/- 2% of the total histamine stores (mean +/- SEM, n = 61). Similar values were obtained with antigen-challenged stellate ganglia. A temperature of 37 degrees C and an extracellular calcium concentration of 1 mM was required to elicit optimal antigen-induced responses. In addition to releasing histamine, antigenic stimulation of the ganglion resulted in a 3- to 5-fold increase in the synthesis and release of arachidonic acid metabolites including peptidoleukotriene, thromboxane B2, prostaglandins (PG) E2, F2 alpha, D2, the PGD2 metabolite 9 alpha 11 beta-PGF2, and the prostacyclin metabolite 6-keto PGF1 alpha. Various putative mast cell secretagogues were examined for their ability to activate the superior cervical ganglion mast cell, as indicated by evoked histamine release. In contrast to rat peritoneal mast cells, high concentrations of substance P, compound 48/80, and nerve growth factor failed to stimulate the ganglion mast cells. Preganglionic nerve stimulation, electrical field stimulation of axons and cell bodies, or depolarizing concentrations of potassium chloride also failed to activate the superior cervical ganglion mast cells. These results suggest that substances released by membrane depolarization do not influence the function of the resident mast cells. The results demonstrate that the mast cells within sympathetic ganglia can be actively sensitized to respond to specific antigen. These mast cells are similar to lung parenchymal mast cells with respect to histological, immunological and pharmacological characteristics...

Hyperpolarization of myenteric neurons by opioids does not involve cyclic adenosine-3′,5′-monophosphate

To investigate the role of cyclic adenosine-3'5'-monophosphate on the inhibitory actions of opioids in guinea-pig ileum, we made intracellular recordings from the two electrophysiologically defined classes of neurons (S and AH) in the myenteric plexus. The selective opioid mu agonist (D-Ala2,N-Me-Phe4,Gly5-ol)-enkephalin caused a membrane hyperpolarization in 34 out of 67 S neurons but did not affect the membrane potential of AH neurons. The mean amplitude (+/- S.E.M.) of the hyperpolarization was 8.2 +/- 0.8 mV. Forskolin, which activates adenylate cyclase and increases intracellular cyclic adenosine-3',5'-monophosphate levels, caused a membrane depolarization in AH neurons (9.4 +/- 1.9 mV) but did not alter the resting membrane potential of S neurons. Similarly, neither the phosphodiesterase inhibitor, isobutylmethylxanthine, nor the membrane permeable analogue of cyclic adenosine-3',5'-monophosphate, dibutyryl cyclic adenosine-3'-5'-monophosphate, altered the resting membrane properties of S neurons. Furthermore, none of these agents affected significantly the amplitude of the hyperpolarization of S neurons by (D-Ala2,N-Me-Phe4,Gly5-ol)-enkephalin. The experiments indicate that changes in intracellular cyclic adenosine-3',5'-monophosphate are not important in the processes that link occupation of mu receptors to the opening of potassium channels on myenteric neurons.

Neuronal membrane depolarization and the control of cholinergic muscarinic receptors: selective effect on different neuronal cell types.

1. The possibility that a long-lasting neuronal activation regulates the expression of muscarinic cholinergic receptors was studied with three cultured neuronal cell lines. 2. Continuous depolarization of a subclone of the neuroblastoma-glioma NG108-15 hybrid cells with potassium chloride increased by 45-75% the number of cholinergic muscarinic receptors, monitored with 3H-QNB, whereas a short incubation with KCl for 10 min or 6 hr had no effect. 3. The calcium channel blocker verapamil increased the effect of KCl. 4. Two cell lines, named SC9 and WC5, that originate from the rat brain, also bind 3H-QNB. They were therefore used to test whether the effect of chronic depolarization is universal. Depolarized SC9 and WC5 cells, in the presence or absence of verapamil, did not show an increased 3H-QNB binding. 5. Muscarinic receptors of both SC9 and WC5 cells have a higher affinity to pirenzepine than the M-3 receptor subtype of the neuroblastoma-glioma cells, suggesting therefore that the two rat brain cell lines possess M-1 or M-2 receptors. 6. The physiological significance of this differential role of depolarization on the expression of different muscarinic receptors is discussed in the context of their postreceptor second messengers.

Direct excitatory action of vasopressin in the lateral septum of the rat brain

The electrophysiological action of arginine vasopressin on neurones in the lateral septum of the rat brain was studied using extracellular recordings and the in vitro brain slice technique. Of 177 neurones tested in the presence of vasopressin at 1-1000 nM, 77 (about 44%) responded by a reversible increase in firing rate, 12 (about 7%) were inhibited and the remaining were not affected. The lowest peptide concentration effective in exciting septal neurones ranged between 1 and 50 nM, and the magnitude of the excitatory effect was concentration dependent. At high vasopressin concentrations, the peptide-induced excitation was often followed by a transient pause in firing; this was probably due to action potential inactivation, brought about by the vasopressin-induced neuronal membrane depolarization. The excitatory effect of vasopressin was postsynaptic, since it was not abolished following synaptic blockade in a low calcium-high magnesium perifusion solution. A comparison of the effects of vasopressin and oxytocin suggested that most of the septal vasopressin-sensitive neurones are endowed with vasopressin receptors, whereas a minority of them bear oxytocin receptors.

Is there feedback regulation of neurotransmitter release by autoreceptors?

Neurotransmitter release does not seem to be regulated by neuronal receptors mediating feedback and the mechanism of action of presynaptically active agents is still uncertain. In a recent set of papers [27, 82], experiments were described in which major modifications were made to the amount of neurotransmitter released per impulse, with all other parameters of field stimulation, such as pulse number, voltage and frequency, fully controlled. These studies done with a number of sympathetically innervated tissues give some insight into an antagonist action presynaptically which is independent of the ambient concentration of extracellular transmitter. It appears to involve, instead, the gating mechanisms which control neuronal membrane depolarization and repolarization. It was found that the effects of yohimbine and also of phenoxybenzamine on stimulation-induced efflux appeared to be essentially "all or none". That is, the absolute total release of tritiated transmitter with 100 pulses was elevated to roughly the same dpm value by the presynaptic antagonist at each of the pulse durations between 50 and 1000 microsec, in a variety of test tissues. The declining percentage effect of the antagonist on tritium efflux, as the pulse duration was enlarged between 50 and 1000 microsec, referred to earlier (Fig. 3), was due to rising values for transmitter release in the controls not matched by proportionally similar increases in the antagonist-treated tissues. Values for the amount of transmitter released during stimulation in the presence of yohimbine, at pulse lengths between 50 and 1000 microsec, were all in the range of values achieved in the absence of yohimbine with long pulse lengths (1000-2000 microsec). In other words, prolongation of the pulse duration from 50 to 1000 microsec and the exposure of tissues to a presynaptic antagonist, such as yohimbine or phenoxybenzamine, may involve a common mechanism, and the effects of these two procedures are not additive. In fact, with much prolonged pulse durations (2000-5000 microsec), the presynaptic antagonists are virtually ineffective. It is known that the release of transmitter from sympathetic nerves is directly related to the duration of the action potential. If it is prolonged, the calcium channels stay open longer leading to greater entry of calcium and to an increased release of transmitter [45, 46]. Yohimbine and phenoxybenzamine may prolong the duration of depolarization by indirect modification of the calcium gating mechanism.(ABSTRACT TRUNCATED AT 400 WORDS)

Neurokinin A depolarizes neurons of the guinea pig inferior mesenteric ganglia

Neurokinin A (NKA) applied either by superfusion (0.1-10 microM) or by pressure ejection evoked a slow membrane depolarization in neurons of the inferior mesenteric ganglia in vitro. The NKA-induced depolarization which was not significantly affected by reducing the Ca concentration or by tetrodotoxin was associated in most cases by a small-to-moderate increase in membrane resistance; however, conditioning hyperpolarization increased rather than decreased the response. The depolarization elicited by NKA was eliminated in the presence of substance P (SP) and the depolarization by SP in the presence of NKA. The results suggest that the actions of NKA on prevertebral neurons are similar to that of SP and that these two peptides may act on the same receptors or share similar ionic channels.

Effects of lithium on electrical activity and potassium ion distribution in the vertebrate central nervous system

Three different regions of the vertebrate central nervous system maintained in vitro (frog spinal cord, guinea pig olfactory cortex and hippocampus) have been used to investigate how Li+ influences membrane potential, membrane resistance, action potentials, synaptic potentials and the transmembrane K+-distribution of neurons and glial cells. In view of the therapeutic action of Li+ in manic-depressive disease, a special effort was made to determine the threshold concentration for the actions of Li+ on the parameters described above. It was observed that Li+ induced a membrane depolarization of both neurons and glial cells, a decrease of action potential amplitudes, a facilitation of monosynaptic excitatory postsynaptic potentials and a depression of polysynaptic reflexes. The membrane resistance of neurons was not altered. Li+ also induced an elevation of the free extracellular potassium concentration and a decrease of the free intracellular potassium concentration. Furthermore, in the presence of Li+ a slowing of the recovery of the membrane potential of neurons and glial cells, and of the extracellular potassium concentration after repetitive synaptic stimulation was observed. The threshold concentrations for the effects of Li+ were below 5 mmol/l in the frog spinal cord and below 2 mmol/l in the guinea pig olfactory cortex and hippocampus. The basic mechanism underlying the action of Li+ may be an interaction with the transport-function of the Na+/K+ pump.

Immunoreactive beta-endorphin in the hypothalamus of female rats: changes in content and release during prepubertal development.

Female Wistar rats of different ages (1-45 days) were used. Extracts were made of the mediobasal hypothalamus (MBH) and beta-endorphin immunoreactivity (beta-ENDi) was quantitated by radioimmunoassay. Low but significant amounts of beta-ENDi (6.5 ng/MBH) were present on the first postnatal day. Hypothalamic beta-ENDi content did not change during the first week but decreased during the second week to a minimum (4.5 ng/MBH) on day 14. Thereafter, beta-ENDi increased rapidly to 13 ng/MBH on day 28 and remained at this level. Gel filtration showed that beta-ENDi substances with chromatographic characteristics identical to those of beta-END and beta-LPH were present in MBHs of 14-, 20- and 45-day-old rats. A beta-ENDi substance, possibly representing beta-END1-27, was nearly absent on day 14, but represented a major component of the MBH of the 45-day-old rat. In vitro incubation of MBH resulted in spontaneous release of beta-ENDi. Depolarization of neuronal membranes by incubation in medium containing 45 mMK+ stimulated beta-ENDi release. Both the spontaneous and K+-stimulated release of beta-ENDi were low on day 10 but reached postpubertal levels on day 20. These observations lead us to propose that the beta-ENDi-containing neurons in the hypothalamus of developing female rats rapidly mature between 14 and 20 days after birth. This may be causally related to the rapid decrease in circulating FSH levels that occurs during this period.

Relationship between membrane depolarization, calcium influx and norepinephrine release in sympathetic neurons maintained in culture.

Relationship between membrane depolarization, calcium influx and norepinephrine release in sympathetic neurons maintained in culture.

Substance P: A Putative Sensory Transmitter in Mammalian Autonomic Ganglia

Repetitive presynaptic stimulation elicited slow membrane depolarization in neurons of inferior mesenteric ganglia from guinea pigs. This response was not blocked by cholinergic antagonists but was specifically and reversibly inhibited by a substance P analog, (D-Pro2, D-Phe7, D-Trp9)-substance P, which also depressed the depolarization induced by exogenously applied substance P. The atropine-sensitive slow excitatory and slow inhibitory postsynaptic potentials evoked in neurons of rabbit superior cervical ganglia were not affected by the substance P analog. These and previous results provide strong support for the hypothesis that substance P or a closely related peptide is the transmitter mediating the slow depolarization. The latter may represent a sensory input from the gastrointestinal tract to neurons of the prevertebral ganglia.

Extracellular recording of neuronal activity of the cat heart ganglia

An analysis of results of extracellular recording of neuronal activity of the cat heart ganglia showed that neurons of the intracardiac ganglia, in contrast to the neurons of other visceral ganglia, were characterized by the absence of spontaneous electrical activity. Variations in the duration and frequency of mechanically induced spike discharge are indicative of a different degree of neuronal membrane depolarization and its stability in time after mechanical action of the tip of the recording microelectrode on the cell. The evoked electrical activity was not dependent on the rhythm of local contractions of the myocardium. Some evidence of interneuronal interaction at the ganglion level under the conditions of complete isolation of the right auricle has been presented.

Membrane depolarization and prolongation of calcium-dependent action potentials of mouse neurons in cell culture by two convulsants: Bicuculline and penicillin

The convulsant compounds bicuculline (BICUC) and penicillin (PCN) are antagonists of GABA-mediated synaptic inhibition. In addition, we have shown that BICUC and PCN produced membrane depolarization of mouse spinal cord neurons in primary dissociated cell culture by blocking a potassium conductance, a non-synaptic direct effect. Both compounds also prolonged calcium-dependent action potentials of mouse dorsal root ganglion and spinal cord neurons in cell culture. Thus, BICUC and PCN had both synaptic and non-synaptic actions. The possibility that both synaptic and non-synaptic actions of BICUC and PCN are involved in their convulsant mechanism of action is discussed.