D-alpha-Aminoadipate as a selective antagonist of amino acid-induced and synaptic excitation of mammalian spinal neurones

Conformational aspects of the actions of some piperidine dicarboxylic acids at excitatory amino acid receptors in the mammalian and amphibian spinal cord

A series of piperidine dicarboxylates (PDA) has been tested for excitatory amino acid agonist and antagonist activity and for synaptic depressant properties of the spinal cords of frogs and immature rats in vitro and of cats in vivo. The substances tested comprised (+/-)-cis-2,3-PDA, (+/-)-cis-2,4-PDA, (+/-)-cis-2,5-PDA, (+/-)-cis-2,6-PDA, (+/-)-trans-2,3-PDA, (+/-)-trans-2,4-PDA and both (+) and (-) forms of cis-2,3-PDA. Peak excitatory amino acid agonist activity was observed with (+/-)-trans-2,3- and (+/-)-trans-2,4-PDA. Excitatory amino acid antagonism and synaptic depressant activity was observed only with cis-dicarboxylates, this activity being greatest in the 2,3-analogue. The agonist actions of piperidine dicarboxylates were effectively depressed by the specific NMDA receptor antagonist, (-)-2-amino-5-phosphonovalerate and, where tested, also by D-alpha-aminoadipate and low concentrations of Mg2+. It was concluded that the major part of these agonist actions were mediated by NMDA receptors. The main structural feature of the NMDA agonist actions of these substances was considered to be their close relationship to N-alkyl-aspartic and glutamic acid molecules, with the trans arrangement of the respective 2,3- and 2,4-situated carboxyl groups promoting most effective interaction with the active sites of the NMDA receptor. (+/-)-Cis-2,3-PDA depressed excitatory responses induced by NMDA, kainate, quisqualate, (+/-)-trans-2,3-PDA and (+/-)-trans-2,4-PDA, or evoked by dorsal root stimulation. Both monosynaptic and polysynaptic excitation were susceptible to the depressant action of this substance. The (-) isomer of cis-2,3-PDA carried both excitatory amino acid agonist and antagonist activity and also the synaptic depressant properties observed with the racemic form of this substance. The (+) isomer showed little pharmacological activity. It is proposed that the structure-activity features of these heterocyclic amino acids indicate some of the conformational requirements for interaction with physiological excitatory amino acid receptors.

Actions of D and L forms of 2-amino-5-phosphonovalerate and 2-amino-4-phosphonobutyrate in the cat spinal cord

The separate optical enantiomers of 2-amino-5-phosphonovalerate (APV) and 2-amino-4-phosphonobutyrate (APB) have been tested for their ability to modify amino acid-induced and synaptic excitation of cat spinal neurones. D-(-)-APV was a highly potent and selective antagonist of amino acid-induced and synaptic excitation. Polysynaptic excitation was more susceptible to antagonism by D-APV than was monosynaptic excitation. It was considered likely that the depression of synaptic excitation by D-APV was due to the blockade of an excitatory amino acid transmitter acting at N-methyl-D-aspartate (NMDA) receptors. L-(+)-APV showed a relatively weak amino acid and synaptic blocking activity, which was similar in character to that of D-APV, and which may have been due to a slight residuum of the D isomer in the sample of the L form used. D-(-)-APB was a weak and relatively non-selective antagonist of amino acid-induced responses. In contrast, L-(+)-APB either had no effect or, at higher concentrations, enhanced these responses. Both isomers depressed synaptic responses in a proportion of the cells tested, the L form being the more potent isomer in producing this effect. Monosynaptic and polysynaptic excitations were both susceptible to this type of action. The depression of synaptic excitation by D-APB may have been due in some cases to the blockade of an excitatory amino acid transmitter. However, it is unlikely that the synaptic depressant action of L-APB is due to this mechanism.

Differential activation and blockade of excitatory amino acid receptors in the mammalian and amphibian central nervous systems

1. Experiments were conducted in vitro on isolated spinal cords of frogs and immature rats and in vivo on cat spinal neurones. 2. The concept of two major types of excitatory amino acid receptors present in these preparations is summarized, one type (NMDA receptors) being activated specifically by N-methyl-D-aspartate (NMDA) and blocked by specific antagonists such as D(-)-2-amino-5-phosphonovalerate (APV), and a second type (non-NMDA receptors) characterized by insensitivity to specific NMDA antagonists. This second type may be comprised of two sub-types activated selectively by the agonists quisqualate and kainate. The putative transmitters L-glutamate and L-aspartate have mixed action on both NMDA and non-NMDA receptors. The major action of both transmitter candidates is considered to be on non-NMDA receptors, but the proportion of the composite responses mediated by NMDA receptors (at least for spinal neurones) appears to be greater for L-aspartate than for L-glutamate. 3. The preference of NMDA and non-NMDA receptors for a range of agonists is discussed. Some newer agonists are considered, in addition to several known agonists not previously discussed in terms of NMDA- and non-NMDA-receptor preference. Structure-activity relations of agonists are discussed. 4. The actions of some new amino acid antagonists are reported. Some of these have useful kainate and quisqualate blocking activity, in addition to their ability to block NMDA induced responses. 5. Evidence is presented suggesting that excitatory amino acid receptors are involved in both polysynaptic and monosynaptic excitation in the spinal cord, NMDA receptors mediating polysynaptic excitation and non-NMDA receptors monosynaptic excitation. 6. The unusual effect is reported of L-2-amino-4-phosphonobutyrate, which potently blocks spinal synaptic excitation in the absence of depressant action on excitatory amino acid-induced responses.

D-aminophosphonovalerate is 100-fold more powerful than D-alpha-aminoadipate in blocking N-methylaspartate neurotoxicity

Here we report that the D-isomers of 2-amino-5-phosphonovalerate (D-APV) and alpha-amino-adipate (D-alpha AA) protect arcuate hypothalamic neurons from the potent excitotoxic activity of N-methylaspartate (NMA). Consistent with evidence that APV is much more powerful than alpha AA in antagonizing the neuroexcitatory activity of NMA, we found D-APV nearly 100 times more powerful than D-alpha AA in preventing NMA from destroying arcuate neurons.

Actions of the optical isomers of 2-amino-5-phosphonovalerate as antagonists of excitatory amino acids

Both D(-)-and L(+)-2-amino-5-phosphonovaleric acid (APV) antagonize amino acid-induced excitations of mammalian spinal neurones and are qualitatively indistinguishable from D-alpha-aminoadipate in this respect. L(+)-APV however has a slower onset of action possibly suggesting that its affinity for the receptor is lower.

Glutamate and aspartate: alteration of thresholds and response patterns of auditory neurons

Iontophoretic application of the excitant amino acids glutamate and aspartate onto neurons in the chinchilla cochlear nucleus results in a lowering of the threshold of response to auditory stimuli. Neurons that display 'on'-type phasic responses to toneburst stimuli may become tonic, sustained responders with iontophoretic application of glutamate or aspartate. The ability of either glutamate or aspartate to effect changes in thresholds and response patterns of cochlear nucleus neurons is further evidence that one of these amino acids may be the afferent transmitter of the auditory nerve. The effects seen with these excitant amino acids may also provide insight into the underlying synaptic events involved in the generation of a particular response pattern.

Lactones derived from kainic acid: novel selective antagonists of amino acid-induced Na+ fluxes in rat striatum slices

The effects of amino acid lactones chemically derived from the neuroexcitant kainic acid on the response of rat striatal slices to excitatory amino acids, were studied. These compounds antagonize to varying extents the effects of kainic acid and N-methyl-D-aspartic acid but have no effect on the responses to glutamic or quisqualic acid. Some of the lactones antagonize preferentially the effects of kainic acid. This study further confirms the existence of heterogenous populations of excitatory amino acid receptors in the rat striatum.

Neurotransmitters in the cochlea and the cochlear nucleus

The inhibitory efferent transmitter in the cochlear is most likely acetylcholine. The afferent transmitter (between hair cells and primary afferent fibres) is not known. There is some evidence for glutamate (or aspartate) but the high concentrations necessary to activate the afferents when these amino-acids are applied intracochlearly may indicate that their effects is unspecific. A number of other transmitter candidates can be safely ruled out at these synapses. In the cochlear nucleus of transmitter between primary afferents and secondary cells is probably glutamate (or aspartate).

Further studies of the chemical sensitivity of the oscillatory potentials of the electroretinogram (ERG). II. Glutamate-aspartate-and dopamine antagonists

The effects on the oscillatory potentials (OPs) of the ERG of some pharmacological agents, which antagonize the putative neurotransmitters glutamate aspartate and dopamine were tested. GDEE and alpha-aminoadipate, blocking agents of the excitatory amino acids glutamate and aspartate, respectively, decreased the amplitude of all the OPs. The amplitude of the b-wave was simultaneously reduced. Thus, no selective or differential sensitivity of the OPs was found, which suggests that glutamate- or aspartate-sensitive neuronal pathways do not seem to be directly involved in the generation of the OPs. Haloperidol, which antagonizes the effect of the inhibitory transmitter agent dopamine, differentially affected the OPs. The earlier OPs appeared more sensitive to low doses of the drug than the later ones. Such doses only slightly decreased the maximum amplitude of the b-wave and did not affect the a-wave. Thus, these findings indicate and support previous suggestions that the individual oscillatory peaks are likely to have different origins and that only inhibitory feed-back synapses give rise to the OPs.

Depression of ventral root--dorsal root potential by DL-alpha-aminoadipate in frog spinal cord

Ventral root--dorsal root potential (VR--DRP) was partially depressed in the presence of 1 mM DL-alpha-aminoadipate (DL-alpha-AAD), probably corresponding to 0.5 mM D-alpha-AAD, in isolated hemisected frog spinal cord. It was suggested that acidic amino acid receptors might be subserving for the generation of VR--DRP in addition to the initial cholinergic link between motoneurons and interneurons and the electrical coupling between motoneurons and primary afferent terminals and the last step between unidentified interneurons and primary afferent terminals which had been reported to be mediated by GABA.

Uptake, release, and metabolism of D- and L-alpha-aminoadipate by rat cerebral cortex

Accumulation of L-alpha-aminoadipate by rat cerebral cortical slices is a stereospecific and Na+-dependent process. The uptake of this compound is also temperature-dependent, with a Km of 1.6 X 10(-4)M for the high-affinity system. D-alpha-Aminoadipate has characteristics similar to those displayed by the L-isomer but to a lesser degree. L-Glutamate and L-aspartate inhibit the uptake of L-alpha-aminoadipate. D- and L-alpha-Aminoadipate are, respectively, weak uncompetitive and weak competitive inhibitors for the uptake of L-glutamate and L-aspartate. Both enantiomers inhibit GABA uptake but in quite different ways. The release of L-alpha-aminoadipate from the cerebral cortical slices is stimulated by a high concentration of K+ ions in the presence of Ca2+ in the perfusion buffer; the D-isomer displays this property to a lesser degree. The omission of Ca2+ markedly reduces the release of these two compounds. Less than 10% of the preloaded D- and L-alpha-aminoadipate are metabolized by the cerebral cortex during 40 min of superfusion. The possibility of L-alpha-aminoadipate as a neurotransmitter candidate is discussed.

Antagonism of excitatory amino acid-induced and synaptic excitation of spinal neurones by cis-2,3-piperidine dicarboxylate

In tests on neurones in the cat spinal cord in vivo, and frog and immature rat spinal cord in vitro, cis-2,3-piperidine dicarboxylate (cis-2,3-PDA) produced the following effects: (1) selective antagonism of amino acid-induced responses, compared with responses to other putative transmitters; (2) effective antagonism of kainate and quisqualate-induced responses in addition to responses induced by N-methyl-D-aspartate (NMDA) and other excitatory amino acids; (3) partial NMDA-like agonist action; (4) antagonism of dorsal root-evoked excitation of Renshaw cells; (5) potentiation of acetylcholine- and ventral root-evoked excitation of Renshaw cells. This unique spectrum of action may be useful for transmitter receptor characterization in the vertebrate central nervous system.

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.

Differentiation of kainate and quisqualate receptors in the cat spinal cord by selective antagonism with gamma-D(and L)-glutamylglycine

The D and L forms of the dipeptide, gamma-glutamylglycine depress NMDA-, L-aspartate- and kainate-induced excitation in cat spinal cord while little or nor effect on L-glutamate- and quisqualate-induced responses. The dipeptides also depress dorsal root-evoked excitation of Renshaw cells, but not acetylcholine- or ventral root-evoked excitation of these cells. The D form of the dipeptide is more potent than the L form. The results are interpreted in favour of three types of receptors for excitatory amino acids on spinal neurones, these being sensitive to the selective agonist action of NMDA, kainate and quisqualate.

Changes in ERG b-wave and Müller cell structure induced by alpha-aminoadipic acid

The role of the Müller cell in the generation of the ERG b-wave was studied in the skate eye by examining the effects of a gliotoxic agent (alpha-aminoadipic acid; alpha-AAA) on retinal structure and function. Superfusing the eyecup for 1 h in 50 mM alpha-AAA resulted in the loss of the b-wave and extensive damage to glial cells, i.e. disruption of the cells' plasma membranes, and a marked loss of cytoplasmic substance. Of the other retinal elements, only the horizontal cells showed some signs of injury in alpha-AAA. On returning the retina to a normal Ringer solution, the widespread loss of cytoplasmic electron density persisted, but the Müller cell membranes appeared to have undergone repair, and the b-wave recovered fully its normal amplitude and waveform.

2-Amino-5-phosphonovalerate (2APV), a potent and selective antagonist of amino acid-induced and synaptic excitation

A new compound, 2-amino-5-phosphonovaleric acid (2APV) is the most potent and selective N-methyl-D-aspartate (NMDA) receptor antagonist yet tested. As with other compounds of this type, it blocks L-aspartate and dorsal root-evoked excitation of spinal neurons, but is without effect on the cholinergic excitation of Renshaw cells evoked by exogenous acetylcholine or ventral root stimulation. The high potency and selectivity of this compound should prove to be of great value in investigations of the amino acid receptor types involved in synaptic excitation.

Dipeptide antagonists of amino acid-induced and synaptic excitation in the frog spinal cord

The dipeptide gamma-D-glutamylglycine (gamma DGG) antagonizes amino acid-induced depolarization and synaptic excitation in the isolated hemisected spinal cord of the frog. In general, the effects of this compound resembled those of the structurally similar D-alpha-aminosuberate (D alpha AS) in being more effective against N-methyl-D-aspartate (NMDA)-induced responses than against responses induced by other excitatory amino acids. However gamma DGG appeared to be more effective than D alpha AS in depressing kainate-induced responses. Similar, though weaker, effects were produced by the L isomer of the dipeptide (gamma LGG), a natural brain constituent.

Neurochemistry of the auditory system

Two areas of auditory biochemistry are reviewed: the identification and characterization of neurotransmitters in the auditory system and the biochemical approach to the study of genetic hearing disorders. Studies to identify neurotransmitters at major auditory synapses are outlined. Evidence supporting glutamate or aspartate as the neurotransmitter for the auditory nerve is presented. The application of biochemistry to the study of genetic hearing disorders is discussed.

Effects of D,L-alpha-aminoadipate on postsynaptic amino acid responses in cultured mouse spinal cord neurons

The effects of the dicarboxylic amino acid, DL-alpha-aminoadipate (DLAA) on amino acid responses have been investigated using intracellular recordings from mouse spinal cord neurons grown in dissociated cell culture. DL-alpha-Aminoadipate markedly antagonized postsynaptic responses to iontophoretically appllied aspartate; antagonism of glutamate was much less prominent. DL-alpha-Aminoadipate altered the affinity of aspartate for its receptor while having no observed effects on aspartate-receptor cooperativity. No direct effects of DLAA on membrane potentials or passive membrane properties were seen at the currents used for antagonism. Responses to the inhibitory amino acids GABA and glycine were unaffected by DLAA.

Structure-activity studies on an excitatory receptor for glutamate on leech Retzius neurones

1 Intracellular recordings were made from Retzius cells from the segmental ganglia of Hirudo medicinalis and Haemopis sanguisuga. Glutamate had a direct excitatory effect on the leech Retzius cells. 2 L-Glutamate was 25 times more potent than D-glutamate. 3 L-Glutamate was approximately equipotent with ibotenic acid and 11.2 times more potent than L-aspartic acid. 4 Quisqualic acid and kainic acid were both approximately 100 times more potent than L-glutamate. DL-1-Amino-cis-1-3-dicarboxyclyclopentane was approximately 5 times more potent than L-glutamate, while the trans isomer was 105 times less potent. 5 alpha-NH2-pimelic acid and beta-CH3-glutamic acid reduced the response to L-glutamate. 6 It is suggested that glutamic acid may interact with the Retzius cell glutamate receptor in an extended conformation.

A simple method for the preparation of D-alpha-aminoadipic acid

High quantity (1 g and more) of racemically and chromatographically pure D-alpha-aminoadipic acid was prepared by selective metabolism of the L-isomer of the commercially available DL-alpha-aminoadipate by Pseudomonas putida. The overall yield of this preparation averaged 40%. The final product has [a]25D value of -25 degrees. This procedure can be useful in the synthesis of high purity D-alpha-amino-adipate, a compound shown recently to be a useful tool in the study of neurotransmission mechanism mediating synaptic excitation.

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.

Amino acids as neurotransmitters of corticofugal neurones in the rat: a comparison of glutamate and aspartate

1 The relative sensitivities to aspartate and glutamate of neurones receiving a corticofugal innervation were examined by microiontophoresis, and compared with the relative sensitivities of neurones not appearing to receive such an input.2 On all the cells tested, glutamate appeared to be a more potent excitant than aspartate in terms of neuronal response size or effective dose.3 DL-alpha-Aminoadipate (alphaAA) reduced the excitatory amino acid responses on all the neurones tested. On many of these cells a control excitation could be produced, by acetylcholine or hydrogen ions, which was in most cases unaffected by doses of alphaAA producing antagonism of amino acid excitation.4 On 70% of the cells, aminoadipate showed no selectivity for aspartate compared with glutamate but a differential action, involving blockade of aspartate but not glutamate, was apparent on the other 30%.5 Doses of alphaAA which selectively reduced responses to aspartate had no effect on short latency evoked spikes, but doses which also reduced responses to glutamate reduced the short-latency synaptic excitation induced by electrical stimulation of either the surface of the cerebral cortex, or of the pyramidal tracts in the medulla.6 These findings suggest that corticofugal neurones having an excitatory action on cells in various parts of the brain may use an amino acid, probably glutamate, as a common neurotransmitter.7 As no significant difference could be demonstrated in the potency ratios of glutamate:aspartate on monosynaptically activated cells compared with other cells, doubt is cast on the validity of drawing conclusions about transmitter identity from potency ratios alone, without the support of antagonist studies.

L-histidine: effects on sensitivity of cat spinal neurones to amino acids

L-Histidine enhanced the inhibitory actions of GABA, muscimol and beta-alanine rather than that of glycine on spinal neurones in pentobarbitone-anaesthetised cats. L-Histidine also enhanced the excitatory action of L-glutamate, D- and L-aspartate, L-homocysteate and especially that of quisqualate, whereas the actions of acetylcholine, kainate, N-methyl-D-aspartate and D-homocysteate were more commonly reduced. These actions of L-histidine are best ascribed to an effect on amino acid transport systems, probably of the low affinity type, which therefore appear to be partially responsible for the inactivation of exogenously administered amino acids.

Glutamate as the neurotransmitter of cerebellar granule cells in the rat: electrophysiological evidence

1 Glutamate and the excitatory aminoacid antagonist, alpha-aminoadipic acid (alphaAA), have been applied by microiontophoresis to Purkinje cells in the rat cerebellum. 2 Glutemate produced excitation of Purkinje cells and alpha AA selectively reduced that excitation without affecting responses to acetylcholine or hydrogen ions. 3 Monosynaptic spikes were evoked in Purkinje cells by stimulating the parallel fibres. alpha AA had little effect on these spikes when applied alone. 4 When the Purkinje cell excitability was reduced by the iontophoresis of gamma-aminobutyric acid, alpha AA then produced railure of the monosynaptic spike on 10 of 13 Purkinje cells, in doses shown to be selectively antagonistic towards aminoacids. 5 These results support neurochemical evidence that glutamic acid may be the neurotransmitter released by granule cell parallel fibres.

Effects of D-alpha-aminoadipate on physiologically evoked responses of cat dorsal horn neurones

Microelectrophoretic administration of D-alpha-aminoadipate reversibly reduced excitatory responses of cat dorsal horn neurones evoked by iontophoretic glutamate and non-noxious peripheral stimuli but did not influence similar responses evoked by noxious peripheral stimuli or iontophoretic substance P.

L-glutamate specific [3H]kainic acid binding in the rat neostriatum after degeneration of the cortico-striatal pathway

Four weeks after lesion of the cortico-striatal pathway, the specific kainic acid binding was reduced by 20% in the neostriatum. It is concluded that the binding sites are most likely not located on cortico-striatal neurons. The displacement of kainic acid by some chemical indicates that the kainic acid binding site is different from the glutamate binding site, as defined iontophoretically.

Kainic acid and synaptic transmission in the stellate ganglion of the squid

Kainate, a conformational analogue of glutamate, blocks synaptic transmission across the giant synapse of the squid. In the presence of blocking doses of kainate, impulses continue to propagate into the nerve terminal, but action potentials are slightly reduced in size and the subsequent hyperpolarization is greatly diminished. Kainate depolarizes the postsynaptic axon. Since the depolarizing action of kainate is confined to the postsynaptic membrane, it appears that kainate can combine with the receptors which are normally activated by the transmitter. This results in a diminished effect of the transmitter released by a presynaptic nerve impulse.

Specific antagonism of excitant amino acids in the isolated spinal cord of the neonatal rat

The specificity of the neurodepressant actions of D-alpha-aminoadipate, alpha,epsilon-diaminopimelic acid, HA-966 (HAP) and Mg2+ has been investigated. On the isolated spinal cord of the neonatal rat, ventral root depolarizations produced by kainate, substance P, carbachol and noradrenaline were relatively unaffected by the same concentrations (0.25--1 mM) of the agents as those which reduced synaptic activity and ventral root depolarizations produced by N-methyl-D-aspartate (especially), L-aspartate and L-glutamate. The same or higher concentrations of the agents did not affect excitatory transmission in the isolated rat superior cervical ganglion. It is proposed that the agents specifically block synaptic transmission mediated by an excitatory amino acid.