The neurotoxic actions of quinolinic acid in the central nervous system

Excitotoxins such as kainic acid, ibotenic acid, and quinolinic acid are a group of molecules structurally related to glutamate or aspartate. They are capable of exciting neurons and producing axon sparing neuronal degeneration. Quinolinic acid (QUIN), an endogenous metabolite of the amino acid, tryptophan, has been detected in brain and its concentration increases with age. The content of QUIN in the brain and the activity of the enzymes involved in its synthesis and metabolism show a regional distribution. The neuroexcitatory action of QUIN is antagonized by magnesium (Mg2+) and the aminophosphonates, proposed N-methyl-D-aspartate (NMDA) receptor antagonists, suggesting that QUIN acts at the Mg2+ -sensitive NMDA receptor. Like its excitatory effects, QUIN's neurotoxic actions in the striatum are antagonized by the aminophosphonates. This suggests that QUIN neurotoxicity involves the NMDA receptor and (or) another receptor sensitive to the aminophosphonates. The neuroexcitatory and neurotoxic effects of QUIN are antagonized by kynurenic acid (KYN), another metabolite of tryptophan. QUIN toxicity is dependent on excitatory amino acid afferents and shows a regional variation in the brain. Local injection of QUIN into the nucleus basalis magnocellularis (NBM) results in a dose-dependent reduction in cortical cholinergic markers including the evoked release of acetylcholine. A significant reduction in cortical cholinergic function is maintained over a 3-month period. Coinjection of an equimolar ratio of QUIN and KYN into the NBM results in complete protection against QUIN-induced neurodegeneration and decreases in cortical cholinergic markers. In contrast, focal injections of QUIN into the frontoparietal cortex do not alter cortical cholinergic function.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kainic acid binding to membranes of striatal neurons.

The specific binding of [³H]-kainic acid to membrane fragments of rat striatum was examined. The specific binding was found to be saturable and of high affinity. The dissociation constant was about 71 nM, while the apparent maximal number of receptor sites was 254 fmoles/mg protein. [³H]-Kainic acid binding was effectively competed by both unlabeled kainic acid and glutamate, Lesions of the striatum by stereotaxic injection of 5 nmoles of kainic acid reduced the density of [³H]-kainic acid binding sites by half, without affecting their affinity. Lesions of the cortico-striatal afferents, however, did not affect the binding of [³H]-kainic acid, although sodium-dependent glutamate uptake was reduced by 30%. It is concluded that [³H]-kainic acid binds to a population of receptors localized on neurons of the caudate-putamen.     

Cellular neurophysiological actions of nociceptin/orphanin FQ

Cellular actions of nociceptin/orphanin FQ (N/OFQ) resemble those of micro-, delta-, and kappa-opioids, i.e. activation of inwardly rectifying K(+) conductance, inhibition of high-voltage-activated Ca(2+) channel currents, and impediment of neurotransmitter release. Differences in ORL(1) and micro-receptor distribution lead to: 1) more widespread actions of N/OFQ on periaqueductal gray neurons than opioids and 2) differential effects of N/OFQ and opioids in the brainstem. Also, unlike opioids, N/OFQ inhibits T-type Ca(2+) channel current in sensory neurons. Opioids and N/OFQ may modulate glutamate responses in different ways, and certain actions of N/OFQ are potentiated following nerve injury whereas those of micro-opioids are attenuated. Agonists at ORL(1) receptors may therefore be of clinical interest in the management of neuropathic pain.     

Reduction of brain taurine: Effects on neurotoxic and metabolic actions of kainate

The effects of chronic administration of 2-guanidinoethane sulfonic acid on the levels of intra- and extracellular amino acids in the rat hippocampus were studied. The tissue content of taurine was selectively reduced by almost one third after 9 days of peroral administration of 1% 2-guanidinoethane sulfonate. Extracellular levels of amino acids were monitored with the brain microdialysis method. The taurine concentration in the extracellular fluid was depressed in relation to the decrease in intracellular taurine. Unexpectedly, extracellular (but not intracellular) glutamate was doubled in 2-guanidinoethane sulfonate treated animals. The kainic acid evoked release of taurine was suppressed in the 2-guanidinoethane sulfonate group, whereas the kainate stimulated efflux of glutamate was elevated after 2-guanidinoethane sulfonate administration. The acute metabolic effects of kainate were studied by measuring the efflux of the adenosine triphosphate breakdown products hypoxanthine, xanthine, inosine and adenosine. No differences were found between control and 2-guanidinoethane sulfonate treated rats with respect to basal or kainic acid evoked release of purine catabolites. Also, the neuronal loss caused by kainate injection into the hippocampus was not modified by 2-guanidinoethane sulfonate treatment, suggesting that endogenous taurine does not affect these responses. We conclude that chronic administration of 2-guanidinoethane sulfonate does not sensitize central neurons to the metabolic and toxic actions of kainate.     

Corticosteroid actions from neuronal membrane to behavior: neurophysiological mechanisms underlying rapid behavioral effects of corticosterone.

Investigation of the rapid suppression of male courtship clasping behavior by corticosterone in roughskin newts (Taricha granulosa) has led to the identification of a specific neuronal membrane receptor for this stress steroid. This paper describes studies of the neurophysiological effects of the rapid, membrane receptor mediated action of corticosterone on neurons that are involved in the control of clasping. In freely behaving newts, medullary neurons, including reticulospinal neurons, process clasp-triggering sensory signals and participate in control of clasping movements. Corticosterone injection causes these brainstem neurons to show selective depression of clasping-related sensorimotor function. These corticosterone effects appear in 3-10 min and are closely associated with the simultaneous depression of clasping. In addition to these functionally specific effects, corticosterone simultaneously causes widespread, primarily depressive effects on neuronal activity and excitability in the medulla and elsewhere in the brain. Thus, the membrane actions of corticosterone lead to diverse neural effects, including changes in membrane excitability as well as specific, network-level actions that are apparent only during behavior. These rapid corticosterone effects strongly interact with actions of the neuropeptides vasotocin and corticotropin-releasing factor, such that the form and magnitude of the steroid's effects depend on the prevailing neuroendocrine state of the brain.     

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.     

Kainic acid depletes retinal phenylethanolamine-N-methyltransferase activity of rats

Kainic acid, an excitotoxic agent to the retina as well as to neuronal cell bodies in the brain, was administered intraocularly to rats in order to study the sensitivity of phenylethanolamine-N-Methyltransferase (PNMT) containing amacrine cells to this agent. Results show that these cells are very sensitive to the toxic effects of kainate. A dose of 5 nmoles caused a significant reduction in retinal PNMT activity. Higher doses further depleted enzyme activity.     

Kainic acid lesion-induced spatial memory deficits of rats

The effects of lesioning the ventral tegmental area (VTA) or substantia nigra (SN) neurons by means of bilateral stereotaxic microinjections of kainic acid (KA) (0.4 mM) were investigated to clarify the role of the VTA and the SN neurons in learning and memory processes. The present study demonstrates that KA in the SN and the VTA lesioned rats significantly decreased spontaneous alternation in Y-maze task, working memory and reference memory in radial 8 arm-maze task, suggesting effects on spatial memory performance. Our findings provide further support for the role of the VTA and the SN neurons in processing and storage of information.     

磷脂酸和溶血磷脂酸的生理功能

磷脂酸（phosphatidic acid,PA)和溶血磷脂酸（lysophosphatidic acid,LPA)是细胞内和细胞外信号转导的重要磷脂信号分子。它们主要通过磷脂酶D和磷脂酶C两条途径产生,并且PA在磷脂酶A2的催化下可水解生成LPA。越来越多证据表明,PA和LPA在细胞诸多生理功能中起重要作用。本文主要介绍PA和LPA的生理功能及作用机制的研究进展。     

磷脂酸和溶血磷脂酸的生理功能

磷脂酸(phosphatidic acid, PA)和溶血磷脂酸(lysophosphatidic acid,LPA)是细胞内和细胞外信号转导的重要磷脂信号分子.它们主要通过磷脂酶D和磷脂酶C两条途径产生,并且PA在磷脂酶A2的催化下可水解生成LPA.越来越多证据表明,PA和LPA在细胞诸多生理功能中起重要作用.本文主要介绍PA和LPA的生理功能及作用机制的研究进展.     

Differences in pharmacological actions between beta-bungarotoxin and other neurotoxic phospholipases A2 purified from snake venoms

Five highly toxic phospholipases A2 (PLAs) (beta-bungarotoxin, caudoxin, Mojave toxin, notexin and a basic PLA from Naja nigricollis venom) were compared for their pharmacological actions. In the chick biventer cervicis nerve-muscle preparation, all PLA toxins except beta-bungarotoxin (beta-BuTX) inhibited the postsynaptic acetylcholine response and induced contracture of the muscle at a high concentration. Indirect hemolytic activity was found in all PLA toxins and some of the toxins (Naja nigricollis basic PLA and Mojave toxin) even showed a potent direct hemolytic action, while beta-BuTX was devoid of both direct and indirect hemolytic activities on the guinea-pig erythrocytes. All PLA toxins except beta-BuTX caused an increase in muscle tone in the guinea-pig ileum at a concentration as low as 0.05 microgram/ml, and an increase in the contractile force in the guinea-pig atrium at a concentration of 1.0 microgram/ml. In contrast, beta-BuTX had no stimulant effect at concentrations up to 10 micrograms/ml. On the cultured cells, beta-BuTX suppressed the proliferation of neuroblastoma cells, but did not cause lysis of non-neuronal cells of the rat brain. However, beta-BuTX uniquely maintained a high population of viable cells in the neuroblastoma cell cultures. From these results it was concluded that beta-BuTX is the most specific presynaptic neurotoxin among the PLA toxins so far tested.     

Development of anuran locomotion: ethological and neurophysiological considerations.

There are dramatic quantitative and qualitative differences in the locomotor behavior of larval and juvenile frogs. Larvae (tadpoles) are primarily herbivourous and rely heavily on locomotion via undulations to acquire food and avoid predation. After metamorphosis, juvenile frogs adopt a carnivorous lifestyle and capture prey and avoid predators by remaining motionless in a place of concealment. When they must move, frogs locomote by means of ballistic hops or by more conventional walking. However, locomotion of both tadpoles and frogs can be considered of two fundamental functional types: (a) startle and escape; and (b) sustained locomotion. Neural mechanisms underlying startle responses and sustained locomotion in larvae and juveniles are described and possible ontogenetic relationships those behaviors are proposed. The role of different parts of the nervous system in the ontogeny of locomotion, as well as nonneuronal factors, are described. Results show that the transition from tadpole-like behavior to frog-like behavior is not a simple function of maturation of central locomotor controls. Rather, it results from a complex interaction of central nervous system maturation, morphological change, and a change in habitat preference. Examples of similar multidimensional control of behavioral ontogeny in other species are described, and it is argued that to understand the ontogeny of behavior, one must investigate contributions made at all levels, from the neuronal to the environmental.     

Modulation of amino acid neurotransmitter actions by other neurotransmitters: some examples.

Developments in the field of central neurotransmission indicate that amino acids serve as important and widespread transmitters throughout the central nervous system. There are increasing indications from recent experimental studies that several of the other central neurotransmitters may exert potent effects on central neurons by modulating the actions of amino acids. Noradrenaline and serotonin have received particular attention as potential modulators, and a wide variety of actions has been reported for them. Modulatory actions have been reported at both pre- and post-synaptic levels, including both short- and long-term effects and facilitation or inhibition of amino acid actions. Selectivity has been found both for specific receptor subtypes of the neuromodulator and for specific effects of amino acids. Examples of such selectivity are modification of actions of an amino acid with little effect on spontaneous activity or membrane properties of the target cell, or in comparison to the actions of other neurotransmitters, or even other selective amino acid analogs. Modulatory actions on amino acids have also been reported for several other neurotransmitters including acetylcholine and various peptides. Recent studies of angiotensin II demonstrate that when iontophoretically applied, it can potently and selectively block the depolarizing action of glutamate on locus coeruleus neurons. It is possible that physiological influences of these various transmitter substances are expressed through modification of amino acid actions, rather than through direct effects on central neurons.     

Real-time intraoperative neurophysiological monitoring.

We discuss the utilization of signal processing techniques during surgical procedures. These techniques are used to provide real-time monitoring of nervous system function. We describe the historical development of these techniques and the hardware and software that have been used to implement them.     

Chemical synthesis of N beta-oxalyl-L-alpha, beta-diaminopropionic acid and optical specificity in its neurotoxic action.

A practical procedure is described for the bulk synthesis of the neurotoxin N beta-oxalyl-L-alpha, beta-diaminopropionic acid (OA2pr3), a potential dicarboxylic amino acid antagonist of Lathyrus sativus seeds. L-Aspartic acid was reacted with sodium azide in 30% fuming sulfuric acid and L-alpha, beta-diaminopropionic acid hydrochloride (A2pr3-HCl) was isolated in yields greater than 75%. Potassium methyl oxalate was found to react selectively with the beta-amino group of S2pr3 resulting in near quantitative yields of OA2pr3. D-OA2pr3 has been made for the first time by this procedure. Unlike L-OA2pr3 the naturally occurring neurotoxin, D-OA2pr3, is not neuroactive even in high doses. The microsynthesis of L-[2,3-3H]A2pr3 from L-[2,3-3H]aspartic acid is also described, and the same procedure could also be used to prepare the neurotoxin with other labels. The availability of the neurotoxin in bulk and in labeled form should further experimental approaches to the understanding of its mechanism of action.     

Kainic acid increases activity only of some cortical neurons in the rat

The influence of a subconvulsant dose of kainic acid (KA) on the activity of neurons was studied in the sensorimotor cortical area of urethane-anesthetized rats. A total of 41 neurons was recorded, 38 of these in layer V (probably pyramidal cells). The activity of 18 neurons was recorded before as well as more than 30 min after KA administration (6 mg/kg i.p.). Nine out of these 18 neurons increased their firing rate significantly even 20 min after KA injection, whereas the remaining neurons did not change their activity. Altogether, the increase in the firing rate was significant. KA was found to enhance markedly the firing rate of a part of cortical neurons at very early stages of its action.     

Learning and memory: neurophysiological mechanisms

The analytical review of study of neurophysiological basis in different kinds of learning and memory in animal and human is given. The main attention is paid to the consideration of systemic and neuronal levels of habituation and conditioned reflexes. A conception on the brain functional state as the main mechanisms of learning and distributed multicomponent engram corresponding to the integrative process peculiarities is developed.     

Kainic acid as a tool for the study of temporal lobe epilepsy

Temporal lobe epilepsy (limbic epilepsy, complex partial epilepsy, psychomotor epilepsy) is the most devastating form of epilepsy commonly encountered in the adult population. The attacks involve loss of consciousness, thus limiting performance of normal functions and exposing the individual to bodily injury. Moreover, long-standing or pharmacologically intractable temporal lobe epilepsy is frequently associated with the loss of neurons from the hippocampus and other brain regions (Ammon's horn sclerosis (AHS)). Unfortunately, pharmacologically intractable cases are rather common, owing to the relatively low efficacy against this condition of the available anticonvulsants. Progress in the understanding and treatment of temporal lobe epilepsy would be greatly facilitated by the availability of an animal model which reproduced the behavioral, electrographic and pathological features of this condition. Here I review evidence which indicates that the kainic acid (KA)-treated rat possesses many of the features required of such a model.