Glutamate as transmitter of hippocampal perforant path

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.

Analysis of short-term plasticity at the perforant path-granule cell synapse

Short-term plasticity was investigated at the perforant path-granule cell synapse in the hippocampal slice preparation. A successive decrement in the amplitude of the extracellular EPSP was obtained at all stimulus frequencies above 0.05 Hz. This effect of repetitive stimulation has previously been shown to fulfill the requirements for habituation processes. If each stimulus within an habituation train was followed by a second identical test stimulus the response to the test stimulus was larger than that to the paired conditioning stimulus. This short-term plasticity has been called paired pulse potentiation. The test response potentiated only with respect to the paired conditioning response and not with respect to previous test responses. Neither form of plasticity appeared to result from changes in the amplitude of the afferent fiber volley. Both habituation and paired pulse potentiation result from an interaction of at least three changes in the efficacy of transmission after a conditioning stimulus: (1) an initial depression, (2) an intermediate relative potentiation and (3) a late depression which decays slowly. Paired pulse potentiation could be demonstrated only if the interpair interval corresponded to the period of maximal late depression and the interstimulus interval to the period of relative potentiation. The amplitudes of intermediate relative potentiation and late depression (and inhibition of transmission by 2-amino-4-phosphonobutyric acid (APB)) were inversely related to the control response amplitude. This relationship likely derives from nonlinear stimulation of postsynaptic ionic currents at higher stimulus intensities. In contrast, the initial depression increased with response amplitude. This is consistent with a mechanism dependent on the postsynaptic membrane potential, such as refractoriness to succeeding stimuli. When the response amplitudes in the presence and absence of 2.5 mM APB were equalized by adjusting the stimulus intensity, no difference was found in the magnitude of either form of plasticity. Since APB probably inhibits transmission at this site through competitive antagonism at the postsynaptic receptor, this observation suggests that habituation and paired pulse potentiation are generated presynaptically.

Antagonism of excitatory amino acid-induced responses and of synaptic excitation in the isolated spinal cord of the frog

1. A range of compounds has been tested for excitatory amino acid agonist or antagonist activity and for effects on synaptic activity on isolated hemisected spinal cords of frogs. 2. L-Monoamino dicarboxylic acids of chain length up to 8 carbon atoms (L-alpha-aminosuberate) were all agonists. 3. Within a series of D-monoamino dicarboxylic acids, and with diamino dicarboxylic acids (mainly unresolved mixtures of diasteroisomers), there was a progression from agonist activity, for compounds of chain length equal to or shorter than glutamate, to antagonist activity, for compounds of longer chain length equal to or shorter than glutamate, to antagonist activity, for compounds of longer chain length, D-alpha-Aminosuberate (D alpha SD) was the most potent antagonist. 4. The antagonist actions of these substances showed a Mg2+--like selectivity with respect to depolarizations produced by different excitants. N-methyl-D-aspartate (NMDA) was the most susceptible agonist and quisqualate and kainate the least susceptible. Responses to other excitatory amino acids, including L-glutamate and L-aspartate, showed intermediate sensitivity to the antagonists. 5. A parallelism was observed between the relative potencies of mono- and diamino dicarboxylic acids as NMDA antagonists and their relative potencies as depressants of synaptic responses. 6. The results support the concept of different types of excitatory amino acid receptors, with NMDA and its antagonists acting predominantly on one type. These NMDA receptors are probably transmitter receptors activated by an excitatory amino acid transmitter.

Selective antagonism of amino acid-induced and synaptic excitation in the cat spinal cord

1. The effects of D-alpha-aminoadipate (DalphaAA), D-alpha-aminosuberate (DalphaAS) and other excitatory amino acid antagonists have been compared on the excitatory responses of neurones of the cat spinal cord to acetylcholine, a range of glutamate-related amino acids and stimulation of appropriate excitatory synaptic pathways. The ionophoretic technique was used for administration of excitants and antagonists. 2. DalphaAA and DalphaAS had little or no effect on acetylcholine-induced excitation of Renshaw cells. Responses of either Renshaw cells or dorsal horn neurones in the spinal cord to excitatory amino acids were depressed in the order: N-methyl-D-aspartate (NMDA), L-homocysteate, D-glutamate, ibotenate greater than D-homocysteate, L-aspartate, D-aspartate greater than L-glutamate, kainate and quisqualate. 3. These effects are consistent with the existence of different excitatory amino acid receptors, one type being sensitive to the actions of the antagonists, and activated predominantly by the NMDA group of excitants, with other receptors being relatively insensitive to DalphaAA and DalphaAS and activated predominantly by quisqualate and kainate. On this hypothesis, many amino acids are assumed to have mixed actions on DalphaAA-sensitive and -insensitive receptors. 4. 2-Amino-4-phosphonobutyrate (2APB) and L-glutamic acid diethyl ester (GDEE) produced different patterns of antagonism of excitatory amino acid-induced responses from those observed with DalphaAA and DalphaAS. Neither substance was as potent as DalphaAA or DalphaAS as an excitatory amino acid antagonist. 5. Both DalphaAA and DalphaAS selectively antagonized synaptic excitation of Renshaw cells evoked by dorsal root stimulation without affecting cholinergic excitation of these cells evoked by ventral root stimulation. These latter responses were selectively antagonized by dihydro-beta-erythroidine (DHbetaE). DalphaAA also antagonized synaptic excitation of unidentified dorsal horn neurones of the spinal cord evoked by dorsal root stimulation. Neither GDEE (particularly) nor 2APB were as effective as DalphaAA or DalphaAS as depressants of synaptic excitation. 6. Taken in conjunction with the results of in vitro studies on the specificity of action of Dalpha¿ and related substances, these observations suggest that certain synaptic excitations in the spinal cord are mediated by an excitatory amino acid transmitter, and that this transmitter interacts with receptors which are activated selectively by NMDA, less selectively by other amino acids, including L-aspartate, and probably only slightly by quisqualate, kainate and (exogenous) L-glutamate.

Intrahippocampal injections of ibotenic acid provide histological evidence for a neurotoxic mechanism different from kainic acid

Stereotaxic injections of ibotenic acid (IBO) and kainic acid (KA) into either the dorsal hippocampus or the lateral cerebroventricle were performed in order to determine the relative potencies of the drugs and the vulnerability of different hippocampal cell types to their neurotoxic action, IBO was found to be approximately five times less potent than KA in causing degeneration of hippocampal neuronal cell bodies. Unlike KA (0.5 and 1.0 microgram), IBO (5.0 micrograms) caused few signs of intrahippocampal bleeding or necrosis of non-neuronal elements. Pyramidal cells of the CA3 and CA4 regions were the most sensitive and dentate granule cells the least sensitive to KA. In contrast, IBO cused degeneration of granule cells and CA3/CA4 pyramids to an equal extent.

Acute dendrotoxic changes in the hippocampus of kainate treated rats

Kainic acid (KA), a potent neuroexcitatory and neurotoxic analog of glutamate (Glu), induces a widespread pattern of brain damage when administered subcutaneously to adult rats. The hippocampus is among the brain regions most consistently and severely damaged. Here we describe acute swelling of certain spines and branchlets of dendrites as the first detectable sign of KA neurotoxic changes in the hippocampus. These swellings conform to a laminar pattern suggesting selective toxic interaction of KA at specific levels of the dendritic trees of hippocampal pyramidal and dentate granule neurons. The frequency and severity of involvement of each type of hippocampal neuron at each level of its dendritic tree was roughly estimated and neuronal types were ranked from the most to least extensively involved (CA3 greater than CA4 greater than CA1 greater than CA2 greater than dentate granules). The same rank order has been described for the vulnerability of these neurons to acute destruction following intraventricular KA administration. Because the pattern of dendritic dilatations observed corresponds well with the pattern of termination of putative glutamergic inputs to the hippocampus, we interpret the findings as being consistent with the hypothesis that the toxic effects of KA are mediated through glutamergic excitatory receptors. We propose that the sensitivity of a given neuron to the neurodestructive action of KA may be determined by the percentage of its dendritic surface occupied by Glu receptors. We suspect that most, if not all, hippocampal neurons receive some glutamergic input and, therefore, are sensitive to KA. That CA3 pyramids are substantially more sensitive than dentate granules may signify that the former receive many more Glu terminals than the latter, an assumption quite consistent with our observation that focal dendritic swellings were both more densely and more widely distributed over the dendritic surfaces of the former than the latter.

Offset rate of action of muscarinic antagonists depends on their structural flexibility

Time course measurements of the action of muscarinic antagonists were performed in the spontaneously beating carp atrium. Several high affinity drugs, which embody the quinuclidine structure were examined. The structural flexibility of these molecules was reflected in the dissociation of the drugs from the muscarinic receptor. The dissociation of rigid drugs was very much prolonged as compared to flexible drugs of the same affinity.

The effect of acidic amino acid antagonists on synaptic transmission in the hippocampal formation in vitro

The effects on synaptic efficacy of the putative acidic amino acid antagonists, 2-amino-4-phosphonobutyric acid (APB), 2-amino-3-phosphonopropionic acid (APP), 1-hydroxy-3-amino-pyrrolidone-2 (HA-966) and glutamic acid diethyl ester (GDEE), were tested by bath application to the hippocampal slice preparation. On the basis of previous work, we hypothesized that APB, HA-966 and GDEE might antagonize synaptic responses to either glutamate or aspartate, but APP should antagonize only synaptic responses to aspartate. APB and HA-966 reduced the amplitude of the extracellular EPSP recorded during stimulation of the perforant path fibers, but APP and GDEE were without effect. APB, APP and HA-966, but not GDEE, consistently inhibited transmission at Schaffer collateral and commissural synapses. The mossy fiber evoked extracellular EPSP was unaffected by these agents. At the concentrations used in this study (usually 2.5 mM) none of these drugs affected the amplitude of presynaptic fiber potentials or antidromic responses, indicating that they probably acted at synapses. The spontaneous activity of hippocampal pyramidal cells, but not of dentate granule cells, increased in the presence of 2.5 mM APB. The amplitude of the population spike generated by Schaffer commissural stimulation initially increased following introduction of APB into the medium and then declined in parallel with the extracellular EPSP. In addition, APB reduced the duration of recurrent inhibition during the period when pyramidal cell firing was enhanced. These results can be explained by an antagonism at the synapse between pyramidal cell and inhibitory interneuron.

Effect of hippocampus extirpation in the rat on glutamate levels in target structures of hippocampal efferents

Twenty days after complete uni- or bilateral hippocampus extirpation in rats, a 25% decrease in glutamate concentration was observed in the septum. Glutamate content also decreased in other terminal structures of the hippocampo-subicular system, i.e. entorhinal cortex, nucleus accumbens septi, mammillary bodies and contralateral hippocampus. It is concluded that the fall in glutamate content which is absent in caudate nucleus is specific for target regions of the hippocampal efferents, adding further support to the suggested transmitter role of glutamate in the limbic system.

Distribution of glutamate in layers of the rabbit hippocampal fields CA1, CA3, and the dentate area

The distribution of L-glutamic acid in single layers dissected from freeze-dried sections of the rabbit hippocampus was estimated by means of an enzymatic cycling procedure. Although the regional variation in glutamate content is less than that of other transmitter candidates, there were present significant differences in it between the projection fields of certain fiber connections. Glutamate concentration was highest in the termination areas of commissural fibers and Schaffer's collaterals.

Glutamate secretion and NAD(P)H levels during calcium-dependent depolarization of slices of the dentate gyrus

Evidence from studies involving release, postsynaptic responses, inactivation, storage and synthesis etc. support the contention that glutamate may be the transmitter of the perforant input to the granule cells in the dentate gyrus of the hippocampus. In the present report the release of endogenous glutamate and the levels of reduced pyridine nucleotides (NAD(P)H) has been measured in parallel experiments on slices from the dentate gyrus of the hippocampus. A Ca-dependent release of glutamate is evoked by tissue depolarization caused either with electrical field stimulation or with elevated KC1. Electrical stimulation induced a transient increase in tissue NAD(P)H levels, the increase being inhibited by approximately 50% during Ca-free conditions. KC1 stimulation, on the other hand, produced a long-lasting decrease in NAD(P)H, the decrease being halved in the absense of Ca. A metabolic relation between stimulus secretion and energy utilization is discussed.