Intracellularly-recorded effects of glutamate and aspartate on neurones in the guinea-pig olfactory cortex slice

Expression and function of kainate receptors in the rat olfactory bulb

Although recent results suggest roles for NMDA and AMPA receptors in odor encoding, little is known about kainate receptors (KARs) in the olfactory bulb (OB). Molecular, immunological, and electrophysiological techniques were used to provide a functional analysis of KARs in the OB. Reverse transcriptase-polymerase chain reaction revealed that the relative level of expression of KAR subunits was GluR5 approximately GluR6 approximately KA2 > KA1 >> GluR7. In situ hybridization data imply that mitral/tufted cells express mostly GluR5 and KA2, whereas interneurons express mostly GluR6 and KA2. Immunohistochemical double-labeling experiments (GluR5/6/7 or GluR5 + synapsin) suggest that KARs are expressed at both synaptic and extrasynaptic loci. This heterogeneous expression of KAR subunits suggests that KARs may play a multitude of roles in odor processing, each tailored to the function of specific OB circuits. A functional analysis, using whole-cell electrophysiology, suggests that one such role is to increase the frequency of glutamate transmission while attenuating the amplitude of individual events, likely via a presynaptic depolarizing mechanism. Such effects would be important to odor processing particularly by OB glomeruli. In these highly compartmentalized structures, an increase in the frequency of glutamate release and the high density of extrasynaptic KARs, activated by spillover, could enhance glomerular synchronization and thus the transfer of more specific sensory information to cortical structures.

Metabolism of the dorsal cochlear nucleus in rat brain slices

In vitro brain slices of the cochlear nucleus have been used for electrophysiological and pharmacological studies. More information is needed about the extent to which the slice resembles in vivo tissue, since this affects the interpretation of results obtained from slices. In this study, some chemical parameters of the dorsal cochlear nucleus (DCN) in rat brain slices were measured and compared to the in vivo state. The activities of malate dehydrogenase and lactate dehydrogenase were reduced in some DCN layers of incubated slices compared to in vivo brain tissue. The activities of choline acetyltransferase and acetylcholinesterase were increased or unchanged in DCN layers of slices. Adenosine triphosphate (ATP) concentrations for in vivo rat DCN were similar to those of cerebellar cortex. Compared with in vivo values, ATP concentrations were decreased in the DCN of brain slices, especially in the deep layer. Vibratome-cut slices had lower ATP levels than chopper-cut slices. Compared with the in vivo data, there were large losses of aspartate, glutamate, glutamine, gamma-aminobutyrate and taurine from incubated slices. These amino acid changes within the slices correlated with the patterns of release from the slices.

L-glutamate excitation of A10 dopamine neurons is preferentially mediated by activation of NMDA receptors: extra- and intracellular electrophysiological studies in brain slices

The aim of the present study was to assess the effects of L-glutamate (L-GLU) on the neurophysiology of ventral tegmental A10 dopamine neurons in rat midbrain slices using extracellular and intracellular recording methods. L-Glutamate perfusion of 10-100 microM concentrations produced dose-dependent increases in firing rate, with no changes in pattern of firing, while higher concentrations led to a loss of activity reminiscent of depolarization inactivation. The extracellular changes were reflected by the pronounced membrane depolarizations observed through intracellular recordings. The effects of low doses (< or = 30 microM) of L-GLU on firing rate and membrane potential were completely antagonized by co-perfusion with the noncompetitive NMDA blocker, phencyclidine, or the selective competitive NMDA receptor antagonist, CGS 19755, but not by the selective non-NMDA blocker NBQX. However, at concentrations of > or = 300 microM L-GLU's effects could not be completely blocked without the presence of both CGS 19755 and NBQX. Moreover, the magnitude of L-GLU-induced depolarizations became attenuated at membrane potentials more negative than -70 mV. These results suggest that in physiological-like conditions that low extracellular levels of glutamate excite midbrain dopamine neurons via a preferential activation of NMDA receptors, and that only at higher concentrations of L-GLU are non-NMDA receptors brought into play.

Depression of a sustained calcium current by kainate in rat hippocampal neurones in vitro

1. High-threshold, slow inactivating inward Ca2+ currents were studied in CA1 pyramidal neurones from rat hippocampal slices using the single-electrode voltage clamp technique. 2. Kainate (50-400 nM) induced a dose-dependent depression of the amplitude of the slow Ca2+ current. At a dose of 200 nM the current amplitude was reduced from -0.63 +/- -0.06 to -0.32 +/- 0.06 nA. Such an effect of kainate was associated with the development of a small inward current (-0.11 +/- 0.03 nA). Kynurenic acid (1 mM) or 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX; 20 microM) fully prevented these actions of kainate. 3. The structurally related kainate analogue alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA; 200 nM) depressed the slow Ca2+ current by 30 +/- 7%, an effect also blocked by CNQX. 4. In low-Na+ medium slow Ca2+ currents were followed by sustained inward tail currents. Kainate reduced both the steady-state Ca2+ current (from -0.98 +/- 0.14 to -0.63 +/- 0.15 nA) and the tail current (from -0.40 +/- 0.04 to -0.14 +/- 0.03 nA). 5. The inactivation process of the slow Ca2+ current was tested by a double-pulse protocol and was found to be enhanced by kainate. 6. Equimolar replacement of Ca2+ by Ba2+ produced larger inward currents followed by prolonged tails. Kainate reduced the Ba2+ steady-state current from -1.77 +/- 0.18 to -1.44 +/- 0.24 nA and the tail current from -0.47 +/- 0.15 to -0.17 +/- 0.05 nA. 7. In current clamp experiments Ca2+ action potentials were recorded from cells loaded with the Ca2+ chelator BAPTA. In these conditions kainate failed to reduce the Ca2+ action potential, while in the absence of BAPTA kainate shortened the Ca2+ action potentials by 30%. 8. It is suggested that low concentrations of kainate reduced the slow Ca2+ current by promoting its inactivation perhaps through a rise in free intracellular Ca2+.

Muscarinic suppression of the evoked N-wave by oxotremorine-M recorded in the guinea-pig olfactory cortex slice

The effect of the muscarinic agonist oxotremorine-M has been studied on the surface-negative field potential (N-wave) evoked by orthodromic stimulation of the lateral olfactory tract in slices of guinea-pig olfactory cortex. Bath-application of oxotremorine-M (5-80 microM) or carbachol (10-300 microM) produced a reversible depression of the N-wave amplitude without affecting the lateral olfactory tract compound action potential. Oxotremorine-M was approximately 5 times more potent than carbachol in this respect, and the effects of both agonists were competitively blocked by telenzepine (5-100 nM), a selective M1-receptor antagonist. In contrast, methoctramine or AF-DX 116, two 'cardioselective' M2-receptor antagonists, had little or no blocking effect on the agonist responses. It is suggested that oxotremorine-M (like carbachol) inhibits the evoked field potential by activating presynaptic M1-type muscarinic receptors in the olfactory cortex slice.

Release of gamma-[3H]aminobutyric acid from rat olfactory bulb and substantia nigra: differential modulation by glutamic acid

We have studied the glutamate modulation of gamma-[3H]aminobutyric acid ([3H]GABA) release from GABAergic dendrites of the external plexiform layer of the olfactory bulb and from GABAergic axons of the substantia nigra. In the olfactory bulb, [3H]GABA release was induced by high K+ and kainate, and not by aspartate and glutamate alone. However, when the tissue was conditioned by a previous K+ depolarization, glutamate and aspartate caused [3H]GABA release. The effect of glutamate was significantly enhanced when the GABA uptake mechanism was blocked by nipecotic acid. N-Methyl-D-aspartate and quisqualate did not cause [3H]GABA release under the same conditions. The acidic amino acid receptor antagonist 2-amino-4-phosphonobutyric acid and the N-methyl-D-aspartate receptor antagonist 2-amino-5-phosphonovaleric acid significantly inhibited the K+-glutamate- and the kainate-induced [3H]GABA release. Mg2+ (5 mM), which blocks the N-methyl-D-aspartate receptors, significantly inhibited the K+-glutamate-induced but not the kainic acid-induced [3H]GABA release. The K+-glutamate-stimulated release, but not the K+-stimulated [3H]GABA release, was strongly inhibited by Na+-free solutions or by 300 nM tetrodotoxin. Apparently the glutamate-induced release of [3H]GABA occurs through an interneuron because it is dependent on the presence of nerve conduction. In the substantia nigra no [3H]GABA release was elicited by any of the glutamate agonists tested. The present results clearly differentiate between the effects of glutamate on the release of [3H]GABA from the substantia nigra and from the olfactory bulb.(ABSTRACT TRUNCATED AT 250 WORDS)

Putative glutamatergic and/or aspartatergic cells in the main and accessory olfactory bulbs of the rat

The "transmitter-specific" retrograde axonal tracer 3H-D-aspartate has been used to demonstrate neurons in the olfactory bulb which putatively utilize aspartate and/or glutamate as their neurotransmitter and which send an axon either to the piriform cortex or within the bulb itself. Injections of 3H-D-aspartate into layer I of the anterior piriform cortex, in the zone of termination of axons from the olfactory bulb, labeled only a few cells in the main olfactory bulb, located in the mitral and external plexiform layers. Although these cells resembled mitral and tufted cells, they tended to have smaller somata than other mitral or tufted cells and apparently form a distinct subpopulation of relay cells. In contrast, many of the mitral cells of the accessory olfactory bulb were labeled by the same injections of 3H-D-aspartate, probably as a result of involvement of the accessory olfactory tract or its bed nucleus in the injection site. Similar injections of the "nonspecific" tracer HRP into the anterior piriform cortex labeled most of the cells in the mitral cell layer of both the main and accessory olfactory bulbs, and some tufted cells in the external plexiform layer. It is concluded that only a small, distinct subpopulation of the mitral or tufted cells of the main olfactory bulb are aspartatergic and/or glutamatergic, while many (at least) of the mitral cells of the accessory olfactory bulb use the excitatory amino acids as transmitters. Injections of 3H-D-aspartate directly into the main olfactory bulb also failed to label the mitral and deeply situated tufted cells. However, a few cells were labeled in the periglomerular region, the superficial external plexiform layer, and the granule cell layer near the injection site. These labeled cells were smaller than mitral and tufted cells but generally larger than periglomerular or granule cells. They may represent a population of glutamatergic or aspartatergic short axon cells. In addition, small cells of an unknown type were labeled in the olfactory nerve layer following injections in the deepest part of the bulb. These cells do not correspond to any of the well characterized cell types of the olfactory bulb.

Piriform cortex brain slices: techniques for isolation of synaptic inputs

Methods are described for preparation of 3 different slices of piriform cortex which allow convenient study of pyramidal neurons and segregation of synaptic inputs. In slices cut parallel to the pyramidal neurons (perpendicular to the brain surface) one can study chemosensitivity of the various parts of the dendritic tree and the soma. By selected division of this slice the population postsynaptic response to activation of the lateral olfactory tract can be studied without action potential generation. Alternatively the superficial lateral olfactory tract can be removed. Stimulation of deeper regions of the slice under these circumstances elicits a pharmacologically different excitation which appears to be that of association fibers.

Intracellular injection of apamin reduces a slow potassium current mediating afterhyperpolarizations and IPSPs in neocortical neurons of cats

Electrophysiologic effects of intracellularly injected apamin, a Ca2+-dependent K+ channel blocker, were investigated in neurons of the motor cortex of awake cats. Single-electrode voltage clamp techniques were used to measure changes in membrane currents including those that were synaptically activated. All changes occurred within 2-4 min after pressure injection of apamin with partial recovery observed within 8-15 min. Apamin selectively abolished an outward current that mediated a slow afterhyperpolarization (AHP) following intracellular depolarizing current pulses and action potentials without influencing the time course of the action potentials or an associated fast AHP component. In addition apamin increased the number and frequency of spike discharges evoked by the depolarizing current pulses and produced a small increase in the rate of background firing activity. The baseline resting potential and input resistance were essentially unchanged by apamin. Apamin also diminished a late, slowly decaying component of inhibitory postsynaptic potentials (IPSPs) and currents (IPSCs) elicited by stimulation of the ventrolateral thalamus or the pyramidal tract. The apamin-induced changes were concomitant with a decrease of the decay time constant of both IPSPs and IPSCs and a positive shift in their reversal potential. The results suggest that the late, slowly decaying component of these inhibitory postsynaptic responses is generated by an apamin-sensitive Ca2+-dependent K+ conductance which is also responsible for the slow AHP.

The glutamate-induced chloride current in Aplysia neurones lacks pharmacological properties seen for excitatory responses to glutamate

The pharmacological properties of the L-glutamate (Glu)-induced chloride current (ICl) in enzymatically isolated Aplysia neurones were examined using the 'concentration clamp' technique. The Glu-ICl did not cross-desensitize with the ICl evoked by gamma-aminobutyric acid or acetylcholine. Quisqualate, kainate (one out of eight) and N-methyl-D-aspartate (one out of nine) induced a small, non-desensitizing ICl in Glu-responding neurones. The quisqualate- and kainate-ICl did not cross-desensitize with the Glu-ICl. L-Aspartate did not induce a ICl in 11 neurones tested, which showed a Glu-ICl. Glutamate diethyl ester, Joro Spider toxin and ketamine did not suppress the Glu-ICl. Concanavalin A had no effect on the time course of desensitization. These results suggest that the Glu receptor-Cl channel complex in Aplysia neurones has pharmacological properties which differ from those of the excitatory Glu receptor-channel complexes in the crustacean muscle fibres and in the central neurones of vertebrates.

Current generators and properties of late components evoked in rat olfactory cortex

Following main olfactory bulb (MOB) stimulation at frequencies of 0.1-0.3 Hz, in addition to early field potentials, a frequency-sensitive, surface negative late N2 wave (latency range: 63-96 msec) followed occasionally by a late N3 transient, was evoked in the piriform cortex and endopiriform nucleus of the rat. The N2 wave inverted polarity at the Ib-II cortical layer interface (P2 wave) and was associated with late unit discharges 200 to 1200 microns deep to the turnover point. Response probability, peak latency, recovery curve and frequency-sensitivity of the P2 wave were not significantly different in animals under urethane or pentobarbital. Current-source-density (CSD) analysis revealed that the N2 wave generators were localized to the Ib-II layer interface. Since inhibitory activity does not contribute substantially to the second derivative curve, CSD analysis strengthens the assumption that late components (LCs) are excitatory events (compound EPSPs) presumably generated on the proximal apical dendritic segments of pyramidal cells by association axons. The early "b" wave in a test response was facilitated, rather than occluded, when a LC was present in the conditioning response, or when the priming volley was delivered to the mediodorsal thalamic nucleus. Clustering of unit and field activity in two distinct periods of the evoked response separated by a prolonged interval of cell silence suggests that cortical coding of olfactory cues might be more efficiently achieved by temporal modulation of the neuronal response rather than by spatial distribution of firing patterns.

Electrical membrane breakdown: a possible mediator of the actions of electroconvulsive therapy

The voltage across electrodes during electroconvulsive therapy (ECT) is two or three orders of magnitude greater than the membrane potential levels at which electrical breakdown occurs. This paper attempts to relate the interelectrode voltage to the membrane potential of individual neurones. For certain neurones the calculated values exceed the breakdown level. The study indicates that electrical breakdown does take place during ECT. It is suggested that electrical breakdown could explain some effects and side-effects of ECT.

A synaptically evoked late hyperpolarization in the rat dorsolateral geniculate neurons in vitro

Intracellular potentials were recorded from presumed relay neurons in the rat dorsolateral geniculate nucleus maintained in vitro preparations. In this material, the neuronal circuit includes the excitatory optic tract which innervates monosynaptically both relay and intrinsic neurons, the latter providing a feed-forward GABAergic inhibition on the former. Electrical stimulation of the optic tract evokes in the dorsolateral geniculate neurons an early excitatory postsynaptic potential followed by an inhibitory postsynaptic potential which precedes a so far unreported long-lasting late hyperpolarization. The properties of the inhibitory postsynaptic potential are consistent with the notion that they are of disynaptic (feed-forward) origin and that they are the consequence of GABAA receptor activation. In contrast, the late hyperpolarization, which was found in almost every neuron, was enhanced by GABAA blockers, without accompanying changes in the resting membrane potential or the input resistance of the recorded cells. The late hyperpolarization had a lower threshold than the excitatory postsynaptic potential, a long latency (m = 38 +/- 4 ms, n = 10) and was of long duration (m = 308 +/- 57 ms, n = 10). The occurrence and threshold for producing these two potentials were uncorrelated, and paired stimulations of the optic tract showed a marked difference of their recovery time-courses. The late hyperpolarization could be elicited only by afferent stimulations; it never followed intracellularly induced depolarizations and/or anodal break calcium spikes. It was associated with a small conductance increase, sufficient, however, to inhibit high-frequency discharges induced by intracellular injection of depolarizing currents. The late hyperpolarization decreased in amplitude with membrane hyperpolarization and ultimately reversed polarity. The apparent reversal potential followed shifts in extracellular potassium concentration in an almost Nernstian relation (47 mV for a tenfold increase in [K]0). Involvement of GABAB receptors in the generation of this potential may be postulated since baclofen readily hyperpolarized the neurons and decreased their input resistance in the presence of GABAA blockers. We conclude that the late hyperpolarization is a postsynaptic potential mediated by an increased conductance to K ions. Our results further suggest that a minimal disynaptic feed-forward circuit impinging on the relay neurons of the dorsolateral geniculate nucleus is sufficient to subserve this late hyperpolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Responses of pyriform cortex neurons to excitatory amino acids: voltage dependence, conductance changes, and effects of divalent cations

The actions of ionophoretically applied N-methyl aspartate (NMA), quisqualate, and kainate, thought to activate three different types of excitatory amino acid receptors, were studied on pyramidal neurons of the rat pyriform cortex, maintained in an isolated, submerged, and perfused brain slice. Intracellular recordings were made with either K acetate or CsCl electrodes. In most neurons all three agonists elicited monophasic responses which could be evoked at 20-sec intervals. Some neurons showed biphasic responses, most commonly to kainate but, on occasion, also for quisqualate. The slower component appeared to be correlated with excitotoxicity and, consequently, was difficult to study. As a result the kainate responses studied were from neurons selected for having a single component. In neurons selected for having a linear current-voltage relationship or neurons loaded with Cs to suppress K conductance and linearize the current-voltage relationship, the average changes in resistance recorded during ionophoretic responses at resting potential were as follows: NMA, 131.2 +/- 6.7% of control; kainate, 104.7 +/- 5.8% of control; and quisqualate, 92.8 +/- 2.8% of control. The magnitude and direction of the conductance change were very reproducible in any one neuron, but especially for kainate some cells showed clear conductance increases, while others showed clear conductance decreases. Using CsCl electrodes it was possible to reduce K+ conductance and depolarize the neurons over a wider range. By passing depolarizing current it was possible to reverse the responses. The response to all three agonists reversed at the same depolarized potential. This observation indicates that while there are differences in the ionic channels associated with the three agonists at resting potential, the channels have similar properties at more depolarized potentials. Responses to all three agonists were influenced by the concentrations of divalent cations in the perfusion medium. The NMA responses were most sensitive to Mg, increasing in amplitude in the absence of Mg and being depressed by Mg elevation. All responses were sensitive to Ca, with discharges being greatly increased by low Ca and depressed by high Ca. The kainate response was most sensitive to Ca concentration changes. Unlike reports from other preparations the apparent conductance decreases to NMA were not altered by the perfusion of solutions with either no added Mg or no added Ca. The NMA response was very much reduced in either Co (1-2 mM) or Zn (100-200 microM).(ABSTRACT TRUNCATED AT 400 WORDS)

Characteristics of long-duration inhibitory postsynaptic potentials in rat neocortical neurons in vitro

The characteristics of long-duration inhibitory postsynaptic potentials (1-IPSPs) which are evoked in rat frontal neocortical neurons by local electrical stimulation were investigated with intracellular recordings from an in vitro slice preparation. Stimulation with suprathreshold intensities evoked 1-IPSPs with typical durations of 600-900 msec at resting membrane potential. Conductance increases of 15-60% were measured at the peak amplitude of 1-IPSPs (150-250 msec poststimulus). The duration of the conductance increases during 1-IPSPs displayed a significant voltage dependence, decreasing as the membrane potential was depolarized and increasing with hyperpolarization. The reversal potential of 1-IPSPs is significantly altered by reductions in the extracellular potassium concentration. Therefore it is concluded that 1-IPSPs in rat neocortical neurons are generated by the activation of a potassium conductance. 1-IPSPs exhibit stimulation fatigue. Stimulation with a frequency of 1 Hz produces a complete fatigue of the conductance increases during 1-IPSPs after approximately 20 consecutive stimuli. Recovery from this fatigue requires minutes. 1-IPSPs are not blocked by bicuculline but are blocked by baclofen.

Deafferentation elicits a transient decrease in Na+, K+-ATPase activity and ouabain binding in the olfactory tubercle

This work examines the effects of olfactory bulbectomy on Na+, K+-ATPase activity and ouabain binding in the olfactory tubercle. The activity and number of enzyme sites were reduced significantly in olfactory tubercle, but not in corpus striatum or hippocampus, 14 and 21 days after bulbectomy. Enzyme activity and ouabain binding returned to normal by 42 days after the lesions. The time of the reduction in Na+, K+-ATPase coincides with that observed earlier for dopaminergic sprouting and increased dopamine-sensitive adenylate cyclase activity.

Petit mal seizure spikes in olfactory bulb and cortex caused by runaway inhibition after exhaustion of excitation

The olfactory bulb (OB), anterior olfactory nucleus (AON) and prepyriform cortex (PC) maintain 3 kinds of feedback among their populations of excitatory and inhibitory neurons: negative feedback, mutual excitation, and mutual inhibition. At normal levels of synaptic input these are balanced and give rise to chaotic and near-sinusoidal oscillatory EEG activity. Under intense repetitive electrical stimulation of the lateral olfactory tract (LOT), there is failure of the afferent excitatory terminals, perhaps due to transmitter depletion. In this circumstance there is deficient excitatory input under the condition of a high level of sustained activity among mutually inhibitory neurons. An instability develops in which some inhibitory neurons become more disinhibited (excited) and others more inhibited (less active) to the point of a paroxysmal discharge that is manifested in a massive compound IPSP of the excitatory neurons. The paroxysm terminates abruptly, but by mechanisms still unclear repeats at a rate of about 3/s for 10-70 s. It is accompanied by simultaneous ipsilateral twitching of the eyelids and muzzle, salivation, tearing, arrest, and lack of responding to sensory stimuli but without loss of posture, resembling absence in humans. It does not result from runaway mutual excitation, and it rarely culminates in full-blown convulsions. Similar spikes usually also occur in the OB and AON; the sequences of spikes appear to entrain. These normal and seizure EEGs are simulated with a network of non-linear differential equations, that is designed in conformance with the anatomy and physiology of the olfactory system. The seizure appears as an emergent property of the OB, AON and PC interactive system, that is due to an induced asymmetry in the feedback network that controls normal background activity.

A1 noradrenergic neurons tonically inhibit sympathoexcitatory neurons of C1 area in rat brainstem

In rats anesthetized with urethane and paralyzed, bilateral microinjections of kainic acid (KA) into the region of caudal ventrolateral medulla (CVL) containing noradrenergic neurons of the A1 group (A1 area) elicited a decrease followed by an increase in arterial pressure (AP), heart rate (HR) and sympathetic renal nerve activity (RNA). The sympathoinhibitory and sympathoexcitatory effects of KA were prevented by bilateral microinjection of tetrodotoxin into an area of the rostral ventrolateral medulla (RVL) containing C1 adrenergic neurons (the C1 area). In contrast, the autonomic responses were not altered by interruption of the two other principal projections of A1 area neurons, namely to the hypothalamus or to the nucleus tractus solitarii. Bilateral microinjections of tyramine, clonidine, alpha-methylnoradrenaline or histamine into the C1 area elicited a dose-dependent, anatomically specific and reversible decrease in AP, HR and RNA. The effect of tyramine was blocked by previous microinjection of reserpine, 6-hydroxydopamine (6-OHDA), or phentolamine into the C1 area. Pretreatment with phentolamine unveiled a hypertensive effect of alpha-methylnoradrenaline. All effects of alpha-methylnoradrenaline were blocked by pretreatment of the C1 area with phentolamine plus DL-propranolol, whereas those elicited by histamine prevailed. Pretreatment of the C1 area with 6-OHDA abolished all changes in AP and HR elicited by microinjections of KA into the A1 area. We conclude that (1) neurons of the CVL tonically inhibit sympathetic activity, (2) this effect is mediated by an action upon vasomotor neurons of the C1 area of RVL, (3) the inhibition is mediated by noradrenergic projections from A1 neurons into the C1 area, and (4) this tonic sympathoinhibitory effect is independent of the baroreceptor reflex.

Desensitization to glutamate and aspartate in rat olfactory (prepyriform) cortex slice

Olfactory cortex brain slices were subject to multiple bath applications of either glutamate or aspartate. The effectiveness of these amino acids (measured by quantitating the amplitude of lateral olfactory tract-stimulated field potentials) was progressively reduced with each successive perfusion of the agonist. However, the effectiveness of the endogenous neurotransmitter recovered to control in each intervening wash period. Thus, repeated applications of glutamate or aspartate desensitized olfactory cortex receptors to these amino acids but did not desensitize the receptors to the endogenous transmitter. These data support the hypothesis that neither glutamate nor aspartate is the neurotransmitter released from the lateral olfactory tract onto pyramidal cells of the olfactory cortex.

Sympathoinhibition by A1-noradrenergic neurons is mediated by neurons in the C1 area of the rostral medulla

In anesthetized, paralyzed rats, bilateral microinjections of kainic acid (KA) into an area of caudal ventrolateral medulla containing A1 noradrenergic neurons of the A1 group (A1 area) first reduced and then elevated arterial pressure (AP), heart rate (HR) and sympathetic renal nerve activity. These effects are attributable to initial excitation and then paralysis of local neurons by KA. The microinjection of tetrodotoxin into an area of rostral ventrolateral medulla containing adrenaline neurons of the C1 group (C1 area) and which is innervated by neurons in A1 area abolished all the effects of KA. The pretreatment of the C1 area with 6-hydroxy-dopamine (6-OHDA) also abolished all the effects of KA. In contrast interruption of projections of the A1 area to the hypothalamus or nucleus tractus solitarii had no effects. The latency for response evoked in renal nerve by stimulation of A1 area was about 10 ms longer than that elicited from C1 area. Tyramine microinjected into the C1 area elicited a dose-dependent decrease in AP prevented by local application of desmethylimipramine. We conclude that neurons of the A1 area tonically inhibit sympathetic activity by inhibiting neurons of the C1 area probably by release of NA.

The variation in action of excitatory amino acids in relation to distance of iontophoretic application to spinal motoneurones

Intracellular recordings were made from lumbosacral motoneurones of barbiturate-anaesthetized cats. DL-homocysteate (DLH) and L-glutamate were iontophoresed extracellularly over a range of distances from the impaled motoneurone. Movement of the iontophoretic electrode unit was controlled by a micromanipulator which was advanced independently of that moving the intracellular electrode. Depolarizations to DLH were first detected at a greater distance from the impaled motoneurones (mean, 383 micron) than depolarizations to L-glutamate (mean, 165 micron). As the point of application approached the soma of the motoneurone, depolarizations developed more rapidly, were larger and the latent period of the L-glutamate depolarization became shorter. Dendritic 'hot-spots' of the depolarizing action of L-glutamate were not detected.

Modification of local neuronal interactions by amygdala kindling examined in vitro

Stimulation of the amygdala in coronal slices of the amygdala-pyriform region elicited burst responses in the pyriform cortex cells. The burst responses, recorded intracellularly, consisted of a train of action potentials riding on a depolarizing envelope that lasted for an average of 0.4 s. When a similar stimulus was applied to slices prepared from rats previously subjected to amygdala kindling, burst responses were significantly prolonged (average of 6.6 s). Our results indicate that the increased excitability of the chronic epileptic site developed in vivo was retained in the excised amygdala-pyriform slice.

N-Acetylaspartylglutamate: possible role as the neurotransmitter of the lateral olfactory tract

N-Acetylaspartylglutamate, an endogenous brain peptide that binds with high affinity to a subpopulation of glutamate-binding sites in rat brain, is excitatory on rat piriform cortex pyramidal cells studied in a perfused brain slice. Both the monosynaptic excitation of the pyramidal cells elicited by stimulation of the lateral olfactory tract and the response to N-acetylaspartylglutamate were blocked by DL-2-amino-4-phosphonobutyrate but not by other excitatory amino acid antagonists. Responses to glutamate and aspartate, previously considered to be candidates as the lateral olfactory tract transmitter, were unaffected by 2-amino-4-phosphonobutyrate. Three days after unilateral bulbectomy there was a significant decrease in concentrations of N-acetylaspartylglutamate as well as aspartate, N-acetylaspartate, and gamma-aminobutyrate in the pyriform cortex of the side from which the olfactory bulb had been removed. These results are consistent with the possibility that N-acetylaspartylglutamate is the endogenous transmitter of the lateral olfactory tract.

Cellular uptake disguises action of L-glutamate on N-methyl-D-aspartate receptors. With an appendix: diffusion of transported amino acids into brain slices

Pharmacological properties of the guanosine 3'5'-cyclic monophosphate (cyclic GMP) responses to excitatory amino acids and their analogues were compared in slices and dissociated cells from the developing rat cerebellum maintained in vitro. The intention was to determine the extent to which cellular uptake might influence the apparent properties of receptor-mediated actions of these compounds. In slices, the potencies of the weakly (or non-) transported analogues, N-methyl-D-aspartate (NMDA) and kainate (KA) (EC50 = 40 microM each) were higher than those of the transported amino acids, D- and L-aspartate (EC50 = 250 microM and 300 microM) and D- and L-glutamate (EC50 = 540 microM and 480 microM). Quisqualate (up to 300 microM) failed to increase cyclic GMP levels significantly. The sensitivity of agonist responses to the NMDA receptor antagonist, DL-2-amino-5-phosphonovalerate (APV), was in the order NMDA greater than L-aspartate greater than L-glutamate, KA. In dissociated cells, L-glutamate was 280 fold more potent (calculated EC50 = 1.7 microM). L- and D-aspartate (calculated EC50 = 13 microM) and D-glutamate (EC50 = 130 microM) were also more effective than in slices. The potencies of NMDA and KA were essentially unchanged. Responses to NMDA, L-glutamate and L-aspartate under these conditions were equally sensitive to inhibition by APV but the response to KA remained relatively resistant to this antagonist. The implications of these results are that, in slices, cellular uptake is responsible for (i) the dose-response curves to L-glutamate, L- and D-aspartate bearing little or no relationship to the true (or relative) potencies of these amino acids; (ii) the potency of APV towards the actions of transported agonists acting at NMDA receptors being reduced and (iii) a differential sensitivity to APV of responses to L-glutamate and L-aspartate being created, the consequence being that a potent action of L-glutamate on NMDA receptors is disguised. These conclusions are supported by theoretical considerations relating to the diffusion of transported amino acids into brain slices, as elaborated in the Appendix.

Comparison of the action of baclofen with gamma-aminobutyric acid on rat hippocampal pyramidal cells in vitro

Intracellular recordings from CA1 pyramidal cells in the hippocampal slice preparation were used to compare the action of baclofen, a gamma-aminobutyric acid (GABA) analogue, with GABA. Ionophoretic application of GABA or baclofen into stratum (s.) pyramidale evoked hyperpolarizations associated with reductions in the input resistance of the cell. Baclofen responses were easier to elicit in the dendrites than in the cell body layer. Blockade of synaptic transmission, with tetrodotoxin or cadmium, did not reduce baclofen responses, indicating a direct post-synaptic action. (+)-Bicuculline (10 microM) and bicuculline methiodide (100 microM) had little effect on baclofen responses but strongly antagonized somatic GABA responses of equal amplitude. The bicuculline resistance of the baclofen response was not absolute, as higher concentrations of these compounds did reduce it. Pentobarbitone (100 microM) enhanced somatic GABA responses without affecting baclofen responses. (-)-Baclofen was approximately 200 times more potent than (+)-baclofen. The reversal potentials for the somatic GABA and baclofen responses were -70 mV and -85 mV respectively. When the membrane was depolarized, the baclofen response was reduced. This apparent voltage sensitivity was not seen with somatic GABA responses. Altering the chloride gradient across the cell membrane altered the reversal potential of the somatic GABA response but not that of the baclofen response. It was extrapolated that a tenfold shift in the extracellular potassium concentration would cause a 48 mV shift in the reversal potential of the baclofen response. Barium ions reduced the baclofen response, but not the GABA response. Orthodromic stimulation produced a fast inhibitory post-synaptic potential (i.p.s.p.) and a slow i.p.s.p. The properties of the fast and slow i.p.s.p.s were remarkably similar to those of the somatic GABA and baclofen responses, respectively. Application of GABA to the pyramidal cell dendrites evoked, in addition to a depolarization, two types of hyperpolarization. One type of hyperpolarization was bicuculline sensitive, had a reversal potential of about -65 mV and appeared to be chloride dependent. The other hyperpolarization was more easily observed in bicuculline methiodide (100 microM). This response was similar to that evoked by baclofen since it had a high reversal potential (about -90 mV), was relatively insensitive to changes in the chloride gradient across the cell membrane and was reduced by barium. The bicuculline-sensitive hyperpolarization could be evoked by the dendritic or somatic ionophoresis of muscimol and THIP (4,5,6,7-tetrahydroisoxazolo-[5,4-c]pyridin-3(2H)-one.(ABSTRACT TRUNCATED AT 400 WORDS)

Fast and slow depolarizing potentials induced by short pulses of kainic acid in hippocampal neurons

Responses of hippocampal neurons to short pulses of alpha-kainic acid (KA) were studied intracellularly in thin brain slices of the guinea pig. A KA pulse induced a slow depolarizing potential either with or without a preceding much faster depolarization. Large fast responses were induced only at the center of glutamate-sensitive spots, where short pulses of L-glutamate (Glu) induced large depolarizations in the impaled neuron. The fast responses resembled Glu-induced depolarizations in time-course, in sensitivity to movement of the tips of amino acid-pipettes, in sensitivity to Glu-antagonists and in reversal potential. The slow response was much more resistant to movement of the amino acid-pipettes and to Glu-antagonists. Mn2+ was without effect on the fast as well as the slow responses. Glu-induced depolarizations super-imposed on the slow response were simply depressed. These results indicate that two different types of receptors are activated by administration of KA, and suggest that the slow response results from a direct action of KA and the fast response is produced as a consequence of either the direct action of KA on the Glu receptors or a calcium-independent release of Glu by KA.

The reversal potential of excitatory amino acid action on granule cells of the rat dentate gyrus

The responses of granule cells to glutamate, aspartate, N-methyl-D-aspartate (NMDA), quisqualate and kainate applied by ionophoresis on to their dendrites in the middle molecular layer of the dentate gyrus were studied with intracellular electrodes using an in vitro hippocampal slice preparation. On passive depolarization 75% of the granule cells displayed anomalous rectification, which persisted in the presence of TTX and TEA but was eliminated by Co2+ or the intracellular injection of Cs+. Short ionophoretic applications of all the excitatory amino acids evoked dose-dependent depolarizations that were highly localized: movement of the ionophoretic electrode by as little as 10 microns could substantially change the size of the response. The depolarizations evoked by glutamate, asparatate, quisqualate and kainate were unaffected by TTX and Co2+. The depolarization evoked by NMDA was unaffected by TTX but markedly reduced by Co2+. Following intracellular injection of Cs+, neurones could be depolarized to +30 mV and the depolarizations produced by glutamate, quisqualate, NMDA and kainate reversed. The reversal potentials (E) were Eglutamate: -5.6 +/- 0.4 mV; ENMDA: 1.8 +/- 1.9 mV; Equisqualate: -3.9 +/- 1.9 mV; Ekainate: -4.6 +/- 2.0 mV. The excitatory post-synaptic potential (e.p.s.p.) evoked by stimulation of the medial perforant path could also be reversed and Ee.p.s.p. was -5.5 +/- 1.1 mV. The 6 mV difference between ENMDA and the equilibrium potential for the other exogenously applied excitatory amino acids and the statistically significant difference between ENMDA and Ee.p.s.p. (P less than 0.005; d.f.: 7) is consistent with our earlier hypothesis that both the transmitter released by the medial perforant path and exogenously applied glutamate are unlikely to interact with NMDA receptors.

Aspartate aminotransferase activity in fiber tracts of the rat brain

Activity of aspartate aminotransferase, an enzyme which catalyzes the interconversion of the excitatory transmitter candidates, glutamate and aspartate, has been measured in fiber tracts of rat, with an emphasis on sensory and motor systems of the brain. Most tracts had significantly higher activities than the cholinergic facial nerve root, consistent with the possibility that a component of aspartate aminotransferase activity might serve as a marker for neurons using glutamate and/or aspartate as neurotransmitter. Highest activity was in the auditory nerve root. On the other hand, a close correlation was found between aspartate aminotransferase and malate dehydrogenase activities in the fiber tracts, raising the question whether aspartate aminotransferase activity may be more closely related to energy metabolism than to transmitter metabolism.

Amino acid transmitter candidates in various regions of the primary olfactory cortex following bulbectomy

The effect of bulbectomy on amino acid levels in 5 regions of the rat primary olfactory cortex has been monitored. Glutamate levels were significantly lowered in the lateral olfactory tract only. In contrast, aspartate levels were significantly reduced in all regions except the periamygdaloid cortex. The results suggest transmitter heterogeneity of the tract fibres and confirm a likely transmitter role for aspartate for some tract terminals.

Responses of solitary retinal horizontal cells from Carassius auratus to L-glutamate and related amino acids

Effects of L-glutamate and its analogues on membrane potentials of solitary horizontal cells were studied by intracellular recording. L-glutamate depolarized these cells at micromolar concentrations (greater than or equal to 10 microM), while D-glutamate and L-alpha-amino adipic acid produced slight depolarizations only at millimolar concentrations. Neither L- nor D-aspartate, even at millimolar doses, produced any change in solitary horizontal-cell resting potential. Solitary horizontal-cell responses to L-glutamate did not desensitize detectably. Responses to pairs of brief, ionophoretic pulses of L-glutamate were nearly equal in amplitude at inter-pulse intervals as short as 50 ms. Responses to maintained applications of low doses of L-glutamate did not decline for as long as 2 min. Depolarizing responses were produced by ionophoretic applications of L-glutamate near cell somata as well as dendrites. The mean sensitivity was 1.4 +/- 1.5 mV/nC with a maximum of 5.1 mV/nC. Depolarizing responses to L-glutamate reversed in polarity at membrane potentials between 0 and -20 mV, were accompanied by a decrease in membrane slope resistance, and were suppressed by replacement of extracellular sodium ions with choline. These results demonstrate that chemosensitivity of retinal horizontal cells to acidic amino acids persists after dissociation protocols, and in several respects resembles that found in horizontal cells in situ. These findings are consistent with the notion that retinal horizontal cells receive a synaptic input involving L-glutamate or a similar substance.

A bicuculline-resistant inhibitory post-synaptic potential in rat hippocampal pyramidal cells in vitro

Experiments were performed on rat hippocampal CA1 pyramidal cells in vitro in order to elucidate the origin of the late hyperpolarizing potential, which follows the gamma-aminobutyric acid (GABA)-mediated inhibitory post-synaptic potential (GABA-i.p.s.p.). The late hyperpolarizing potential could be evoked by orthodromic stimulation via stratum radiatum or stratum oriens but not by selective antidromic stimulation. The membrane soluble analogue of cyclic AMP, 8-bromoadenosine 3',5'-cyclic monophosphate (8-Br cyclic AMP), which blocks calcium-activated potassium hyperpolarizations (GK(Ca], did not reduce the late hyperpolarizing potential. The enkephalin analogue, (D-ala2-met5)-enkephalinamide (DALA) reversibly reduced both the GABA-i.p.s.p. and the late hyperpolarizing potential. The late hyperpolarizing potential and GABA-i.p.s.p. were more sensitive to low doses of the calcium antagonist, cadmium, than the excitatory post-synaptic potential (e.p.s.p.). The local application of cadmium to the pyramidal cell layer blocked the antidromic i.p.s.p. but the orthodromically evoked late hyperpolarizing potential was less affected. In contrast to the GABA-i.p.s.p., the late hyperpolarizing potential was not reversed by chloride injection and was enhanced, rather than depressed, by bicuculline. We conclude that the late hyperpolarizing potential is a bicuculline-resistant i.p.s.p. The unidentified transmitter for this i.p.s.p. is released from feed-forward interneurones primarily onto the dendrites of the pyramidal cell and may act by increasing the potassium permeability of the membrane. The epileptiform burst after-hyperpolarization evoked in the presence of GABA antagonists is composed of at least two components, a long-duration hyperpolarization mediated GK(Ca) and an earlier and shorter late hyperpolarizing potential. Blockade of the GK(Ca) by 8-Br cyclic AMP did not alter the duration of epileptiform bursts but did markedly increase the frequency of their occurrence. This suggests that GK(Ca) is involved in controlling the interval between bursts.

Action of glutamate in the cat labyrinth

Glutamate solutions of either 50 mM applied on the membranous labyrinth or 1 mM perfused into the lateral canal in cats increased spontaneous and stimulus-evoked activity of vestibular neurons. Kainic acid (10(-4) M) perfused into the labyrinth produced a depolarizing action on vestibular afferents. These results indicate that glutamate could be an excitatory neurotransmitter at the synapse between vestibular hair cells and afferent nerve fibers in the cat.

Attenuation of glutamate-action, excitatory postsynaptic potentials, and spikes by intracellular QX 222 in hippocampal neurons

The effects of intracellular applications of QX 222, a quaternary analogue of lidocaine, were investigated in CA1 neurons of in vitro hippocampal slices of guinea-pig brain. QX 222 produced a strong depression of spontaneous, electrically-(by current injection) or orthodromically-evoked action potentials. These dose-dependent effects were characterized by a reduction in the rate of rise and amplitude of spikes, presumed to be mediated by a Na+-conductance. Although resting membrane conductance tended to diminish with prolonged applications of QX 222, marked changes in resting potential generally were not observed. The threshold for eliciting spikes by intracellular injection of depolarizing current was increased greatly by QX 222, reflecting the impairment of Na+-electrogenesis of spikes. The reduction of action potential amplitude by QX 222 may be partly attributable to enhanced inactivation of Na+-channels because brief depolarizing pulses preceded by strong tonic hyperpolarization, elicited spikes at a lower threshold and of considerably larger amplitude than in the absence of such tonic hyperpolarization. These observations on recovery are compatible with a removal of sodium inactivation. However, this experimental paradigm of current injection also might be expected to remove QX 222 molecules from their blocking sites at the inner end of Na+-channels. When spikes were abolished by QX 222, the depolarization evoked with application of S-glutamate by pressure ejection from an extracellular micropipette positioned close to the neuron was attenuated. This reversible blockade was reproducible in the 14 neurons where the interactions of QX 222 and glutamate were examined systematically. Excitatory postsynaptic potentials, evoked by stimulation of strata oriens or radiatum, were reduced in a similar manner by internal QX 222. These data confirm previous observations that voltage-dependent Na+-channels mediating spike genesis in CA1 neurons can be blocked by internal QX 222. However, QX 222 also apparently interferes with the functions of Na+-channels activated by glutamate-receptor interaction or by receptor interactions with neurotransmitter(s) associated with certain excitatory postsynaptic potentials in CA1 neurons.

Ionic mechanism of a hyperpolarizing glutamate effect on two identified neurons in the buccal ganglion of Aplysia

The ionic mechanism of a membrane effect of L-glutamate on two identified neurons in the buccal ganglion of Aplysia kurodai was investigated with conventional microelectrode techniques and glutamate iontophoresis. Bath-applied and iontophoresed glutamate hyperpolarized the membrane and increased the membrane conductance. The hyperpolarizing glutamate response decreased in amplitude and finally reversed its polarity by conditioning hyperpolarization. The reversal potential of the hyperpolarizing glutamate response was close to the ECl (-60 mV). The reversal potential changed by 22.4 mV when the external chloride concentration was altered by a factor of 5. The relationship between the iontophoretically applied current and the membrane conductance changes was suggestive of two glutamate molecules reacting with a single receptor site. The hyperpolarizing glutamate response was essentially unaffected by 2-amino-4-phosphonobutyric acid (2-APB), L-proline, and quinuclidinyl benzilate (QNB). It was concluded that the hyperpolarizing glutamate response was generated by an activation of Cl- conductance.

Kainate-glutamate interactions in rat cerebellar slices

The effects of L-glutamate on the potency of kainate for stimulating guanosine 3',5'-cyclic monophosphate (cyclic GMP) accumulation and for killing neurones in incubated slices of immature (8-day) and adult rat cerebellum were investigated. L-glutamate did not potentiate the cyclic GMP responses to kainate in either the adult or the immature tissue (in contrast to a recent report), nor did it alter the pharmacological characteristics of this postsynaptic action of kainate in the immature cerebellum. Slices incubated for 2 h in the presence of L-glutamate displayed pronounced glial swelling and neuronal damage. These effects were concentration-dependent and neurones in the immature cerebellum proved to be about 10 times more susceptible than in the adult. None of the neuronal cell types appeared to be selectively vulnerable to the toxicity of glutamate. At the lower concentrations tested (300 microM in the immature tissue, 3 mM in the adult), neurotoxicity was largely restricted to regions near the cut edges of the slices, indicating that very effective mechanisms limit the diffusion of glutamate within the cerebellum. Kainate caused selective necrosis of Purkinje cells and inhibitory interneurones in slices of adult cerebellum at concentrations between 5 and 20 microM; 30 microM kainate, however, also affected granule cells. The neurotoxic potency of kainate towards all neuronal cell types was significantly lower in the immature cerebellum and was not enhanced by including glutamate in the incubation medium. Similarly, glutamate did not potentiate the neurotoxicity of kainate towards Purkinje cells and inhibitory interneurones or or towards granule cells in adult slices. It is concluded that the availability of glutamate is unlikely to be a factor which limits the neurotoxicity of kainate either in the immature or in the adult cerebellum. The increase in the neurotoxic potency of kainate with cerebellar maturation can be ascribed, more readily, to be developmentally-related appearance of kainate receptors.

Evidence for a bicuculline-insensitive long-lasting inhibition in the CA3 region of the rat hippocampal slice

Long-lasting inhibition (up to 2 s) of the commissurally-evoked response in the CA3 region of hippocampal slices was observed following a mossy fibre or commissural conditioning stimulus. Bicuculline applied iontophoretically or by superfusion (1-5 X 10(-6) M) blocked the early phase (20-40 ms) of the post-stimulus inhibition but either had no effect or potentiated the later inhibition.

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)

"Epileptic" brain damage in rats induced by sustained electrical stimulation of the perforant path. II. Ultrastructural analysis of acute hippocampal pathology

Sustained electrical stimulation of the perforant path evokes granule cell population spikes and epileptiform discharges, abolishes recurrent inhibition in the granule cell layer and induces a reproducible pattern of hippocampal damage (see preceding paper, this volume, for electrophysiological and light microscopic findings). Electron microscopic findings described here reveal that the hippocampal damage is identical in pattern and cytopathological detail to that associated with sustained limbic seizures induced by chemical convulsants such as kainic acid, folic acid and dipiperidinoethane. Acutely swollen dendritic segments distributed in a laminar pattern corresponding closely with the termination of putative glutamate or aspartate-containing fibers, including those of the perforant path, were a conspicuous finding. Cell bodies of CA1 and CA3 pyramidal neurons and various interneurons in the hilus and elsewhere displayed degenerative changes ranging from mild to severe. Both the dendritic and somal degenerative changes closely resemble the "excitotoxic" type of damage that the putative transmitters glutamate and aspartate are known to cause. It is proposed, therefore, that sustained electrical stimulation of the perforant path results in excessive synaptic release and accumulation of glutamate (or aspartate) at numerous dendrosomal receptors in the hippocampus with consequent degeneration of the dendrosomal structures housing these receptors. Early excitotoxic effects on interneurons that mediate recurrent inhibition may play an important role in the observed loss of recurrent inhibition and in the evolution of subsequent excitotoxic degeneration in the hippocampus.

Transmitters mediating inhibition of ganglion cells in the cat retina: iontophoretic studies in vivo

The effects of iontophoretically applied gamma-aminobutyrate (GABA) and glycine and their antagonists, bicuculline and strychnine on inhibition of retinal ganglion cells were studied in the optically intact eye of anaesthetised cats. Two kinds of inhibition were studied. One is the inhibition which occurs when a spot (a white spot for on-centre and a black spot for off-centre cells) which produces a maximal response from a cell, is removed from the receptive field centre, i.e. the central post-excitatory inhibition. The other is the inhibition which occurs when an annulus (a white annulus for on-centre and a black annulus for off-centre cells) which occupies the surround region of the receptive field, is presented, i.e. the surround inhibition. GABA enhanced and bicuculline blocked the post-excitatory inhibition at the receptive field centre and surround inhibition of on-centre but not off-centre cells regardless of whether the cell was 'sustained' or 'transient' type. On the other hand, glycine enhanced and strychnine blocked the post-excitatory inhibition at the receptive field centre and surround inhibition of off-centre but not on-centre cells, regardless of whether the cell was 'sustained' or 'transient' type. Inhibition of on-centre cells, thus, appears to be mediated by GABA, whereas that of off-centre cells, by glycine regardless of whether the cells are 'sustained' or 'transient'. Possible existence of GABAergic and glycinergic amacrine cells making postsynaptic contact with on-centre and off-centre ganglion cells, respectively, is proposed. Other possible explanations are discussed.

On the mechanism of action of GABA in pelvic vesical ganglia: biphasic responses evoked by two opposing actions on membrane conductance

Intracellular recording techniques were used to study the response of cat vesical pelvic ganglion neurones loaded with permeable anions to the application of GABA in vitro. In 106/127 neurones GABA evoked a biphasic response, the initial phase of which was depolarizing and associated with a conductance increase; the latter phase was hyperpolarizing and associated with a conductance decrease. The GABA evoked hyperpolarization and conductance decrease were related and behaved as though generated by closure of ion channels open in the resting membrane. The hyperpolarization had a strong inhibitory action on both spontaneous activity, and excitation evoked by depolarizing current injection and pre-synaptic nerve stimulation. Ion substitution experiments suggest that the conductance decrease is primarily to chloride ions, although other ionic species may contribute. Short iontophoretic applications of GABA-evoked monophasic depolarizing excitatory responses, even during the hyperpolarizing response evoked by perfusion of GABA, suggesting no cross-desensitization between the mechanisms generating the initial and late phases of the biphasic response.

Fast inward-rectifying current accounts for anomalous rectification in olfactory cortex neurones

The somatic membrane of guinea-pig olfactory cortex neurones in vitro (23 degrees C) was voltage clamped by means of a single-micro-electrode sample-and-hold technique. In most cells the current-voltage (I-V) relationship showed inward (anomalous) rectification with increasing hyperpolarization beyond the resting potential (ca. -80 mV). Under current-clamp conditions a time-dependent 'sag' of the hyperpolarizing electrotonic potentials was observed following an initial overshoot. No depolarizing after-potential was seen on return to the resting potential. Inward rectification was activated between -100 and -110 mV (irrespective of pre-set resting potential) and increased the membrane input conductance by up to three-fold. The rectification was unaffected by tetrodotoxin or Cd2+. Under somatic voltage clamp, hyperpolarization beyond -110 mV activated a rapid inward relaxation fitted by a single exponential. The relaxation time constant (tau on) decreased e-fold for a 40 mV hyperpolarization. (Typical values: 28 ms at -110 mV declining to 13 ms at -140 mV; external K+ concentration 3 mM, 23 degrees C). More extreme hyperpolarizations evoked a slower 'inactivation' phase (tau = 40-60 ms). A transient outward-decaying 'tail' current reflecting deactivation of inward rectification was seen on stepping from -140 mV to more positive potentials. tau off became slower with hyperpolarization. The tail current disappeared at a potential close to the expected VK but was rarely inverted to an inward-decaying tail. It is proposed that the fast inward-rectifying current of olfactory neurones (If.i.r.) is a K+ current analogous to the anomalous K+ rectifier of marine egg and frog muscle membranes. The behaviour of the inward rectifier was dependent on external K+ concentration in accordance with the unique 'V--VK' dependence of classical anomalous rectification; however, of several agents tested (external Cs+, Ba2+, Rb+, Tl+ or tetraethylammonium), only Cs+ and Ba2+ blocked If.i.r. in a time- and voltage-dependent manner. The effect of tetraethylammonium resembled that of an increase in external K+. The possible contribution of the inward rectifier to the passive cell membrane properties is discussed.

Voltage-clamp analysis of muscarinic excitation in hippocampal neurons

Pyramidal cells in the CA1 field of guinea pig hippocampal slices were voltage-clamped using a single microelectrode, at 23-30 degrees C. Small inwardly relaxing currents triggered by step hyperpolarizations from holding potentials of -80 to -40 mV were investigated. Inward relaxations occurring for negative steps between -40 mV and -70 mV resembled M-currents of sympathetic ganglion cells: they were abolished by addition of carbachol, muscarine or bethanechol, as well as by 1 mM barium; the relaxations appeared to invert at around -80 mV; they became faster at more negative potentials; and the inversion potential was shifted positively by raising external K+ concentration. Inward relaxations triggered by steps negative to -80 mV, in contrast, appeared to reflect passage of another current species, which has been labelled IQ. Thus IQ did not invert negative to -80 mV, it was insensitive to muscarinic agonists or to barium, and it was blocked by 0.5-3 mM cesium (which does not block IM). Turn-on of IQ causes the well known droop in the hyperpolarizing electrotonic potential in these cells. The combined effects of IQ and IM make the steady-state current-voltage relation of CA1 cells slightly sigmoidal around rest potential. It is suggested that activation of cholinergic septal inputs to the hippocampus facilitates repetitive firing of pyramidal cells by turning off the M-conductance, without much change in the resting potential of the cell.

Excitatory amino acid receptors and guanosine 3',5'-cyclic monophosphate in incubated slices of immature and adult rat cerebellum

Addition of the excitatory amino acids l-glutamate, l-aspartate and their analogues kainate and N-methyl-d-aspartate to incubated slices of adult rat cerebellum led to large increases in cyclic GMP levels. The order of apparent potencies was kainate greater than N-methyl-d-aspartate greater than glutamate and aspartate. D-alpha-aminoadipate and Mg2-+ inhibited responses to N-methyl-d-aspartate while glutamic acid diethyl ester was most effective against those to glutamate; responses to kainate were least affected by the antagonists. The exicitant amino acids also elicited large elevations of cyclic GMP levels in slices of immature (8 day) cerebellum. Kainate was less effective than in adult but induced two responses distinguishable by their different time courses, concentration dependencies and sensitivity to antagonists. N-methyl-d-aspartate, glutamate and aspartate were 5 to 10-fold more potent than in the adult. Responses to N-methyl-d-aspartate were similarly inhibited by d-alpha-aminoadipate and Mg2+ but those to glutamate were more resistant to glutamic acid diethyl ester than in the adult. It is concluded that the accumulation of cyclic GMP in response to excitant amino acids in the adult cerebellum is mediated via the operation of receptor types showing pharmacological characteristics expected of excitatory amino acid receptors. The actions of kainate in the immature cerebellum appear to be mediated by receptors different from those on which it acts primarily in the adult.

Convulsant actions of 4-aminopyridine on the guinea-pig olfactory cortex slice

The effects of bath-applied 4-aminopyridine on neurones and extracellular potassium and calcium concentrations were recorded in slices of guinea-pig olfactory cortex. Neurones were orthodromically activated by stimulating the lateral olfactory tract. 4-Aminopyridine (3-10 microM) had the following effects: (1) an increase in the frequency and amplitude of spontaneous postsynaptic potentials; (2) a prolongation and oscillatory behaviour of orthodromically evoked postsynaptic potentials; (3) induction of spontaneous or stimulus-evoked seizure-type discharges which were accompanied by large rises in extracellular potassium and falls in calcium concentration; (4) a prolongation of the lateral olfactory tract population fibre spike. Prior to paroxysmal depolarization, membrane potential, input resistance and soma spike duration were unaffected. In the seconds before seizure discharges, a late hyperpolarizing potential (evoked by orthodromic stimulation) was reduced in amplitude or abolished. Diphenylhydantoin (50 microM) or magnesium ions (5 mM) prevented paroxysmal activity. Our results show that 4-aminopyridine can produce seizure-type discharges in a brain slice preparation. The role of increased spontaneous potentials and possible loss of synaptic inhibition as causal factors for such discharges is discussed.