Cholinergic excitation of mammalian hippocampal pyramidal cells

Intracellular theta-rhythm generation in identified hippocampal pyramids

The hippocampal EEG and the transmembrane potential of CA1-CA3 hippocampal pyramids were recorded in curarized and urethanized rats. Pyramids were identified by antidromic driving and intracellular staining with Lucifer yellow. During theta-rhythm most pyramids showed 10-20 mV sustained depolarizations and potential oscillations either consisting of 5-10 mV smooth sine-like waves or slow spikes of up to 60 mV. Fast Na+ and slow, probably Ca2+-mediated, spikes were triggered by depolarizing pulses or spontaneously. Depolarizations greater than 15 mV triggered rhythmic slow spikes at theta-frequency, but if less than 15 mV, slow spikes were irregular and at lower rates. With depolarizations of less than 10 mV, no slow spikes were triggered. Sine-like intracellular theta-wave amplitudes increased with hyper- and decreased with depolarizing pulses, showing the behavior of rhythmic EPSPs. Periodic fast spike bursts were theta-correlated. Cells with intracellular theta could either fire periodic fast spike bursts or at random, but always at a preferred phase of the theta-wave. Slow spikes were generated above a potential threshold by a slow depolarization and driven by periodic EPSPs. Intracellular theta is the reflection of EPSPs and of slow spikes; the oscillatory phenomena are not exclusively generated, as previously hypothesized, by network properties which may, however, contribute as tuning and modulatory elements. The determining events in intracellular theta-generation are the intrinsic biophysical characteristics of the pyramidal neuron membrane.

Hippocampus of the seizure-sensitive gerbil is a specific site for anatomical changes in the GABAergic system

The brains of seizure-sensitive (SS) and seizure-resistant (SR) gerbils were studied with an immunocytochemical method to localize glutamic acid decarboxylase (GAD) to determine whether a defect existed in the inhibitory GABAergic system similar to that which has been reported in animal models of focal epilepsy in which GABAergic cell bodies and terminals are decreased in number. A major difference between the two strains of gerbils was found in the number of GABAergic neurons in the hippocampal formation. Specifically, a paradoxical increase occurred in the number of glutamate decarboxylase GAD-immunoreactive neurons: there were approximately 65% more GABAergic cells within the dentate gyrus and the CA3 region of the hippocampus in the SS gerbils. Furthermore, the density of GAD-immunoreactive puncta, the light microscopic correlates of synaptic boutons, was greater in the SS animals. Other histological methods were used to determine if the difference between SS and SR gerbils was specific for the GABAergic system. Nissl-stained preparations showed that the number of granule cells in the dentate gyrus was 20% greater in SS gerbils than in SR gerbils. An examination of some hippocampal afferents, efferents, and intrinsic connections with acetylcholinesterase histochemistry and the Timm's stain for heavy metals demonstrated no differences between the two strains. In addition, Golgi-stained preparations of the dentate gyrus indicated that the morphology of basket cells did not differ between the two strains nor between the gerbil and the rat. Several brain regions in addition to the hippocampus were studied to determine whether or not the increased number of GAD-immunoreactive neurons was specific for the hippocampal formation. These regions included the substantia nigra, motor cortex, and nucleus reticularis thalami and were selected because they contain large populations of GABAergic neurons and have been implicated in seizure activity. No differences between the two strains were detected in any of these regions. Therefore, a major morphological difference between the brains of SS and SR gerbils exists in the hippocampal formation of SS gerbils in which an increase occurs in the number of GABAergic neurons and granule cells. If these additional inhibitory neurons act mainly to inhibit other inhibitory neurons, the net effect would be increased disinhibition of the principal excitatory neurons of the hippocampal formation. This could lead to seizure activity within the hippocampal formation and at distant sites through multiple synaptic connections.

Cholinergic innervation of hippocampal GAD- and somatostatin-immunoreactive commissural neurons

This study describes the cholinergic innervation of chemically defined nonpyramidal neurons in the hilar region of the rat hippocampus. Cholinergic terminals were identified by immunocytochemistry employing a monoclonal antibody against choline acetyltransferase (ChAT), the acetylcholine-synthesizing enzyme, and the avidin-biotin-peroxidase (ABC) technique. Nonpyramidal neurons in the hilar region were characterized by immunostaining with antibodies against glutamate decarboxylase (GAD), the gamma aminobutyric acid (GABA)-synthesizing enzyme, and somatostatin (SS). The immunoreactivity to these antibodies was detected by using biotinylated secondary antibodies and avidinated ferritin as an electron-dense marker. This electron microscopic double immunostaining procedure enabled us to demonstrate that immunoperoxidase-labeled ChAT-immunoreactive terminals established symmetric synaptic contacts on the ferritin-labeled GAD- and SS-immunoreactive hilar cells. In additional experiments at least some of the GAD- and SS-immunoreactive hilar neurons were further characterized as commissural neurons by retrograde filling with horseradish peroxidase (HRP) following an injection of the tracer into the contralateral hilus. From these triple labeling experiments, we concluded that at least some GABAergic and somatostatin-containing neurons in the hilar region, which are postsynaptic to cholinergic terminals, project to the contralateral hippocampus. Together with previous studies on the cholinergic innervation of the hippocampus and fascia dentata, our present results thus demonstrate that different types of hippocampal cells, including GABAergic and peptidergic commissural neurons in the hilar region, receive a cholinergic input.

Muscarine affects calcium-currents in rat hippocampal pyramidal cells in vitro

Ca2+-currents were recorded from single CA3 pyramidal cells in hippocampal slice cultures, voltage-clamped through a single Cs+ - or K+-filled microelectrode and perfused with Hanks' balanced salt solution containing 1 microM tetrodotoxin and 10 mM tetraethylammonium. The Ca2+-current was reversibly reduced by bath-perfused muscarine (10-100 microM). This effect was inhibited by pirenzepine (10 microM) or atropine (1 microM). In K+-filled cells, inhibition was preceded by a phase of inward current enhancement; this was considered to be secondary to rapid outward current inhibition induced it by muscarine since it was reduced when outward currents were previously inhibited with Ba2+. In partially clamped or unclamped cells inhibition of Ca2+-current leads to a shortening of the Ca2+-spike plateau.

Diurnal rhythms in the responsiveness of hippocampal pyramidal neurons to serotonin, norepinephrine, gamma-aminobutyric acid and acetylcholine

Radioligand binding studies have revealed the existence of endogenous circadian rhythms in the number of several receptors in the rat brain. The present microiontophoretic study was undertaken to assess diurnal rhythms in the responsiveness of rat hippocampal pyramidal neurons to serotonin (5-HT), norepinephrine (NE), gamma-aminobutyric acid (GABA), and acetylcholine (ACh). Between December and April, there was a significant diurnal variation in the responsiveness of hippocampal pyramidal neurons to 5-HT and ACh. Between May and August, the responsiveness to NE and ACh showed a diurnal variation. There was no diurnal variation in the responsiveness to GABA in either period of the year. Short-term exposure to constant light or darkness produced a phase-shift of the serotoninergic and cholinergic rhythms, suggesting their endogenous nature and their synchronization to clock-time by the light-dark cycle. The diurnal rhythms in responsiveness to 5-HT and NE underwent phase-shifts from the December-April to the May-August period in rats entrained to 12:12 light-dark cycle, suggesting the existence of seasonal modulation of these rhythms. These circadian rhythms in the postsynaptic responsiveness of hippocampal pyramidal cells and their seasonal fluctuation may be related to the diurnal variation of mood seen in major depression as well as to the seasonal incidence of this illness.

Absence of modification in GABA and benzodiazepine binding and in choline acetyltransferase activity in brain areas of the epileptic mutant mouse tottering

1. In the tottering mutant mouse, which suffers from epilepsy and cerebellar ataxia, we examined whether possible changes in GABA, benzodiazepine receptors and choline acetyltransferase (ChAT) activity are implicated in the pathophysiology of these animals. 2. No alteration in GABAA and GABAB binding could be detected in cerebellar membranes of epileptic mice as compared to normal mice. 3. Benzodiazepine receptor density and affinity showed no statistical difference in cerebellar membranes of epileptic and normal mice. 4. The activity of ChAT determined in the cortices of epileptic and normal mice did not differ significantly between the two groups.

Muscarinic slow excitation and muscarinic inhibition of synaptic transmission in the rat neostriatum

Intracellular recording from neurones in rat neostriatal slices was used to compare the muscarinic effects of endogenous acetylcholine (ACh) released from cholinergic neostriatal synapses with the action of exogenously applied muscarinic agonists. Repetitive electrical stimulation in the neostriatum evoked a series of fast excitatory post-synaptic potentials (e.p.s.p.s) followed by a short, variable period of input resistance decrease. In the presence of the acetylcholinesterase (AChE) inhibitor, physostigmine, these potentials were followed by a slow e.p.s.p. which lasted about 60 s. Higher stimulus intensities were needed to elicit the slow e.p.s.p. than the fast e.p.s.p. The slow e.p.s.p. could not be observed after a single stimulus. Its amplitude was graded and increased with stimulus strength. The slow e.p.s.p. was blocked by the muscarinic antagonist atropine (10 microM) and by Ba2+ (100 microM). Input resistance increased during the slow e.p.s.p. Depolarization of the cell increased the size of the slow e.p.s.p. and hyperpolarization decreased it. Simultaneously, resting input resistance increased with membrane depolarization and decreased with membrane hyperpolarization. Repetitive intrastriatal stimulation was followed by a hyperpolarization instead of the depolarization at membrane potentials negative to -75 mV. Input resistance increased during this hyperpolarization as it did during the slow e.p.s.p. The slow e.p.s.p. persisted at membrane potentials of -70 to -80 mV if K+ concentration in the saline was reduced from 5 to 2 mM. In 10 mM-K+, the repetitive stimulation was followed by a hyperpolarization even at membrane potentials as low as -60 to -50 mV. Bath perfusion of high concentrations (100 microM) of muscarine or carbachol induced a sustained increase in the input resistance. The muscarinic agonists also reduced the amplitude of intrastriatally evoked fast e.p.s.p.s; however, this effect was transient and compensated by the increase in input resistance. The effects of the muscarinic agonists on input resistance and e.p.s.p. amplitude were antagonized by atropine (10 microM). Sustained decreases of e.p.s.p. amplitude were induced by the bath application of low doses (0.5-10 microM) of muscarine or carbachol. Input resistance was not altered. Atropine (1-10 microM) antagonized this effect. A sustained reduction of fast e.p.s.p. amplitude resulted also from inhibition of AChE by application of physostigmine (1-100 microM). Input resistance and neuronal excitability were not affected by AChE blockade.(ABSTRACT TRUNCATED AT 400 WORDS)

Intracellular injection of cGMP-dependent protein kinase results in increased input resistance in neurons of the mammalian motor cortex

Purified, cyclic GMP-dependent protein kinase (cGPK) was pressure-injected into neurons of the precruciate cortex of awake cats. Input resistances increased within seconds after injection and remained elevated for 2 min or longer. The increases were larger when cGPK was injected in a mixture with 10 microM cGMP than when injected alone. Injections of heat-inactivated cGPK, with or without 10 microM cGMP, failed to produce increases in input resistance. The present results indicate that injection of activated cGPK into neurons of the mammalian motor cortex can mimic actions of extracellularly applied acetylcholine and intracellularly applied cGMP, the latter in 100-fold higher concentrations than those used here, in neurons of the same cortical areas.

GABAergic input to cholinergic forebrain neurons: an ultrastructural study using retrograde tracing of HRP and double immunolabeling

Amygdalopetal cholinergic neurons in the ventral pallidum were identified by combining choline acetyltransferase (ChAT) immunohistochemistry with retrograde tracing of horseradish peroxidase (HRP) following injections of the tracer in the basolateral amygdaloid nucleus. Although ChAT-positive terminals were identified in the ventral pallidum, they were never seen in contact with either immunonegative or ChAT-positive amygdalopetal neurons. In material, in which immunostaining against glutamic acid decarboxylase (GAD), the synthesizing enzyme for GABA was combined with retrograde tracing of HRP from the basolateral amygdaloid nucleus, GAD-positive terminals were seen to contact immunonegative amygdalopetal neurons. In addition, when sections of the rostral forebrain were processed, first to preserve and identify the transported HRP, and then were sequentially tested for both ChAT and GAD immunohistochemistry with the immunoperoxidase reaction for both tissue antigens, GAD-immunopositive terminals were seen to make synaptic contacts with cholinergic amygdalopetal neurons. These results suggest that amygdalopetal, presumably cholinergic, neurons receive GAD-positive terminals. In separate experiments using immunoperoxidase for ChAT and ferritin-avidin for GAD labeling, we confirmed the presence of GAD-containing terminals on cholinergic neurons. In addition, cholinergic terminals were seen in synaptic contact with GAD-positive cell bodies. These morphological studies suggest that direct GABAergic-cholinergic and cholinergic-GABAergic interactions take place in the rostral forebrain.

Slow cholinergic excitation of guinea pig hippocampal neurons is mediated by two muscarinic receptor subtypes

Stimulation of cholinergic fibers or bath application of carbachol (0.1-10 microM) induced a slow excitability increase in CA3 neurons and dentate granule cells of hippocampal slices. This effect which was antagonized by atropine (1 microM) was mediated by two receptor subtypes: a pirenzepine (10 microM)-insensitive receptor, 'M2', and a pirenzepine (1 microM)-sensitive receptor, 'M1'. The M2-receptor activation led to a blockade of slow afterhyperpolarizations following trains of action potentials and to the occurrence of threshold-activated plateau-depolarizations associated with a conductance increase. The M1-receptor mediated a membrane depolarization sometimes associated with a conductance decrease which reversed its polarity at membrane potentials negative to -80 mV. The 'slow excitatory postsynaptic potential' which results from activation of cholinergic fibers is thus caused by the activation of two receptor subtypes.

Non-pyramidal neurons in the guinea pig hippocampus. A combined Golgi-electron microscope study

Morphological characteristics of non-pyramidal neurons in the guinea pig hippocampus (regions CA1 and CA3) were analyzed by a correlated light and electron microscopic approach. Following Golgi impregnation, the cells were first studied under the light microscope and classified according to the location of their cell bodies and the distribution of their dendrites in the different hippocampal layers. Next, the Golgi impregnated non-pyramidal neurons were gold-toned and deimpregnated, allowing an electron microscopic analysis of the identified structures. With regard to cell body location and dendritic pattern, non-pyramidal cells are a rather heterogeneous group of neurons. Their perikarya were found in all hippocampal layers and their dendrites had a less regular orientation when compared to pyramidal neurons and granule cells. Two basic types, i.e., "vertical" and "horizontal" non-pyramidal neurons are described. Many cells were of an intermediate type with dendrites extending in all directions. Non-pyramidal cell dendrites were mostly devoid of spines but exhibited numerous varicosities. Non-pyramidal cell axons could sometimes be seen extending towards the pyramidal cell layer. A surprising uniformity was observed when the impregnated, identified non-pyramidal neurons were studied in the electron microscope. Their perikarya exhibited a well-developed endoplasmic reticulum and indented nuclei. Both the cell bodies and the varicose dendrites were densely covered with synaptic boutons which mainly formed asymmetric synaptic contacts. Only occasionally were symmetric synaptic contacts observed. Non-pyramidal cell dendrites extending into the stratum lucidum of CA3 were found to be contacted by the giant boutons of mossy fiber axons. In addition to synaptic contacts, the dendrites of gold-toned non-pyramidal neurons formed gap junctions with neighboring dendrites. The results are discussed in relation to recent immunocytochemical studies which have shown non-pyramidal neurons in the hippocampus to contain gamma-aminobutyric acid and/or various neuropeptides.

Responses of morphologically identified cortical neurons to intracellularly injected cyclic GMP

Cyclic nucleotides are thought to act as second messengers of neurotransmission inside central neurons, and cyclic guanosine monophosphate (cGMP) has been postulated to act as a messenger for muscarinic, cholinergic transmission. Nonetheless, the action of cGMP has not yet been established in identified cortical neurons. We injected cGMP and horseradish peroxidase (HRP) intracellularly in neurons of the motor cortex of awake cats. Fifty-four percent of injected cells responded to cGMP and HRP with an increase in input resistance within 30 s after injection. None of a control group of cells injected with HRP without cGMP so responded. In cells receiving intracellular depolarizing current sufficient to produce repeated spike discharge at the time of injection, the increase in input resistance after cGMP persisted for as long as the cells could be held. There was no significant increase in firing rate after injection of cGMP. Cells responding to cGMP with an increased input resistance were identified as pyramidal cells of layer V. One inverted pyramidal cell of layer VI also showed an increase in input resistance in response to cGMP. Previous studies have suggested that muscarinic cholinergic agents produce an increased input resistance (thought to reflect a decreased potassium conductance) underlying an increased rate of discharge in neocortical neurons. Our results favor a dual action of muscarinic cholinergic transmission in mammalian cortical neurons--the increase in input resistance in layer V pyramidal cells mediated by cGMP, and the increase in rate of discharge mediated by other means.

Desensitization of muscarinic acetylcholine receptors: possible relation to receptor heterogeneity and phosphoinositides

The increases in firing rates of hippocampal cells were examined following microiontophoretic application of several muscarinic cholinergic receptor agonists. The agonists studied had been pharmacologically characterized previously and divided into two classes: class A agonists (e.g. acetylcholine, carbamylcholine, and oxotremorine-M) which maximally stimulate PI turnover and reveal mAChR heterogeneity, and class B agonists (e.g. bethanecol and oxotremorine-1) which poorly stimulate PI turnover and do not alter mAChR conformation/orientation in the hippocampus. While comparable stimulatory effects on hippocampal pyramidal cell firing rates were seen with both classes of agonists during short (20 s) ejection periods, longer applications (greater than 25 s) produced class-dependent differential firing patterns. Prolonged ejection of class A agonists selectively desensitized cells to further, continued application in the same ejection period, and the firing rates declined. Class B agonists produced stimulatory responses in hippocampal cells during the entire ejection period, and DE was not observed. This desensitization effect (DE) was observed only for bursts and not for simple spikes.

Chemical modulation of ephaptic activation of CA3 hippocampal pyramids

In rats under urethane anaesthesia, antidromic population spikes were evoked in CA3 pyramidal layer by fimbrial/commissural stimulation at a very low frequency (approximately 0.5 Hz). Submaximal population spikes--between 20 and 90% of maximum--were enhanced by 8-38% by applications of acetylcholine and bicuculline, or by medial septal stimulation. Noradrenaline had a less pronounced and regular facilitatory action, whereas gamma-aminobutyrate and glutamate only depressed population spikes. Maximal enhancement by acetylcholine or bicuculline was observed when the antidromic population spike was initially at 38-53% of maximum amplitude. A simple explanation of these results is that acetylcholine and bicuculline, by raising their excitability, facilitate the excitation of non-invaded pyramidal cells by antidromic field potentials. They are fully in keeping with previous intracellular observations on ephaptic interactions between CA3 neurons, and provide a further illustration, in situ, of the importance of increased excitability and disinhibition--whether caused by drugs or synaptic action--in promoting synchronized excitation by ephaptic currents.

Acetylcholine induces burst firing in thalamic reticular neurones by activating a potassium conductance

Recent studies have emphasized the role of acetylcholine (ACh) as an excitatory modulator of neuronal activity in mammalian cortex and hippocampus. Much less is known about the mechanism of direct cholinergic inhibition in the central nervous system or its role in regulating neuronal activities. Here we report that application of ACh to thalamic nucleus reticularis (nRt) neurones, which are known to receive a cholinergic input from the ascending reticular system of the brain stem, causes a hyperpolarization due to a relatively small (1-4 nS) increase in membrane conductance to K+. This cholinergic action appears to be mediated by the M2 subclass of muscarinic receptors and acts in conjunction with the intrinsic membrane properties of nucleus reticularis neurones to inhibit single spike activity while promoting the occurrence of burst discharges. Thus, cholinergic inhibitory mechanisms may be important in controlling the firing pattern of this important group of thalamic neurones.

An analysis of cholinoceptive neurons in the hippocampal formation by direct microinfusion

Microinfusions of cholinergic agents were made in various sites in the dorsal hippocampal formation of urethane anaesthetized rats. Infusions of eserine or carbachol elicited hippocampal theta activity when made in areas containing high levels of cholinergic markers: the stratum oriens and radiatum of the CA1 and CA3, the stratum moleculare and stratum granulosum of the dentate gyrus and the infragranular region of the hilus. Subsequent infusions of atropine sulfate antagonized the theta activity. Control infusions of equal volumes of saline in active sites were without effect. Infusions of eserine or carbachol in the vicinity of the hippocampal fissure, the stratum lacunosum/moleculare of the CA1 or CA3, in the deep regions of the hilus, and in the lateral ventricle and overlying neocortex, were also without effect. Furthermore, in active sites, the latency to onset of theta and subsequent theta frequency, were both directly related to the total amount of carbachol infused. Thus, areas in which theta could be elicited with a cholinergic agonist (carbachol), or an anticholinesterase (eserine) and antagonized with atropine, were found to correspond well to areas previously found to contain a high density of cholinoceptive neurons, using autoradiographic and immunohistochemical techniques. These results provide further support for the involvement of acetylcholine as a neurotransmitter in the generation of type 2 theta in the hippocampal formation.

Intracellular injection of acetylcholine blocks various potassium conductances in vagal motoneurons

Injection of acetylcholine into cholinergic neurons of the dorsal motor nucleus of the vagus induced membrane depolarization, an increase in input resistance, a decrease of early and late afterhyperpolarizations and a prolongation of the action potential. These effects were reversible and within 10-20 min almost complete recovery was always observed. Externally applied acetylcholine, even with doses as high as 15 mM, was not effective. Acetylcholine appeared to block voltage- and Ca2+-dependent K+ conductances. This block was manifested by the reduction of both the early and late afterhyperpolarizations and a decrease of the delayed rectification. The reversal potential for the conductance decrease was 15-30 mV negative to the resting potential. As a result of this blockade an increased Ca2+ current ensues, which is responsible for most of the prolongation of the action potential. The same responses were obtained after the injection of carbamylcholine, neostigmine and choline. However, unlike acetylcholine no sign of recovery was observed. In fact injection of neostigmine, carbamylcholine or neostigmine, together with acetylcholine, produced a delayed response which may reflect the accumulation of endogenous acetylcholine.

Spontaneous muscarinic suppression of the Ca-activated K-current in bullfrog sympathetic neurons

Neurons in bullfrog sympathetic ganglia were voltage-clamped using a single microelectrode. A prolonged outward current which was identified as the Ca-activated K-current secondary to a transient Ca entry through voltage-operated channels was shortened by oxotremorine. An inward Ca-current was not significantly depressed by oxotremorine. It was suggested that muscarinic agonists accelerate the re-closure of K-channels either directly or secondarily via their effects on an intracellular sequestration process of Ca ions. It was also suggested that a small amount of acetylcholine only sufficient to cause a miniature synaptic current via nicotinic receptors could shorten the Ca-activated K-current via muscarinic receptors.

Cholinergic innervation of the rat hippocampus as revealed by choline acetyltransferase immunocytochemistry: a combined light and electron microscopic study

The cholinergic innervation of the rat hippocampus proper and fascia dentata was investigated by using a monoclonal antibody against choline acetyltransferase (ChAT). At the light microscopic level, thin varicose ChAT-immunoreactive fibers were observed mainly in the vicinity of the pyramidal and granular layers where they formed a fine network around proximal dendrites of pyramidal and granule cells. In addition, many ChAT-immuno-reactive fibers were found in the hilar region and in stratum oriens, radiatum, and lacunosum-moleculare of all hippocampal sectors. Electron microscopic analysis revealed ChAT immunoreactivity in thin unmyelinated varicose axons and terminals which established synaptic contacts. Asymmetric contacts of ChAT-immunoreactive terminals were found on small spines in the dendritic layers of the hippocampus proper and in the molecular layer of the fascia dentata. Symmetric synaptic contacts were formed on the cell bodies of pyramidal and granule cells. Both symmetric and asymmetric synaptic contacts occurred on dendritic shafts. The analysis of serial thin sections, which allows identification of postsynaptic elements, suggests that pyramidal cells, granule cells, and nonpyramidal neurons of the hippocampus receive a cholinergic input.

Physiological mechanisms of focal epileptogenesis

The key elements in the development of epileptogenesis appear to be the capacity of membranes in some (pacemaker) neurons to develop intrinsic burst discharges, the presence of disinhibition, and the proper excitatory synaptic circuitry. It is likely that the relative role of each of these processes will differ at different sites in the central nervous system which are prone to epileptogenesis. Synchronization of neuronal populations is a vital element in the development of focal discharge and a variety of mechanisms, including those dependent upon excitatory postsynaptic potentials, and other interactions are possible. Pathological processes may alter some or all of these regulatory mechanisms. However, different pathological entities presumably produce epileptogenesis through different combinations of pathogenetic mechanisms.

Significance of slow synaptic potentials for transmission of excitation in guinea-pig myenteric plexus

Intracellular recordings were made from neurones in myenteric ganglia of the guinea-pig ileum in vitro. Synaptic potentials were evoked by electrically stimulating presynaptic fibres as they entered the ganglion, using a small focal electrode. Slow synaptic depolarizations (excitatory postsynaptic potentials) were evoked in most myenteric neurones of both types. A single stimulus was more likely to evoke a slow excitatory postsynaptic potential in cells with nicotinic synaptic input (S cells; 50%) than in cells with long-lasting after-hyperpolarizations following the soma action potential (AH cells; 20%). Two pulses often evoked a slow excitatory postsynaptic potential in AH cells when one pulse was ineffective. The optimally effective time between the pulses was about 100 ms. Ten pulses resulted in slow excitatory postsynaptic potentials even when delivered at frequencies as low as 0.5 Hz. For the same frequency of presynaptic stimulation, the duration of the slow excitatory postsynaptic potential was greater in AH cells than in S cells and the amplitude of the slow excitatory postsynaptic potential was slightly greater in S than AH cells. Spontaneous depolarizations were observed which had time-courses and amplitudes similar to the evoked slow excitatory postsynaptic potential. They were not blocked by tetrodotoxin or atropine. The calcium-dependent after-hyperpolarization which follows one or more action potentials in AH cells was reduced or even abolished during the slow excitatory postsynaptic potential. Presynaptic nerve stimulation at intensities lower than those required to cause a slow excitatory postsynaptic potential caused a reduction in the calcium dependent after-hyperpolarization. It is concluded that the slow excitatory postsynaptic potential is generated by an intracellular intermediate process which is sensitive to the intracellular calcium concentration. The results suggest that the postsynaptic action of the synaptic transmitter is to interfere with the intracellular process which couples the entry of calcium to the increase in potassium conductance.

Seizures produced by pilocarpine in mice: a behavioral, electroencephalographic and morphological analysis

Increasing doses of pilocarpine, 100-400 mg/kg, were given intraperitoneally to mice and the resulting behavioral, electroencephalographic and neuropathological alterations were studied. No behavioral phenomena were observed in mice treated with the lowest dose of pilocarpine. Occasional tremor and myoclonus of hindlimbs were found in animals which received pilocarpine in a dose of 200 mg/kg. At doses of 300, 325 and 350 mg/kg, pilocarpine produced a sequence of behavioral alterations including staring spells, limbic gustatory automatisms and motor limbic seizures that developed over 15-30 min and built up progressively into a limbic status epilepticus lasting for several hours. The highest dose of pilocarpine, 400 mg/kg, was generally lethal to mice. Pilocarpine produced both interictal and ictal epileptiform activity in the electroencephalogram (EEG). The earliest EEG alterations appeared in the hippocampus and then spread to cortical areas. EEG seizures started 10-15 min after injection of large doses of pilocarpine, 300-350 mg/kg. Ictal periods lasted for 1-2 min, recurred every 5-10 min and were followed by periods of depression of the EEG activity. By 30-45 min paroxysmal activity resulted in a status epilepticus. Examination of frontal forebrain sections with light microscopy revealed a widespread damage to several brain regions including the hippocampus, amygdala, thalamus, olfactory cortex, neocortex and substantia nigra. Scopolamine, 10 mg/kg, and diazepam, 10 mg/kg, prevented the development of convulsive activity and brain damage produced by pilocarpine. The results emphasize that excessive and sustained stimulation of cholinergic receptors can lead to seizures and seizure-related brain damage in mice. It is proposed that systemic pilocarpine in mice provides a useful animal model for studying mechanisms of and therapeutic approaches to temporal lobe epilepsy.

Effects of intracellular antibodies to cGMP on responses of cortical neurons of awake cats to extracellular application of muscarinic agonists

Intracellular injection of specific antibody to cyclic 3',5'-guanosine monophosphate (cGMP-Ab) produced substantial decreases in input resistance (Rm) selectively in neurons of the motor cortex that had responded with increased resistance to prior application of muscarinic agents. Intracellular injection of nonspecific immunoglobulins (IgG) did not produce this effect. (Some nonspecific effects on spike production occurred in cells given IgG or cGMP-Ab.) The decrease in Rm may be interpreted as being consequential to a reduction in baseline amounts of active cGMP due to binding of cGMP with the injected antibody. In cells which demonstrated a prior increase in Rm following extracellular application of the muscarinic agonist, aceclidine, or acetylcholine, injection of antibody to cGMP also resulted in suppression of the increase in Rm to subsequent applications of these muscarinic agents. Some increases in firing rate to these agents continued to be observed after injection of cGMP-Ab. The results support the hypothesis that cGMP mediates effects of muscarinic neurotransmission on the conductances of neurons of the motor cortex of awake cats. Intracellular injection of antibodies to specific cellular elements is shown to be feasible in cortical neurons of awake cats and may prove a useful adjunct to future studies of neurotransmitter mechanisms.

The pharmacology of cholinergic excitatory responses in hippocampal pyramidal cells

The pharmacology of excitatory cholinergic responses in CA1 pyramidal cells was examined in detail using intracellular recording from the hippocampal slice preparation. Acetylcholine (ACh), carbachol, muscarine and pilocarpine depolarized the membrane potential with an associated increase in input resistance. In addition, these agonists increased cell firing and depressed the afterhyperpolarization (AHP) that is due to a calcium-activated potassium conductance. The weak effects of ACh (20-200 microM) were considerably enhanced by addition of eserine (1-10 microM). All excitatory effects were completely antagonized by atropine (0.1-1 microM) but unaffected by dihydro-beta-erythroidine (DHBE) and gallamine (1-50 microM). In contrast to the muscarinic agonists, the nicotinic agonists nicotine and dimethylphenylpiperazinium (DMPP) had no excitatory effects on CA1 pyramidal cells. Phenyltrimethylammonium (PTMA), at high concentrations did depolarize cells and depress the AHP but these effects were antagonized by atropine and not DHBE or gallamine. The action of the analogue of cyclic GMP, 8-bromo-cyclic GMP, although variable, mimicked the membrane effects of ACh in some cells and depressed the AHP in most cells. Intracellular injection of cyclic GMP routinely depressed the AHP. In summary, we have demonstrated two cholinergic responses of hippocampal pyramidal cells that are mediated purely by muscarinic receptors. We could find no evidence to support a mixed-type receptor or the involvement of nicotinic receptors in the excitation of hippocampal pyramidal cells to cholinergic agents.

The role of inhibitory mechanisms in hippocampal long-term potentiation

The role of inhibitory processes in long-term potentiation (LTP) was investigated in hippocampal slices of the rat. GABAergic inhibition, tested by double shock experiments and by intracellular recording of inhibitory postsynaptic potentials, was not reduced in CA 1 pyramidal neurones after the induction of LTP. In cells recorded with caesium chloride-filled electrodes LTP could not be elicited. A reduction of intrinsic potassium-dependent inhibition may thus be responsible for LTP.

The pharmacology of hippocampal theta cells: evidence that the sensory processing correlate is cholinergic

The firing repertoires of theta cells in the CA1 and dentate layers of the hippocampal formation of the freely moving rabbit were analyzed during 3 behavioral conditions: (1) voluntary motor patterns, termed type 1 theta behaviors; (2) automatic motor patterns, termed type 2LIA behaviors; (3) alert immobility with presentation of sensory stimuli, termed type 2 theta behavior. Cholinergic manipulations were shown to effect the firing repertoires of theta cells during the type 2 theta behavior condition (sensory processing) and not the other two behavioral conditions. A hypothesis of a sensorimotor processing function of the hippocampal formation is presented and discussed.

The stability of the hippocampal slice preparation: an electrophysiological and ultrastructural analysis

The viability and stability of the in vitro rat hippocampal slice preparation were assessed using electrophysiological and electron microscopical means. Slices exhibited lifetimes of 6-19 h. Correlation between the duration of electrical activity and changes in ultrastructure of these slices was found. Possible reasons for the wide variability in lifetime of the hippocampal slice are suggested.

Muscarinic agonists depress calcium-dependent gK in bullfrog sympathetic neurons

Intracellular recordings were made from 'fast B' [9] neurons in bullfrog sympathetic ganglia. A single soma action potential was followed by a prolonged after-hyperpolarization lasting for several hundred milliseconds up to 2 s. The spike afterhyperpolarization, which is generated by calcium-dependent potassium conductance increase (gKCa) [3,20-24], was shortened by the muscarinic action of acetylcholine and oxotremorine (30-300 nM). These concentrations of muscarinic agonists were too low to cause any detectable changes in resting membrane potential, input resistance or action potential wave form. ACh released from presynaptic terminal under a physiological condition also caused the shortening of the calcium-dependent hyperpolarization. The results suggested that the shortening of calcium-dependent spike afterhyperpolarization may permit the neuron to pass the high frequency of discharge during the muscarinic excitation.

Facilitation by acetylcholine of tetrodotoxin-resistant spikes in rat hippocampal pyramidal cells

The electrical activity of hippocampal pyramidal cells was studied in slice cultures during blockade of the regenerative Na currents. In the presence of tetrodotoxin, these neurones had a mean resting potential of -68 mV, a membrane input resistance of 87 M omega and displayed marked non-linearities in their current voltage relationship. In response to depolarizing stimuli, pyramidal cells generated action potentials of small amplitude, slow rise and long duration. These tetrodotoxin-resistant spikes were abolished by calcium conductance blockers such as cobalt and cadmium ions. Acetylcholine applied to the bath or by iontophoresis depolarized pyramidal cells, elicited spontaneous tetrodotoxin-resistant spikes and facilitated spiking evoked by depolarizing rectangular current pulses or a current ramp. The effects of acetylcholine were not only slow in onset, but also prolonged; they were completely reversible and sensitive to atropine and calcium-antagonists such as cadmium and cobalt ions which, respectively, reduced and abolished these effects. After hyperpolarizations following injection of depolarizing current pulses were suppressed by acetylcholine and often transformed into depolarizing afterpotentials. Acetylcholine had no effect on voltage-independent conductances as determined by application of hyperpolarizing current pulses. These results could be explained by inhibition of the voltage-dependent K+-current, i.e. the M current (blockade of the calcium current could remove any depolarizing influence resulting from M current inhibition) or by a direct activation of a voltage-dependent calcium current by muscarinic agonists.

Modulation of low calcium induced field bursts in the hippocampus by monoamines and cholinomimetics

The influence of monoamine transmitter candidates, acetylcholine and related substances on rhythmic depolarization shifts (field bursts) in the CA 1 area of hippocampal slices from rats in low calcium (0.2 mmol X 1(-1) ) high magnesium (4 mmol X 1(-1) ) was investigated. Acetylcholine (ACh), histamine (HA) and H2-agonists, noradrenaline (NA) and beta-agonists at nano- to micromolar concentrations as well as dopamine (DA) and 8-bromo-cyclic AMP at 100 mumol X 1(-1) accelerated the field bursts. H2-antagonists blocked HA actions, beta-antagonists blocked NA actions selectively; muscarinic antagonists blocked ACh, HA and NA actions. H1-agonists, serotonin, dopamine and adenosine slowed the field bursts at micromolar concentrations. These effects parallel the action of the tested substances on afterhyperpolarizations in CA 1 pyramidal cells. High sensitivity and specificity make this response of the field bursts an excellent model to study postsynaptic transmitter actions in the central nervous system.

Cholinergic modulation of the functional organization of the cat visual cortex

The cortex receives a cholinergic input which is considered to be involved in mediating the effects of arousal. The experiments reported here have examined the nature of the cholinergic influence on the neuronal organization of the cat visual cortex. Out of 83 cells studied, 92% exhibited a modification in their visual response properties during the iontophoretic application of ACh. These comprised 61% in which responses were facilitated and 31% in which responses were depressed. The facilitatory effects were associated with a striking increase in stimulus specific responses without any concomitant loss in the selectivity. This comment applied equally to orientation and direction selectivity. It is argued that the facilitatory action of ACh on stimulus specific responses is consistent with a modulation of potassium conductance and most probably the conductance associated with a voltage dependent channel. We found no evidence to support the view that the facilitatory action involved disinhibition; the action of bicuculline, which blocks inhibitory influences in the visual cortex, was quite distinct to that of ACh. The facilitatory and depressive effects of ACh did not show any correlation with the simple-complex classification of cells or any other obvious parameter of receptive field organization, but there was a correlation with cortical lamination. Cells facilitated by ACh were found in all cortical laminae, but those depressed by ACh were found in laminae III and IV.

Cholinomimetics produce seizures and brain damage in rats

Microinjections of the cholinergic agonists, carbachol and bethanechol, either into the amygdala or into the dorsal hippocampus produced sustained limbic seizures and brain damage in rats. Systemic administration of pilocarpine in rats resulted in a sequence of convulsive disorders and widespread brain damage as well. Scopolamine prevented the development of convulsive activity and brain damage produced by cholinomimetics. These results suggest that the excessive stimulation of cholinergic muscarinic receptors can lead to limbic seizures and brain damage. It is postulated that muscarinic cholinergic mechanisms are linked to the etiology of temporal lobe epilepsy and epileptic brain damage.

Limbic seizures produced by pilocarpine in rats: behavioural, electroencephalographic and neuropathological study

Behavioural, electroencephalographic and neuropathological responses to increasing doses of pilocarpine (100-400 mg/kg) administered intraperitoneally to rats were studied. At the dose of 400 mg/kg pilocarpine produced a sequence of behavioural alterations including staring spells, olfactory and gustatory automatisms and motor limbic seizures that developed over 1-2 h and built up progressively into limbic status epilepticus. Smaller doses showed different threshold for these behavioural phenomena but a similar time course of development. The earliest electrographic alterations occurred in the hippocampus and then epileptiform activity propagated to amygdala and cortex. Subsequently electrographic seizures appeared in both limbic and cortical leads. The ictal periods recurred each 5-15 min and were followed by variable periods of depression of the electrographic activity. The sequence of electrographic changes correlated well with the development of behavioural phenomena. Histological examination of frontal forebrain sections revealed disseminated, apparently seizure-mediated pattern of brain damage. Neuropathological alterations were observed in the olfactory cortex, amygdaloid complex, thalamus, neocortex, hippocampal formation and substantia nigra. Pretreatment of animals with scopolamine (20 mg/kg) and diazepam (10 mg/kg) prevented the development of convulsive activity and brain damage. These results show that systemic pilocarpine in rats selectively elaborates epileptiform activity in the limbic structures accompanied by motor limbic seizures, limbic status epilepticus and widespread brain damage. It is suggested that a causative relationship between excessive stimulation of cholinergic receptors in the brain and epileptic brain damage may exist.

Asymmetric distribution of acetylcholine receptors and M channels on prepyriform neurons

The responses of pyramidal neurons of rat prepyriform cortex to ionophoretic application of acetylcholine (ACh) were studied in a submerged, perfused brain slice. ACh excited some neurons but only if applied to an area near to the cut surface of the slice. This area contained the basal dendrites of the pyramidal cells and some cell bodies. No excitation was seen if ACh was applied at depths of 250 microns or more from the cut surface, an area which contained only apical dendrites, although the apical dendrites were very sensitive to excitatory amino acids such as aspartate (Asp) and glutamate (Glu). On all neurons which did not discharge to ionophoretic application of ACh, ACh potentiated the response to Glu and Asp. No potentiation of amino acid responses was obtained on apical dendrites. The potentiation had a time course similar to that of the discharge of neurons which fired to ACh. This observation suggests that pyramidal neurons have receptors for ACh on basal but not apical dendrites. The ACh response in the basal dendrite-soma region was elicted by pilocarpine and blocked by atropine but not curare. This was true whether the response studied was direct excitation or potentiation of the response to an amino acid. The ACh response was associated with a voltage-dependent increase in membrane resistance which had a slow time course and appeared to be due to a turning off of an M current, as described by Brown and Adams (1980) in sympathetic ganglion cells. The effects of ACh were minimal at the resting potential but increased with depolartization. ACh had no effect on the current-voltage relation of the cell, except at depolarized potentials of less than -60 mV. Ionophoretic application of Ba2+ to the basal dendritic region resulted in potentiation of the amino acid responses and sometimes induced a discharge similar to that of ACh. Since Ba2+ mimics the ACh response, presumably by a direct blockade of the M channel, the effects of Ba2+ on apical dendrites were tested to determine whether these dendrites contain M channels associated with a transmitter receptor other than ACh. However, Ba2+ did not induce potentiation in apical dendrites, suggesting that M channels are also restricted to the basal dendrites or cell bodies.(ABSTRACT TRUNCATED AT 400 WORDS)

Cholinergic enhancement of penicillin-induced epileptiform discharges in pyramidal neurons of the guinea pig hippocampus

Acetylcholine (1-20 mM) was applied to guinea pig hippocampal slices bathed in normal and penicillin-containing media. Recordings in the CA 1 pyramidal cell layer in the presence of penicillin showed that acetylcholine caused a prolonged enhancement of the extracellular field potential. Intracellular recordings documented an increase in duration of cell bursting, a decrease in burst afterhyperpolarization, and a membrane depolarization lasting 1-5 min. These results suggest that the actions of acetylcholine to increase membrane excitability interact with penicillin-induced disinhibition to enhance hippocampal epileptogenesis.

Ionic mechanisms of cholinergic excitation in mammalian hippocampal pyramidal cells

Intracellular recordings from CA1 hippocampal pyramidal neurons were obtained using the in vitro hippocampal slice preparation. Responses to ACh were monitored in the presence of blockers of voltage-dependent conductances including Mn2+, TTX and Ba2+. When Mn2+ was used to block voltage-dependent Ca conductance and possible indirect presynaptic cholinergic actions, ACh still induced a significant voltage-sensitive increase in apparent input resistance (Ra) (29%), but only an insignificant depolarization of membrane potential (Vm). When both voltage-dependent Ca and Na conductances were blocked by application of Mn2+ and TTX, respectively, ACh produced voltage-dependent increases in Ra (31%) without significant depolarization. In solutions containing TTX alone, ACh produced voltage-sensitive increases in Ra (32%) as well as a significant depolarization (6.2 +/- 3.1 mV (S.D.)). ACh transiently blocked the conductance increase which followed presumed Ca spikes, suggesting an action on the Ca-activated K-dependent conductance. The effects of Ba2+ application (100-200 microM) on Ra mimicked those of ACh. When ACh was applied to neurons in the presence of Ba2+, Ra remained unchanged, although Vm depolarization of 5-15 mV was still seen. The data indicate that ACh decreases both a voltage-dependent K conductance (distinct from that of the delayed rectifier) and a Ca-activated K conductance. Muscarinic cholinergic depolarization occurs as a result of blockade of K conductance, and is mediated by voltage-dependent Ca and Na conductances, and perhaps by presynaptic actions.