Localization of transmitter candidates in the brain: the hippocampal formation as a model

Fine structural localisation of acetylcholinesterase activity in the compound eye of the honeybee (Apis mellifica L.)

Acetylcholinesterase (AChE) activity was demonstrated histochemically at the electron microscopic level in the compound eye of the worker bee (Apis mellifica L.) by use of the method of Lewis and Shute (1969). All photoreceptor axons (short and long visual fibres) display AChE activity. The reaction product is located in the axoplasm and at the plasma membrane. Substantial amounts of the reaction product can be detected in the intercellular spaces between the visual fibres. Along the visual fibres, the enzyme activity is unevenly distributed. High AChE activity is present in the distal parts of te axons, in contrast to lower enzyme levels in the lamina. However, AChE is also present in the proximal terminals of the visual fibres as well as in the intercellular spaces between visual fibre terminals and the postsynaptic neurones (monopolar cells). Intracellular enzyme activity is almost absent in the monopolars. The authors assume the high AChE activity in the visual fibres to be indicative of acetylcholine as the transmitter at the first synapse of the compound eye. This hypothesis is discussed in view of the results of autoradiographic, electrophysiological and pharmacological investigations of the compound eye and of hte ocellus. Our data are a variance with results of studies on the eyes of Diptera.

Increased [3H]glutamate receptor binding in aged rats

Na-independent [3H]glutamate binding to rat hippocampal membranes increases progressively as a function of age. The increased binding represents an increased number of binding sites without changes in their apparent affinity for glutamate. However, [3H]glutamate binding, measured with a saturating concentration of calcium does not change at various ages. This does not reflect a change in the apparent affinity of calcium ions to stimulate [3H]glutamate binding, but a decrease in their maximal stimulatory effect. These results are discussed in relationship to age-related changes in certain physiological and behavioral functions.

Glutamate receptor binding in insects and mammals

High affinity stereospecific binding sites for L-glutamate have been reported in several regions of mammalian brain. The binding sites in the hippocampus and cerebellum have been studied more extensively than binding in other brain regions. The hippocampal and cerebellar binding sites show similar properties with respect to their pharmacology and their independence of Na+. There is evidence, particularly good in the case of hippocampus, of mechanisms that may regulate the availability of the binding sites in both brain areas. Some progress has been made with the isolation of the hippocampal binding site but the protein has not been extensively characterised. In the case of insect muscle, high-affinity stereospecific binding of L-glutamate to whole membrane preparations, to detergent-solubilised membranes and to isolated proteolipids has been reported. Much greater variability in the binding characteristics is seen than is the case with the mammalian brain preparations. Preliminary experiments suggest that at least four distinct binding sites may be present on insect muscle. The complete characterisation of glutamate binding sites is at present precluded by a lack of potent agonists and antagonists. However, recent advances in the pharmacological classification of receptor sites for the excitatory amino acids in mammalian brain could provide sufficient information to permit the identification of the binding sites as synaptic receptors. Invertebrate toxins whose site of action is the insect neuromuscular junction may well prove to be useful tools with which to isolate and characterise the synaptic receptor proteins.

Kainic acid produces depolarization of CA3 pyramidal cells in the vitro hippocampal slice

Kainic acid (KA) (10(-6)-10(-8) M) reversibly depolarized CA3 pyramidal cells when applied topically to the apical dendritic area of these cells in the hippocampal slice. The magnitude of membrane depolarization and the time to recovery of resting membrane potential were concentration-related. Application of 10(-5) M KA produced complete membrane depolarization which did not recover in baseline levels. Unlike CA3 neurons cells from the CA1 region were unaffected by KA (10(-6)-10(-8) M). However, 10(-5) M KA also proved effective in depolarizing CA1 cells.

Ethyl beta-carboline-3-carboxylate antagonizes the action of GABA and benzodiazepines in the hippocampus

In urethane-anaesthetized rats, the beta-carboline derivative beta CCE (0.3-1.0 mg/kg i.v.) excited hippocampal pyramidal cells which were inhibited by GABA (applied iontophoretically) and benzodiazepines (applied iontophoretically or intravenously). While benzodiazepines facilitated the action of GABA, the effects of GABA and benzodiazepines were antagonized by beta CCE. This electrophysiological study supports the behavioural observations that beta CCE is a benzodiazepine receptor antagonist.

Micromolar L-2-amino-4-phosphonobutyric acid selectively inhibits perforant path synapses from lateral entorhinal cortex

Transverse slices of the rat hippocampus were used to examine the ability of phosphonate analogues of acidic amino acids to inhibit perforant path synaptic transmission. Micromolar concentrations of L-2-amino-4-phosphonobutyric acid (APB), an analogue of L-glutamic acid, inhibited transmission from the lateral entorhinal cortex. Two other less-sensitive components were detected in projections from the medial entorhinal cortex. The component from the lateral entorhinal cortex showed high stereospecificity for the L-isomer of APB and was relatively insensitive to phosphonate homologues of shorter and longer chain length.

Behavioral assessment of norepinephrine and serotonin function and interaction in the hippocampal formation

Norepinephrine (NE) and serotonin (5-HT) were injected either into the dorsal or ventral hippocampal formation of rats in doses ranging from 0.005 microgram/microliter to 5.0 microgram/microliter. Behavioral reactivity was assessed by recording latency to paw lick when placed on a hot plate and magnitude of force displaced in a vertical direction to a footshock. In addition open field activity was measured. NE injections resulted in a dose-dependent increase in behavioral reactivity to the hot plate and footshock; 5-HT injections resulted in a dose-dependent decrease in behavioral reactivity to hot plate and footshock. Both NE and 5-HT injections resulted in a dose-dependent increase in open field activity. NE injections were more effective in increasing reactivity when injected into the dorsal hippocampus while 5-HT injections were more effective in decreasing behavioral reactivity when injected into the ventral hippocampus. Both NE and 5-HT were most effective in increasing open field behavior, however, when injected into the dorsal hippocampus. When NE and 5-HT were injected simultaneously they resulted in no change in behavioral reactivity as compared to saline injections. Simultaneous injections of NE and 5-HT neither enhanced nor antagonized the increase in open field activity of each amine injected alone. The results are discussed in terms of the functional significance of NE and 5-HT in the hippocampus, their modes of action and significance for understanding dorsal-ventral hippocampal differences.

Synaptic excitation may activate a calcium-dependent potassium conductance in hippocampal pyramidal cells

In hippocampal CAl pyramidal cells, orthodromic synaptic excitation is followed by an early hyperpolarization mediated by gamma-aminobutyric acid (GABA) and a late non-GABA-mediated hyperpolarization that has properties consistent with an increase in potassium conductance. Depolarizations produced by iontophoretically applied glutamate are followed by hyperpolarizations that have features in accordance with an increase in potassium conductance. The hyperpolarizations are independent of chloride and resistant to tetradotoxin but are blocked by a low-calcium, high-cobalt medium. Voltage clamping the glutamate depolarization does not reduce the subsequent hyperpolarization, indicating that the hyperpolarization results from a direct increase in calcium conductance produced by glutamate, rather than from activation of voltage-sensitive calcium channels. A single transmitter, possibly acting on one type of receptor and channel, may initiate both excitation and inhibition in the same postsynaptic cell.

Monosodium glutamate: increased neurotoxicity after removal of neuronal re-uptake sites

Microinjections of monosodium glutamate (MSG; 300 microgram/0.5 microliter) into the hippocampus of the adult rat result in only marginal damage to local neurons. Perforant path transections, removing glutamatergic afferents to hippocampal granule cells, make the latter markedly more vulnerable to a subsequent MSG injection. The principle of modulating toxic effects of MSG by interfering with its neurotransmitter role may have significant impact on our understanding of human neurodegenerative disorders.

Acetylcholine induced modulation of hippocampal pyramidal neurons

Applications of acetylcholine to hippocampal slices maintained in vitro resulted in slow depolarizations and simultaneous increases in membrane resistance (RN)in hippocampal pyramidal neurons. Increases in RN had both voltage dependent and voltage independent components. These effects were associated with increases in cell discharge frequency, and development of spontaneous as well as synaptically and directly evoked burst discharges. The increase in RN and burst firing lasted for hours. Muscarinic antagonists blocked these actions and in addition, produced a decrease in membrane resistance, which appeared to be due to blockade of a tonic effect of acetylcholine on postsynaptic membrane properties. These findings suggest that ACh acts as a neuromodulator in the hippocampus.

Regeneration of the septohippocampal pathways in adult rats is promoted by utilizing embryonic hippocampal implants as bridges

The ability of embryonic hippocampal tissue to promote regeneration of cholinergic axons in the septohippocampal system has been studied in adult rats. Strips of embryonic hippocampus, taken from 7-40 mm rat fetuses, were implanted into a 2-3 mm wide cavity which completely transected the septal cholinergic axons innervating the intrinsic hippocampus. The ingrowth of cholinergic fibres into the denervated host hippocampal formation was monitored by measuring the activity of the enzyme, choline acetyltransferase (ChAT), and by acetylcholine esterase (AChE) histochemistry. The results demonstrated a gradual, partial return of both ChAT enzyme activity and AChE-positive fibres in the initially denervated hippocampal formation of the adult recipient. Time-course studies indicated that this ingrowth progressed from the implant into the rostral tip of the host hippocampus, and continued caudally to cover the entire dorsal hippocampus by 3-6 months postoperative. Although the regenerating AChE-positive fibres reached the hippocampal target in the recipient along abnormal routes, they reinnervated selectively the appropriate terminal areas within the host hippocampus and dentate gyrus, suggesting the presence of quite specific mechanisms to guide the regenerating axons back to their original targets. Lesions of the medial septum-diagonal band area of the host and horseradish peroxidase (HRP) injections into the host hippocampus, caudal to the implant, indicated that the origin of the regenerating axons was predominately from the ipsilateral ventral medial septum and diagonal band area of the host. The results provide evidence that axonal regeneration and reinnervation of a denervated target zone can be promoted by utilizing implants of embryonic CNS tissue to bridge a tissue defect between the target and the lesioned axonal stumps.

Sympathetic noradrenergic sprouting in response to central cholinergic denervation; a histochemical study of neuronal sprouting in the rat hippocampal formation

An unusual example of neuronal sprouting occurs in the rat brain. Several weeks after fimbrial transection or septal lesions, peripheral sympathetic fibers appear in the dentate and hippocampal gyri. We compared the distribution of normal cholinergic septohippocampal fibers and nerve terminals with the distribution of noradrenergic sympathetic (sympathohippocampal) fibers after septal lesions using anterograde transport of horseradish peroxidase and fluorescence histochemistry. In addition, we destroyed other afferents to the hippocampal formation and examined the effect of subtotal septal lesions on acetylcholinesterase staining and the distribution of sympathohippocampal fibers. The combined results of these experiments suggest that peripheral noradrenergic fibers sprout specifically in response to destruction of central cholinergic fibers after septal lesions. This appears to be the first model of neuronal sprouting in the central nervous system where one identified transmitter system (noradrenergic) sprouts only in response to, and perhaps to replace, another specific transmitter system (cholinergic).

Innervation of embryonic hippocampal implants by regene-rating axons of cholinergic septal neurons in the adult rat

The regeneration of the septal cholinergic system in adult rats has been studied in animals bearing transplants of hippocampus taken from 20-40 mm rat fetuses (approximately 17-21 days of gestation). The septal axons located within the fimbria and the dorsal fornix were lesioned and a cavity was prepared at the rostral end of the hippocampus. The embryonic tissue was placed adjacent to the severed end of the fornix-fimbria. The time-course of ingrowth of cholinergic fibers into the transplant was monitored by acetylcholine esterase (AChE) histochemistry and the determination of the levels of choline acetyltransferase (ChAT). Both methods indicate that there is a progressive ingrowth into the transplant of cholinergic fibers up to 3 months after transplantation. The newly-formed AChE-positive fibers in the transplant remain beyond one year after transplantation and are thus presumably permanent. Both horseradish peroxidase (HRP) injections into the implant and radiofrequency lesions of the septal-diagonal band area indicate that the principal source of these fibers is the AChE-positive neurons of the medial septum and the nucleus of the diagonal band which normally form the septohippocampal cholinergic projection. The results suggest: (1) that implants of a normal embryonic target tissue can promote axonal regeneration in mature neurons of the mammalian central nervous system; (2) that some neurons in the adult mammalian CNS retain at least part of their embryonic capacity to generate axons and recognize specific postsynaptic targets in developing CNS tissue; and (3) that this host-implant interaction can result in the formation of quite specific innervation patterns in the implanted target tissue.

Effects of phenytoin on pyramidal neurons of the rat hippocampus

The effects of phenytoin (35 micrograms/ml) on membrane properties and inhibitory postsynaptic potential (IPSPs) in CA1 and CA3 pyramidal neurons of the in vitro rat hippocampus were examined. No significant change was observed on input resistance or resting membrane potential. Action potential amplitude, overshoot, rate of rise and rate of decay were decreased. IPSP conductance increase and reversal potential, evoked in CA3 cells through mossy fiber stimulation and in CA1 cells through recurrent and Schaffer's collateral stimulation, were unaffected.

Differential effects of pentobarbital and ether on the synaptic transmission of the hippocampal CA1 region in the rat

The effect of ether and sodium pentobarbital on the synaptic transmission of the hippocampal CA1 region was studied in chronically implanted rats. Animal behavior, EEG, and the average evoked potentials (AEPs) following electrical stimulation of the alveus or the stratum radiatum in the CA1 region were recorded. Components of the AEPs, interpreted previously as generated by population excitatory postsynaptic potentials (EPSPs), population inhibitory postsynaptic potentials (IPSPs) (Leung 1979a, b, c) or population postsynaptic spikes (Andersen et al. 1971), were differentially sensitive to ether or pentobarbital. Ether reduced the population EPSPs and population spike evoked at all intensities tested (1-4 X threshold); the population IPSP was slightly enhanced at intermediate stimulus intensities. Pentobarbital suppressed the population EPSP evoked by alvear stimulation but not that by radiatum stimulation, reduced the population spike and greatly enhanced and prolonged the population IPSP evoked at low stimulus intensities. At high stimulus intensities, the IPSP was interpreted to be smaller after pentobarbital but neuronal output from the hippocampal CA1 region, as seen from the evoked population spike, remained attenuated. It is concluded that ether and pentobarbital both suppress hippocampal neuronal excitability but the effect of anesthesia differs for different anesthetics, for different synapses and for different levels of activity in the input fibers.

Characterization of two [3H]glutamate binding sites in rat hippocampal membranes

The specific binding of L-[3H]glutamate was investigated in the presence and the absence of sodium ions in freshly prepared membranes from rat hippocampus. Sodium ions were found to have a biphasic effect; low concentrations induced a marked inhibition of the binding (in the range 0.5-5.0 mM), whereas higher concentrations resulted in a dose-dependent stimulation of binding (in the range 10-150 mM). These results permit the discrimination of two binding sites in hippocampal membranes. Both Na+-independent and Na+-dependent binding sites were saturable, exhibiting dissociation constants at 30 degrees C of 750 nM and 2.4 microM, respectively, with Hill coefficients not significantly different from unity, and maximal number of sites of 6.5 and 75 pmol/mg protein, respectively. [3H]Glutamate binding to both sites reached equilibrium between 5 and 10 min and was reversible. The relative potencies of a wide range of compounds, with known pharmacological activities, to inhibit [3H]glutamate binding were very different for the Na+-independent and Na+-dependent binding and suggested that the former sites were related to post-synaptic glutamate receptors, whereas the latter were related to high-affinity uptake sites. This conclusion was also supported by the considerable variation in the regional distribution of the Na+-dependent binding site, which paralleled that of the high-affinity glutamate uptake; the Na+-independent binding exhibited less regional variation.

The influence of some neurotransmitter agonists and antagonists on the response of hippocampal units and the cortical EEG to ethanol in the awake rat

The spontaneous activity of single unit populations in the dorsal hippocampus and the cortical EEG were monitored in the awake rat. Experiments consisted of three consecutive recording periods; a drug-free baseline period, a pretreatment period and an ethanol period. Pretreatment with doses of dopaminergic or cholinergic agonists, which produced decreases in unit rate and an awake EEG attenuated the inhibitory effect of ethanol on hippocampal unit activity and reduced the amount of high-amplitude, slow (HAS), drowsy-state activity. GABAergic and adrenergic antagonists, which increased hippocampal unit rate, did not attenuate and sometimes enhanced the ethanol-induced inhibition in firing rate but had little additional effect on the EEG. These results point to the involvment of hippocampal neurons in those behavioural aspects of ethanol intoxication mediated by activity in the neurotransmitter systems examined here.

Genetic variation in the histoarchitecture of the hippocampal region of mice

Timm's sulphide-silver method and the histochemical procedures for the demonstration of AChE, MAO and SDH were applied to the brains of three strains of adult mice of either sex: C57/BL/6J, DBA/2J and NMRI. Differences between strains were found 1) in the sulphide-silver pattern of the molecular layer of area dentata, probably reflecting differences in entorhinal, ipsilateral and/or commissural connections, 2) in the distribution of the mossy fibers, 3) in the AChE-staining of a suprapyramidal zone of regio inferior, probably reflecting differences in septal connections, 4) in the AChE-staining of the induseum griseum. The staining patterns for MAO and SDH did not vary, at least not qualitatively, between the strains investigated. Variation in adult age and sex did not influence the results. Since the differences observed seemed to reflect a pattern of genetic differentiation, five more inbred mice (A/J, AKR/A, BALB/c/A, C3H/Tif, St/6Fi) were included to strengthen the hypothesis that different genetic systems are operating at separate septo-temporal levels in the same areas during the development of the hippocampal formation.

Development of glutamate binding sites and their regulation by calcium in rat hippocampus

The postnasal development of the Na-independent [3H]glutamate binding sites, which exhibit some characteristics of postsynaptic glutamate receptors, has been studied in rat hippocampal membranes. The amount of binding sites (expressed in pmol/hippocampus) represents 4% of the adult level at postnatal day (PND) 4, increases very rapidly until PND 9, and then increases at a slower rate reaching 80% of the adult value at PND 23. In contrast, the density of binding sites (expressed in pmol/mg protein) exhibits a maximum at PND 9 and slowly decreases to reach the adult value at PND 23. These changes seen to be only quantitative since the affinity (about 450nM) and Hill coefficient (about 1.0) of these binding sites remain constant throughout development. Calcium ions have been shown to markedly stimulate [3H]glutamate binding in adult hippocampal membranes. This effect appears on PND 9--10 and increases rapidly until PND 16 when it is similar to that seen in the adult rat. We also determined the minimum age at which long-term potentiation (LTP) of synaptic transmission could be detected in the CA1 field of hippocampal slice preparations following repetitive electrical stimulation of the Schaffer-commissural pathways. LTP was only rarely detected at PND 8 whereas it could be reliably obtained after PND 9. These results indicate that the postnatal development of Na-independent glutamate binding sites closely parallels synapse formation in the hippocampus, further supporting the idea that the binding sites are associated with a physiological receptor. They also show that the appearance of the stimulatory effect of calcium on glutamate binding occurs at a time when several forms of synaptic plasticity appear in the hippocampus. In particular the correlation of the development of LTP with the calcium-stimulation of glutamate binding suggests that these phenomena have similar cellular mechanisms.

Epileptiform burst afterhyperolarization: calcium-dependent potassium potential in hippocampal CA1 pyramidal cells

Synaptic excitation of hippocampal cells during blockade of synaptic inhibition results in an epileptiform "burst" potential followed by a prolonged afterhyperpolarization. This afterhyperpolarization resembles the one that is seen after the epileptic interictal spike and that is considered of critical importance in preventing seizure development. The afterhyperpolarization produced in the presence of y-aminobutyric acid antagonists is associated with a conductance increase and is inhibitory. It can occur in an all-or-none fashion after a burst, is independent of chloride, and is depressed by barium. The afterhyperpolarization has a reversal potential of (-86) millivolts, and the reversal potential is strongly dependent on the extracellular concentration of potassium. The afterhyperpolarization appears to be an intrinsic, inhibitory potassium potential mediated by calcium. This finding has implications for understanding the cellular mechanisms of epilepsy.

Quantitative relationships of five putative neurotransmitter receptor sites in rat hippocampal formation

The hippocampus is well suited for studies of the interrelationships of various neurotransmitter systems in the CNS by reason of its simple laminated organization, defined connections, and variety of identified neurotransmitters. We have studied the biochemical and pharmacological properties of five radiolabeled ligand binding sites in a membrane fraction prepared from rat hippocampal formation. These binding sites are thought to identify recognition sites for neurotransmitter receptors. The rank order of ligand binding sites is [3H]muscimol > [3H]quinuclidinyl benzilate > [3H]dihydroergocryptine > [3H]dihydroalprenolol > 125I-labeled alpha-bungarotoxin. All ligands have a single, saturable, high-affinity binding site. Pharmacological characterization of the ligand binding sites indicates properties consistent with the identification of these sites as neurotransmitter receptors.

Evidence against an exclusive role of glutamate in kainic acid neurotoxicity

Transection of the non-glutamatergic septohippocampal fibers 3-5 days prior to intrahippocampal microinjection of 1 microgram kainic acid (KA) or 3 micrograms ibotenic acid (IBO) protect dentate granule cells against KA but not IBO. In the transected animals, a significant reduction of KA-induced behavioral seizures can be observed. Neither transection of the hippocampal commissural system nor the fornix contralateral to the intrahippocampal injections protected against KA or IBO neurotoxicity. These findings are discussed in the light of the current hypothesis of KA- and IBO-induced neuronal degeneration.

Changes in hippocampal cholinergic activity following learning in mice

A short bar-press operant conditioning acquisition session with food reward on continuous reinforcement was shown to induce a decrease (13.5%) of hippocampal choline acetyltransferase activity in mice. Such an effect seems to be specific to this kind of learning since no change was observed in several control groups, including a group of mice submitted to another type of conditioning in the same apparatus. It is suggested that these enzymatic modifications might be responsible for the delayed improvement of performance observed on retention of this task.

Antibodies to synaptic vesicles purified from Narcine electric organ bind a subclass of mammalian nerve terminals

Antibodies were raised in rabbits to synaptic vesicles purified to homogeneity from the electric organ of Narcine brasiliensis, a marine electric ray. These antibodies were shown by indirect immunofluorescence techniques to bind a wide variety of nerve terminals in the mammalian nervous system, both peripheral and central. The shared antigenic determinants are found in cholinergic terminals, including the neuromuscular junction, sympathetic ganglionic and parasympathetic postganglionic terminals, and in those synaptic areas of the hippocampus and cerebellum that stain with acetylcholinesterase. They are also found in some noncholinergic regions, including adrenergic sympathetic postganglionic terminals, the peptidergic terminals in the posterior pituitary, and adrenal chromaffin cells. They are, however, not found in many noncholinergic synapse-rich regions. Such regions include the molecular layer of the cerebellum and those laminae of the dentate gyrus that receive hippocampal associational and commissural input. We conclude that one or more of the relatively small number of antigenic determinants in pure electric fish synaptic vesicles have been conserved during evolution, and are found in some but not all nerve terminals of the mammalian nervous system. The pattern of antibody binding in the central nervous system suggests unexpected biochemical similarities between nerve terminals heretofore regarded as unrelated.

Behavior-dependent evoked potentials in the hippocampal CA1 region of the rat. II. Effect of eserine, atropine, ether and pentobarbital

The correlations of the rat's behaviors and the hippocampal EEG with the averaged evoked potentials (AEPs) evoked by the Schaffer collaterals in the hippocampal CA1 region of the rat were studied after intraperitoneal injections of several drugs known to affect hippocampal EEG. Ether and eserine induced continuous train of rhythmical slow activity (RSA) of 5-6/sec in the hippocampal EEG, during which the AEPs showed waveforms intermediate between those elicited during large irregular activity (LIA) in the awake, immobile control and those elicited during walking in the control. Low dose nembutal and atropine induced high amplitude LIA during immobility, resembling EEG during slow-wave sleep (SWS). The AEPs during these LIA states, and that during LIA of wake-immobility were of similar waveforms. The AEP waveforms are proposed to form a continuum which corresponds to the continuum of EEG from high amplitude LIA to RSA of increasing frequency. AEP waveforms do not depend only on walking or similar movements which correlate with high frequency RSA. Atropine sulfate (25-50 mg/kg i.p.) severely dampened the oscillations in the AEPs of rats during walking or similar movements, even though the high frequency RSA was essentially unaffected. The difference between AEPs during immobility and those during walking was markedly reduced after atropine, even though the EEG-behavior relationship persisted. The effect of atropine on AEPs may be interpreted as a direct effect on the hippocampus which is apparently inconsistent with present knowledge. If the effect was on inputs from the brain stem or the septum to the hippocampus, the hypothesis that there are two pharmacological types of RSA (atropine-sensitive and -resistant) requires re-definition and re-examination.

Evidence for an agonist independent down regulation of hippocampal muscarinic receptors in kindling

Kindling induces a decline of hippocampal muscarinic cholinergic receptors. To test the hypthesis that the decline was mediated by the agonist, acetylcholine, adult male Sprague--Dawley rats were lesioned in the medial septum prior to kindling. Despite the marked destruction of presynaptic cholinergic terminals in the hippocampus, amygdala kindling proceeded normally and the hippocampal muscarinic receptor decline was not blocked. A small but significant decline in choline acetyltransferase activity was demonstrated in non-lesioned kindled rats. It is proposed that the kindling induced decline of hippocampal muscarinic receptors is mediated by repeated neuronal depolarization.

Origin of dopaminergic innervation of the rat hippocampal formation

The origin of the dopaminergic afferents to the rat hippocampal formation has been investigated by measuring dopamine and DOPAC contents in this area after electrolytic or chemical lesion of the ventral tegmental area (A10) or substantia nigra (A9). The present study indicates that dopaminergic afferents to the hippocampal formation originate from the A10 and A9 dopaminergic cell groups. The 'anterior' hippocampal formation receives a major input from the A10 area whereas the 'posterior' hippocampal region receives dopaminergic afferents from both A9 and A10 cell groups. The dopaminergic afferents are entering the hippocampal region mainly through the dorsal route.

Changes in central cholinergic neurons in the spontaneously hypertensive rat

The activity of choline acetyltransferase (ChAT) was measured in discrete areas of the brain in 4-, 8- and 12-week-old spontaneously hypertensive rats (SH rats) and age matched Wistar Kyoto (WKY rats) controls. The concentration of acetylcholine (ACh) was also measured in certain hindbrain nuclei of 12 week SH and WKY rats. An increase in the ChAT activity and ACh concentration in the locus coeruleus was detected in 12-week-old SH rats. Decreases in the ChAT activity were found in several hypothalamic nuclei of SH rats, specifically in the paraventricular nucleus of 4-week-old rats, in the dorsomedial nucleus at 8 and 12 weeks and in the posterior hypothalamic nucleus at 12 weeks. Changes in ChAT activity were also detected in 4- and 8-week-old SH rats in the anterior ventral thalamus and in the nucleus gigantocellularis. These results suggest that cholinergic nerve activity in certain rat brain areas, several of which play a role in cardiovascular control, is altered in spontaneously hypertensive rats.

Localization of alpha-bungarotoxin binding sites to the goldfish retinotectal projection

The optic tectum of the goldfish Carassius auratus is a rich source of alpha-bungarotoxin (alpha-Btx) binding protein. In order to determine whether some fraction of these receptors is present at retinotectal synapses, we have compared the histological distribution of receptors revealed by the use of [125I]alpha-Btx radioautography to the distribution of optic nerve terminals revealed by the use of cobalt and horseradish peroxidase (HRP) techniques. The majority of alpha-Btx binding is concentrated in those tectal layers containing primary retinotectal synapses. The same layers contain high concentrations of acetylcholinesterase (AChE), revealed histochemically. Following enucleation of one eye, there is a loss of alpha-Btx binding in the contralateral tectum, observed both by radioautography and by a quantitative binding assay of alpha-Btx binding. Approximately 40% of the alpha-Btx binding sites are lost within two weeks following enucleation. By contrast, no significant change in AChE activity could be demonstrated up to 6 months following enucleation. These results are discussed in light of recent studies which show that the alpha-Btx binding protein and the nicotinic acetylcholine receptor are probably identical in goldfish tectum. We conclude that the 3 main classes of retinal ganglion cells projecting to the goldfish tectum are nicotinic cholinergic and that little or no postdenervation hypersensitivity due to receptor proliferation occurs in tectal neurons following denervation of the retinal input.

Characteristics of tetanic and post-tetanic potentiation in the septohippocampal and hippocampal commissural systems in the acute rabbit

The frequency characteristics of tetanic and post-tetanic potentiation of the septohippocampal and hippocampal commissural systems were studied in the acute rabbit preparation. Glass micropipettes were employed to stimulate the medial septal (MSR) and contralateral CA1 (cCA1) regions. Extracellular postsynaptic potentials were recorded in the stratum radiatum and stratum oriens layers of dorsal CA1. Low frequencies of stimulation (2--12 Hz) and brief stimulus trains (7 or 16 stimuli) ensured that only short-term effects appeared in the data. With MSR and cCA1 stimulation, tetanic potentiation became pronounced at 4 Hz, and plateaued at 6--8 Hz. Thus potentiation was found to be pronounced within the range of the rabbit hippocampal theta rhythm. No differences were found in the characteristics of potentiation evoked by stimulation of MSR and cCA1. Post-tetanic potentiation lasting 6--12 sec was found. Again, potentiation characteristics did not depend on stimulus site, suggesting a common mechanism for the pathways studied. A two-factor mechanism was proposed to account for the post-tetanic potentiation data.

Electrophysiological interactions of enkephalins with neuronal circuitry in the rat hippocampus. I. Effects on pyramidal cell activity

Effects of enkephalins on hippocampal pyramidal cell activity were studied in situ and in the in vitro hippocampal slice. Active enkephalin derivatives produced a dose-dependent naloxone-reversible excitation in both preparations whereas inactive enkephalin derivatives had no effect. Several different types of experiments, carried out in the slice, strongly suggest that this excitation is due to blockade of inhibitory pathways. First, when the pyramidal cell population spike is increased during enkephalin administration, no change is seen in the simultaneously recorded EPSP. Second, the magnitude of the enkephalin effect is highly correlated with the amount of inhibition, as judged by paired-pulse stimulation, initially present in the slice. Third, if inhibitory pathways are depressed by a brief period of hypoxia, enkephalin has little effect. Finally, enkephalin responses are mimicked by picrotoxin, which selectively antagonizes inhibitory input to the pyramidal neuron. Since enkephalins do not block the effects of GABA, the putative inhibitory transmitter, these data suggest that opioid peptides depress the inhibitory interneurons and disinhibit the pyramidal cells.

Pharmacological identification of acetylcholine and glutamate excitatory systems in the dentate gyrus of the rat

The responses of dentate granule cells to medial septum (MS) and perforant path (PP) stimulation were examined in urethane anaesthetized rats. MS and PP stimulation evoked an orthodromic activation of granule cells which was correlated with the negative transient of the characteristic field potential elicited from each site. The effects of electrophoretic application of acetylcholine (ACh) and glutamate (Glu) were examined on granule cells identified in this manner. The excitatory action of ACh but not that of Glu was antagonized by atropine. Glutamate diethylester (GDEE) blocked the excitation produced by Glu but not ACh. The synaptically evoked excitation elicited by MS was blocked by atropine but unaltered by GDEE whereas the PP excitatory response was blocked by GDEE and unaltered by atropine. The results of this study indicate that two discrete excitatory systems are present in the dentate gyrus of the rat: a cholinergic system originating in the medial septum and a glutamate mediated system originating in the entorhinal cortex.

Biphasic action of ethanol on single units of the dorsal hippocampus and the relationship to the cortical EEG

The effects of four doses of ethanol (100, 200, 400, 800 mg/kg) administered IV, on the spontaneous firing rate of single units in the dorsal hippocampal regin of the rat were studied. At the lower doses, a mixture of excitatory and inhibitory effects occurring in that order was seen, reflecting a biphasic action of ethanol at the level of the single neuron. As the dose increased, the excitation disappeared and successively greater degrees of response inhibition prevailed. The pattern of the fronto-cortical EEG changed from predominantly low amplitude fast activity with a few episodes of high amplitude slow activity at low doses, to more sustained episodes of slow activity at high doses. The time-response curve showed that the peak of maximum inhibition seen at the highest dose occurred with a longer latency than the peak of maximum excitation seen at the lower doses. Finally, the changes in unit firing appeared to follow four general patterns and to be correlated with the mode of fronto-cortical EEG activity.

Regulation of glutamate receptors by cations

Current evidence suggests that glutamate is a major excitatory neurotransmitter in the mammalian central nervous system (CNS); particularly, glutamate excites most neurones in the CNS. Until recently this effect was widely used to study glutamate receptors and to distinguish them from those of other excitatory amino acids. The development of ligand binding studies for many neurotransmitters has facilitated the study of receptors at the molecular level and using these methods we recently reported the existence in hippocampal membranes of pharmacologically distinct sodium-dependent and sodium-independent glutamate binding sites, the former related to high-affinity uptake and the latter exhibiting several characteristics of postsynaptic receptor sites. We now report that, as with other neurotransmitters, several ions regulate the Na-independent binding of glutamate; the monovalent cations induce a decreased binding while certain divalent cations enhance this Na-independent binding. Additionally, since some of these effects appear to be irreversible, we propose that the regulation of glutamate binding by cations might account for the extremely long-lasting potentiation of synaptic responses found in the hippocampus following bursts of repetitive electrical stimulation (see ref. 9 for a review).