Phylogenetic distribution of [3H]kainic acid receptor binding sites in neuronal tissue

Chronic subconvulsive activity during early postnatal life produces autistic behavior in the absence of neurotoxicity in the juvenile weanling period

The diagnosis of autism spectrum disorder (ASD) varies from very mild to severe social and cognitive impairments. We hypothesized that epigenetic subconvulsive activity in early postnatal life may contribute to the development of autistic behavior in a sex-related manner. Low doses of kainic acid (KA) (25-100 μg) were administered to rat pups for 15 days beginning on postnatal (P) day 6 to chronically elevate neuronal activity. A battery of classical and novel behavioral tests was used, and sex differences were observed. Our novel open handling test revealed that ASD males nose poked more often and ASD females climbed and escaped more frequently with age. In the social interaction test, ASD males were less social than ASD females who were more anxious in handling and elevated plus maze (EPM) tasks. To evaluate group dynamics, sibling and non-sibling control and experimental animals explored 3 different shaped novel social environments. Control pups huddled quickly and more frequently in all environments whether they socialized with littermates or non-siblings compared to ASD groups. Non-sibling ASD pups were erratic and huddled in smaller groups. In the object recognition test, only ASD males spent less time with the novel object compared to control pups. Data suggest that chronic subconvulsive activity in early postnatal life leads to an ASD phenotype in the absence of cell death. Males were more susceptible to developing asocial behaviors and cognitive pathologies, whereas females were prone to higher levels of hyperactivity and anxiety, validating our postnatal ASD model apparent in the pre-juvenile period.

Kainic acid: insights into excitatory mechanisms causing selective neuronal degeneration

Kainic acid, an acidic pyrolidine isolated from the seaweed Digenea simplex, is the most potent of the commonly used exogenous excitotoxins. The neurotoxic threshold of kainic acid is nearly two magnitudes lower than that of the other receptor-specific agonists, N-methyl-D-aspartic acid and quisqualic acid. Neurophysiological and ligand-binding studies indicate that the neurotoxic action of kainic acid is mediated by a specific receptor which exhibits a remarkably broad phylogenetic distribution in the nervous system of vertebrates and invertebrates. The mechanism of neurotoxicity of kainic acid appears to be indirect and requires the functional integrity of excitatory afferents to vulnerable neurons. Consistent with the excitotoxin hypothesis, kainic acid depletes high-energy phosphates and glucose at sites of neurotoxic action; nevertheless, the proximate cause of neurotoxicity may involve increases in intraneuronal calcium levels and the activation of calcium-dependent proteases. Kainic acid neurotoxicity provides a useful animal model for selective neuronal vulnerability that may shed light on the pathophysiology of a number of neurodegenerative disorders, including Huntington's disease and temporal lobe epilepsy.

Absence of neurotoxic effects in leopard sharks, Triakis semifasciata, following domoic acid exposure

Domoic acid (DA), a potent neurotoxin produced by select species of algae and diatoms, kills neurons bearing kainic acid-type glutamate receptors. Studies have shown that DA bioaccumulates in invertebrates and fish that consume the diatoms. In every vertebrate species tested or observed in the wild, dietary or systemic DA causes neuronal damage or clinical signs of neurotoxicity. Sharks, like marine birds and mammals, are exposed to DA through their diet; however, no research has demonstrated the effect of DA on shark behavior or physiology. In this study, juvenile leopard sharks (Triakis semifasciata) were given DA by intracoelomic injection at doses of 0, 1, 3, 9, and 27 mg/kg and observed for 7 days. The sharks failed to demonstrate behavioral or histological changes in response to the toxin. We identified putative brain glutamate receptors by probing western blots with an antibody specific for kainic acid-type glutamate receptors and demonstrated receptor localization in the cerebellum with immunohistochemistry. Blood levels of DA in three sharks dosed at 9 mg/kg fell rapidly within 1.5h of injection. We show that leopard sharks possess the molecular target for DA but are resistant to doses of DA known to be toxic to other vertebrates.

Characterization of a domoic acid binding site from Pacific razor clam

The Pacific razor clam, Siliqua patula, is known to retain domoic acid, a water-soluble glutamate receptor agonist produced by diatoms of the genus Pseudo-nitzschia. The mechanism by which razor clams tolerate high levels of the toxin, domoic acid, in their tissues while still retaining normal nerve function is unknown. In our study, a domoic acid binding site was solubilized from razor clam siphon using a combination of Triton X-100 and digitonin. In a Scatchard analysis using [3H]kainic acid, the partially-purified membrane showed two distinct receptor sites, a high affinity, low capacity site with a KD (mean +/- S.E.) of 28 +/- 9.4 nM and a maximal binding capacity of 12 +/- 3.8 pmol/mg protein and a low affinity, high capacity site with a mM affinity for radiolabeled kainic acid, the latter site which was lost upon solubilization. Competition experiments showed that the rank order potency for competitive ligands in displacing [3H]kainate binding from the membrane-bound receptors was quisqualate > ibotenate > iodowillardiine = AMPA = fluorowillardiine > domoate > kainate > L-glutamate. At high micromolar concentrations, NBQX, NMDA and ATPA showed little or no ability to displace [3H]kainate. In contrast, Scatchard analysis using [3H]glutamate showed linearity, indicating the presence of a single binding site with a KD and Bmax of 500 +/- 50 nM and 14 +/- 0.8 pmol/mg protein, respectively. These results suggest that razor clam siphon contains both a high and low affinity receptor site for kainic acid and may contain more than one subtype of glutamate receptor, thereby allowing the clam to function normally in a marine environment that often contains high concentrations of domoic acid.

AMPA/kainate receptors permeable to divalent cations in amphibian central nervous system

Glutamate receptors have been studied extensively in mammals but less explored in lower vertebrates. These receptors are present in amphibians. Using a recent method based upon agonist-induced cobalt uptake, we were able to detect the presence of functional alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/kainate receptors permeable to divalent cations in tadpoles and in adults. The uptake specificity was checked by co-application of an antagonist. We studied the distribution of receptor-bearing cells in the principal brain regions. The distribution was similar in the two species studied: Rana esculenta (green frog) and Bufo bufo (common toad). The high number of cobalt-positive cells suggests that the AMPA/kainate receptors permeable to divalent cations play an important role in the anuran nervous system.

CDNA cloning of chick brain alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid receptors reveals conservation of structure, function and post-transcriptional processes with mammalian receptors

Several types of functional ionotropic glutamate receptor have been cloned in the recent years from the mammalian central nervous system, but till now, none from other vertebrate species. Here, we report the cloning and functional analysis of four chick brain cDNAs, coding for members of the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor subtype of glutamate receptors. These receptors are highly homologous to the mammalian GluR1-4 (A-D) receptors ( > 90%), and conserve their post-transcriptional modifications. The flip/flop exons are conserved not only at the amino acid level but also at the nucleotide level, and the intron of GluR4 involved in the RNA editing of the R/G site displays a rat-chick sequence conservation of 95%. Significant sequence differences are found only in the region containing the immunogenic epitope of neuroactive anti-GluR3 antibodies. Chick AMPA receptors are expressed in both the cerebrum and cerebellum. The ion channel activities of chick GluR1-4 were analyzed in Xenopus oocytes and found to be similar to those of mammalian AMPA receptors. Though their contribution to kainate binding activity in the cerebellum is minor, the profile of channel activity of the chick GluR1-4 suggests that they account for the kainatergic channel activity expressed by total chick cerebellar mRNAs.

Kainate-binding proteins: phylogeny, structures and possible functions

Recent advances have demonstrated that the family of [3H]kainate-binding proteins and kainate receptors comprise a number of related polypeptides. In all the cases so far investigated, the kainate-binding proteins from non-mammalian vertebrates have M(r) values in the range of 40-50 kDa whereas mammalian kainate receptors and kainate-binding proteins have M(r) values in the order of 100 kDa. There have not, as yet, been any reports of 40-50 kDa kainate-binding proteins in mammalian CNS and, despite the cloning of increasing numbers of cDNAs encoding new kainate-binding proteins, the relationships between these two general groups of polypeptides remain unclear. Nonetheless, there is now a wealth of phylogenetic, structural and molecular biological data available about these proteins. In this review, Jeremy Henley outlines the properties and structures of kainate-binding proteins and offers some possibilities as to the roles of these often hugely abundant proteins.

Development of rapid and sensitive high throughput pharmacologic assays for marine phycotoxins

The lack of rapid, high throughput assays is a major obstacle to many aspects of research on marine phycotoxins. Here we describe the application of microplate scintillation technology to develop high throughput assays for several classes of marine phycotoxin based on their differential pharmacologic actions. High throughput "drug discovery" format microplate receptor binding assays developed for brevetoxins/ciguatoxins and for domoic acid are described. Analysis for brevetoxins/ciguatoxins is carried out by binding competition with [3H] PbTx-3 for site 5 on the voltage dependent sodium channel in rat brain synaptosomes. Analysis of domoic acid is based on binding competition with [3H] kainic acid for the kainate/quisqualate glutamate receptor using frog brain synaptosomes. In addition, a high throughput microplate 45Ca flux assay for determination of maitotoxins is described. These microplate assays can be completed within 3 hours, have sensitivities of less than 1 ng, and can analyze dozens of samples simultaneously. The assays have been demonstrated to be useful for assessing algal toxicity and for assay-guided purification of toxins, and are applicable to the detection of biotoxins in seafood.

Experimental seizures in the frog (Rana pipiens)

We investigated the effects of chemical convulsants in the leopard frog. Systemic kainic acid (5-20 mg/kg) caused limbic-like seizures, with staring, catatonia, fasciculations, and severe motor seizures, which were almost always lethal. Intracerebral electroencephalographic (EEG) recordings showed spike or spike-and-wave patterns at 6-8 Hz that decreased in frequency and increased in amplitude, maximal at an electrode in the midline olfactory/telencephalic (OLF-M) region. With time, an interictal pattern of 100-200 microV periodic spikes developed, followed by diffuse suppression of all brain activity. Seizures induced by pentylenetetrazole (150-450 mg/kg) and bicuculline (5-10 mg/kg) were characterized by the abrupt onset of motor activity, which continued intermittently for several hours, followed by recovery. EEG recordings in animals treated with pentylenetetrazole showed rhythmic spike-and-wave bursts at 1.5-3 Hz that were maximal at OLF-M. Recordings from frogs treated with bicuculline showed repetitive 3-6 Hz spike-and-wave discharges maximal at OLF-M that were nearly constant in amplitude and at times became continuous. Strychnine (1-5 mg/kg) caused reversible seizures characterized by tonic extensions of the extremities, that seemed to originate in the spinal cord. Frogs with recurrent seizures from systemic cis-diamminedichloroplatinum II showed 4-8 Hz rhythmic spike-and-wave activity that gradually slowed in frequency and increased in amplitude. Thus, the frog's reactivity to convulsive agents is similar to that of mammals.

Characterization of L-glutamate and kainate binding sites in the brain of a freshwater fish, Telapilia monsanbica

[3H]Kainate and L-[3H]glutamate binding sites in a rich source of kainate binding sites, fish brain, have been thoroughly analysed here for the purpose of studying the correlation between kainate binding sites and L-glutamate receptors in vertebrate CNS. The brain of a freshwater fish, Telapilia monsanbica, was found to contain three types of kainate binding sites: Type 1 sites (Kd = 1050 +/- 380 microM, Bmax = 4 +/- 4 pmol/mg), Type 2 sites (Kd = 133 +/- 20 nM, Bmax = 190 +/- 20 pmol/mg), and Type 3 sites (Kd = 23 +/- 15 nM, Bmax = 28 +/- 19 pmol/mg). The dissociation constants of L-glutamate to Type 1, 2 and 3 sites were, respectively, 0.28 +/- 0.04, 5.5 +/- 0.2 and 137 +/- 28 microM. Pharmacological characterization of these binding sites showed that Type 1 and 2 sites, respectively, corresponded to N-methyl-D-aspartate-subtype L-glutamate receptors and non-N-methyl-D-aspartate L-glutamate receptors. Autoradiographic studies showed that Type 1 and 2 sites were distributed widely in fish brain, indicating the involvement of L-glutamate receptors in various brain functions. Type 3 sites, on the other hand, were relatively insensitive to most endogenous amino acids and were only found in the molecular layer of cerebellum and torus longitudinalis. Type 3 sites possibly representing a distinctive class of receptor has been suggested by the results.

Structural characterization and expression of a brain specific gene encoding chick kainate binding protein

The gene encoding chick kainate-binding protein (c-KBP), a member of the non-NMDA ionotropic glutamate receptor family has been isolated and characterized. The c-KBP gene is at least 13 kilobases long and contains 11 exons interrupted by 10 introns. Primer extension and RNase protection studies identified a major transcription initiation site located 117 bases upstream from the initiation methionine codon ATG. Consensus TATA and CCAAT sequences were detected in the putative promoter region. The structure of the c-KBP gene is strikingly different from that of other members of neurotransmitter-gated ion-channels (cloned at present) although the topology of c-KBP consists of four membrane-spanning domains, a structural characteristic of ionotropic receptor subunits. The c-KBP gene was found to be expressed at high levels in chick cerebellar Bergmann glia and at extremely low levels in the forebrain. The limited expression of the c-KBP gene raises important questions concerning the mechanisms governing the regulation of c-KBP gene transcription.

Glutamic acid-insensitive [3H]kainic acid binding in goldfish brain

Kainic acid is supposed to be a specific agonist for a subclass of excitatory glutamate receptors in the vertebrate CNS. An investigation of (2 nM) [3H]kainic acid binding sites in goldfish brain, using quantitative autoradiography, has revealed evidence for two types of kainic acid receptors which differ in sensitivity to glutamic acid. L-Glutamic acid (0.1-1 mM) displaced over 95% of specific [3H]kainic acid binding elsewhere in the brain but only 10-50% in the cerebellum and cerebellar crest. These structures apparently contain [3H]kainic acid binding sites that are extremely insensitive to glutamic acid. The glutamic acid-insensitive [3H]kainic acid binding was not displaced by quisqualic acid, kynurenic acid, alpha-amino-3-hydroxy-5-methylisoxazolepropionic acid (AMPA), or N-methyl-D-aspartatic acid, but was completely displaced by the kainic acid analogue domoic acid. The data indicate that two types of high affinity binding sites for [3H]kainic acid exist in the goldfish brain: glutamic acid-sensitive and glutamic acid-insensitive. High affinity [3H]kainic acid binding may therefore not always represent binding to subsets of glutamic acid receptors.

Excitatory and inhibitory amino acid neurotransmitter binding sites in the cerebellar cortex of the pigeon (Columba livia)

We used receptor autoradiography to determine the distribution of excitatory and inhibitory amino acid neurotransmitter binding sites in the cerebellar cortex of the pigeon (Columba livia). alpha-Amino-3-hydroxy-5-methylisoxazole-4-propionic acid, kainate and metabotropic binding sites had highest levels in the molecular layer. N-methyl-D-aspartate binding sites, assayed with both [3H]glutamate under selective conditions and with [3H]glycine binding to the associated strychnine-insensitive glycine site, had highest levels in the granule cell layer. There was little specific binding of the non-competitive N-methyl-D-aspartate antagonist, [3H]MK-801. The level of gamma-aminobutyric acid (GABA)-A binding sites was higher than GABA-B binding sites in both molecular and granule cell layers with the highest level of GABA-A sites in the granule cell layer. The highest level of GABA-B binding sites was in the molecular layer. [3H]Flunitrazepam binding levels were approximately the same in both molecular and granule cell layers. With the exception of kainate binding sites, the distribution of binding sites was identical to that seen in the cerebellar cortex of mammals. Our results support the concept that the chemoarchitecture of the cerebellar cortex has been conserved in the course of vertebrate evolution.

Autoradiographic localisations of glutamatergic ligand binding sites in Xenopus brain

In the Xenopus central nervous system the binding sites for [3H]kainate and [3H]alpha-amino-3-hydroxy-5-methylisoxazolepropionate [( 3H]AMPA) are highly localised and the distributions of both ligands are largely coincident. The telencephalon was the most strongly labelled area with a relatively uniform distribution of binding sites. In addition, the infundibulum and the cerebellum were also heavily labelled. Areas containing a lower density of binding sites included the septum, the thalamus and the optic lobes. [3H]Kainate binding was potently inhibited by 1 microM AMPA in the presence of 0.1 M KSCN and [3H]AMPA binding was blocked by 1 microM kainate. These data are consistent with the hypothesis that kainate and AMPA bind to the same site on a single protein entity and that this unitary AMPA/KA binding protein may constitute the predominant type of excitatory amino acid receptor in the Xenopus brain.

Properties of kainate receptor/channels on cultured Bergmann glia

Following the localization, at the electron microscope level, of the immunoreactivity towards a putative kainate receptor on Bergmann glial cells in the chick cerebellar cortex, cultures of Bergmann glia were used to establish the presence of functional kainate receptor/channels and study their properties. Bergmann glia were identified by their fusiform morphology and their ability to bind an anti-kainate binding protein monoclonal antibody, a kainate receptor high affinity ligand--kainyl-bovine serum albumin--and a glial marker--anti-vimentin monoclonal antibody. Membranes prepared from the culture cells displayed, using 25 nM [3H]kainate, the binding of 4.1 pmol of [3H]kainate/mg protein and showed the presence in Western blots of the two polypeptides of 49 and 93 kDa attributed to the kainate binding protein. Kainate, at concentrations above 0.1 mM, was found to increase the influx into cultured Bergmann glia of 22Na+, 86Rb+, 45Ca2+ and 36Cl- ions. The traffic of 22Na+, induced by kainate and glutamate, observed only in the presence of 1 mM ouabain, was blocked by kainate receptor antagonists and by 0.01 mM quisqualate. Analysis of the kinetics of incorporation of 22Na+ and 45Ca2+ ions showed an initial accumulation of 22Na+ and 45Ca2+ ions followed by their total dissipation. The results indicate that the kainate-induced influx of Na+ ions through the kainate receptor/channel causes the reverse transport of Na+ ions, by activation of the Na+/Ca2+ and Na+/H+ exchangers which remove intracellular Na+ ions. Pre-exposure of the cells to 0.5 mM dibutyryl cAMP was found to greatly enhance the kainate-induced 22Na+ ion influx. We propose that the Bergmann glia kainate receptors modulate the efficacy of the glutamatergic synapses between the parallel fibers and Purkinje cell spines and form part of a glial machinery responsible for plastic changes in synaptic transmission.

The distribution of excitatory amino acid binding sites in the brain of an electric fish, Apteronotus leptorhynchus

The distribution of three types of exitatory amino acid receptors was examined in the brain of a high frequency weakly electric fish, Apteronotus leptorhynchus, by localizing the binding sites of ligands selective for mammalian kainic acid (KA), quisqualate (AMPA) and N-methyl-D-aspartate (NMDA) receptors. All three binding sites were densest within the forebrain and in certain hypothalamic nuclei (nucleus tuberis anterior, inferior lobe). The core of the dorsal forebrain (dorsal centralis) had a very high density of NMDA binding sites and only moderate levels of AMPA and KA binding sites, while this was reversed for the dorsolateral forebrain. The AMPA and NMDA binding sites were found throughout the brain while KA binding sites were relatively restricted and were absent from most of the brainstem. The cerebellar molecular layer contained a very high density of KA and AMPA binding sites but almost no NMDA binding sites; the granular layer had a low density of AMPA and NMDA binding sites but was lacking in KA binding sites. All three types of binding sites were found within the electromotor system (nucleus electrosensorius and prepacemaker nucleus) at sites where the iontophoresis of glutamate causes species-specific behaviours. KA binding sites were found at only two sites along the electrosensory afferent pathways: (1) in the molecular layer of the electrosensory lateral line lobe, associated with a feedback pathway emanating from granule cells of the overlying cerebellum, and (2) in the lateral nucleus praeminentialis dorsalis, associated with a descending pathway emanating from the torus semicircularis. NMDA and AMPA binding sites are found throughout the electrosensory pathways. Within the electrosensory lateral line lobe the NMDA binding sites were predominantly associated with the feedback pathways terminating in its molecular layer and not with the deep neuropil layer containing primary electroreceptor afferents.

Synaptic receptors and intracellular signal transduction in the cerebellum

Glutamate receptor subtypes mediating excitatory synaptic neurotransmission in the cerebellar cortex are briefly reviewed from molecular biological, electrophysiological and pharmacological points of view. In particular, molecular biological findings of a novel family of AMPA-selective glutamate receptors are introduced, and the pharmacological and electrophysiological properties and the identity of cerebellar N-methyl-D-aspartate-sensitive receptors probably existing on Purkinje cells are discussed in comparison with well-established cerebral NMDA receptors. As possible intracellular mechanisms of the long-term depression of parallel fiber-Purkinje cell neurotransmission, the perspective of the roles of novel messengers, nitric oxide and arachidonic acid, is particularly commented based on recent information about cerebral long-term events. The specificity and possible independence of cerebellar excitatory amino acid receptors and linked intracellular second messengers are also suggested, taking the highly active guanylate cyclase system in Purkinje cells and other cerebellum-specific proteins into consideration.

Sensitivity of hippocampal neurones to kainic acid, and antagonism by kynurenate

1. The sensitivity to kainic acid of neurones in the CA1 and CA3 regions of rat hippocampal slices has been examined by microiontophoresis and by superfusion methods. 2. When the iontophoretic currents needed to produce comparable plateaux of firing were compared, neurones in the pyramidal cell layer of the CA3 region were approximately 5 times more sensitive than cells in the CA1 region. No difference was noted in sensitivity to N-methyl-D-aspartate (NMDA) or quisqualate. 3. When kainate was superfused at known concentrations, the threshold for eliciting excitation in CA1 was 2.1 microM. The threshold concentration in CA3 was 0.24 microM. 4. Two weeks after the stereotaxic intrahippocampal injection of colchicine, the granule cells of the dentate gyrus and thus the mossy fibre projections to CA3 were destroyed. In slices prepared from animals thus treated the threshold concentration of kainate for eliciting excitation had risen to 1.64 microM. 5. Kainate was less effective in promoting the development of epileptiform bursts of neuronal firing in colchicine-treated slices than in controls. 6. Kynurenic acid antagonized the excitation of CA1 neurones elicited by kainate, NMDA or quisqualate. In the CA3 region kynurenate antagonized selectively responses to microiontophoretic NMDA, with little effect on responses to kainate or quisqualate. 7. In slices taken from colchicine-treated rats kynurenate was able to block responses to kainate in the CA3 area in parallel with responses to NMDA. 8. Taken together the results suggest that the excitatory responses to kainate in the CA3 region may be partly due to a presynaptic action on mossy fibre terminals to release endogenous amino acids. The differential action of kynurenate in normal and lesioned slices may, therefore, indicate that the postsynaptic kainate receptors are sensitive to antagonism by this compound whereas the presynaptic receptors are resistant to kynurenate.

[3H]kainate localization in goldfish brain: receptor autoradiography and membrane binding

The anatomical distribution of specific [3H]kainate binding in goldfish brain was investigated by membrane binding and autoradiographical techniques. Saturation binding of the radioligand was determined in 8 anatomically defined regions and demonstrated a single class of high affinity sites with Kd values ranging from 290 to 650 nM. Kainate receptor densities, however, varied significantly. The cerebellum contained the highest concentration of binding sites (964 pmol/mg prot.), while the optic tectum had the lowest (96 pmol/mg prot.). Binding site distributions determined by autoradiographic studies demonstrated the same regional variation and allowed more specific localization of the binding sites. Within the cerebellum, the molecular layers of the corpus, valvula and lobus caudalis displayed a uniform and highly intense image while the granule cell layers (except for the medial granule cell mass of the lobus caudalis) did not. Other areas of intense binding were the posterior tubercle of the diencephalon, inferior lobes of the hypothalamus and layers 1 and 2 of the optic tectum (deep to the periventricular granule cells).

A competitive inhibitor of kainic acid binding from the goldfish nervous tissue

An inhibitor of the receptor binding of the neuroexcitant kainic acid was extracted from the nervous tissue of the goldfish and purified. The substance acts as a competitive inhibitor (displacer) on the kainate binding sites in membranes from the fish nervous system; this action is selective since the substance does not affect the membrane binding of glutamate, the common ligand for the excitatory amino acid binding sites. The interaction of the substance with the fish kainate binding sites displays a positive cooperativity, similar to that measured for kainic acid itself. Thus the endogenous kainate binding inhibitor (KBI) can be assumed as a candidate for the role of physiological ligand of receptors for kainic acid in the fish. The substance, at the tested concentration, does not significantly affect the binding of kainic acid in membranes from rat brain while it is active on the sites from the pigeon cerebellum. The relevance of these findings for the understanding of the functional heterogeneity of the kainate receptors in different species is discussed.

Pharmacological characteristics and distributions of sigma- and phencyclidine receptors in the animal kingdom

The phylogenetic distributions of sigma- and phencyclidine receptors in neural tissues of 13 species and the pharmacological characteristics of these receptors in whole sea anemone and neural tissues of the guinea pig, chicken, and frog were studied. Specific binding of [3H]haloperidol and [3H]N-[1-(2-thienyl)cyclohexyl]-3,4-piperidine, ligands that bind with high affinity to sigma- and phencyclidine receptors, respectively, was detected in all organisms examined. The order of potencies of various ligands to inhibit 1 nM [3H]haloperidol binding in brains of frogs and guinea pigs or 1 nM [3H]N-[1-(2-thienyl)cyclohexyl]-3,4-piperidine in chicken or guinea pig brain homogenates was very similar. However, the characteristics and stereospecificity of binding of the two radioligands in sea anemone were different than in higher organisms. The results suggest that sigma- and phencyclidine binding sites are evolutionarily old, as the characteristics of the two sites are well preserved over a range of vertebrate phyla.

Ontogeny of binding sites for [3H] kainic acid in chick and rat cerebellar membranes: a comparative study

We have analyzed the developmental properties of kainate receptors in cerebellar membranes prepared from chick and rat, two vertebrate species with contrasting patterns of functional maturation. Single populations of binding sites have been characterized in the avian and rodent membranes with apparent dissociation constants (Kd) in the 210-280 nM and 40-55 nM ranges, respectively; the number of binding sites (Bmax) increases with age in both species, reaching a maximum of 187 pmol/mg in the case of 10-day chicks vs. 1.28 pmol/mg in 75-day rats. The ontogenetic profiles of kainate receptors in chick and rat cerebella are in consonance with the patent differences in motor development at birth.

Subcellular localization of a putative kainate receptor in Bergmann glial cells using a monoclonal antibody in the chick and fish cerebellar cortex

A monoclonal antibody, IX-50, that was raised against a kainate binding protein (Mr = 49,000) from chicken cerebellum, was used in light and electron microscopic immunocytochemical studies to localize putative kainate receptors. Pre- and postembedding immunoperoxidase and immunogold methods were used in the cerebellar cortices of one to 26-day old chickens and adult rainbow trout. Immunoreactivity was detected only in association with Golgi epithelial/Bergmann glial cells. Intracellular immunoreactivity was present in the granular and agranular endoplasmic reticulum, Golgi apparatus and in lysosomes, representing the sites of synthesis, glycosylation and degradation of the protein. In the fish the granular endoplasmic reticulum was not immunoreactive. Extracellular immunoreactivity was associated with the plasma membrane. In the fish it was established that the epitope is on the outer surface of the membrane. The protein seems to be uniformly distributed along the membrane including the somata, the radial stem processes and the leafy lamellae surrounding Purkinje cell dendrites. Areas of the glial membrane in contact with other glial cells were also immunopositive. High-resolution light microscopy demonstrated all the Bergmann glial plasma membrane in the cortex, providing a "negative" image of Purkinje cell dendrites. It is apparent that Bergmann glial processes selectively outline the dendrites of the Purkinje cells by surrounding the parallel fibre terminal/Purkinje cell spine synaptic complexes. The parallel fiber terminals were highly immunoreactive for glutamate, as shown by an immunogold procedure. The association of Bergmann glial processes, carrying the Mr = 49,000 kainate binding protein, with the Purkinje cell dendrites and spine synapses could provide a basis for neuronal signalling to the Bergmann glia, possibly by glutamate.

Molecular structure of the chick cerebellar kainate-binding subunit of a putative glutamate receptor

Kainate receptors mediate some of the excitatory transactions carried out in the central nervous system by the neurotransmitter glutamate. They are involved in neurotoxicity, possibly in neurodegenerative disorders and it has been suggested that they have a role in long-term potentiation. Kainate receptors are present both on neuronal and glial cell membranes where they regulate the gating of a voltage-independent ion channel. Nothing is known about their molecular structure. Taking advantage of the unusually high abundance of 3H-kainate binding sites in the chick cerebellum, we have isolated an oligomeric protein that displays a pharmacological profile similar to that of a kainate receptor, and have demonstrated, using the monoclonal antibody IX-50, that this protein is composed of a single polypeptide of Mr 49,000 which harbours the specific kainate recognition site. The structure of this kainate binding protein (KBP) is also of interest because of its exclusive cerebellar localization on Bergmann glial membrane in close proximity to established glutamatergic synapses. We now report the isolation of the complementary DNA containing the complete coding region of the kainate binding protein. The predicted structure of the mature protein has four putative transmembrane domains with a topology analogous to that found in the superfamily of ligand-gated ion channels. This raises the possibility, that kainate binding protein may form part of an ion channel and may be a subunit of a kainate subtype of glutamate receptor.

Kainyl-bovine serum albumin: a novel ligand of the kainate sub-type of glutamate receptor with a very high binding affinity

Bovine serum albumin has been conjugated with kainylaminooxyacetylglycine to afford a multivalent kainylated protein called kainyl-bovine serum albumin (KA-BSA). This derivative, radiolabelled with 125I to more than 5000 Ci/mmol, was found to interact in the chick, goldfish and rat brain to specific membranous sites displaying the pharmacological properties attributed to the kainate sub-type of glutamate receptor. Measurements of the kinetics of association and dissociation of KA-BSA showed a quasi-irreversible binding with dissociation constants in the subpicomolar and nanomolar range. The chemical properties and the binding characteristics of KA-BSA suggest that it interacts mainly with kainate binding sites present in clusters in the membrane. Localization of the KA-BSA binding sites, by autoradiography in the chick cerebellum and by immunoperoxidase staining in the goldfish cerebellum, revealed an exclusive association with the molecular layer.

[3H]kainic acid binding sites in chick cerebellar membranes

1. A total particulate fraction of chick cerebellar membranes, obtained by a simple method, has been found to specifically bind [3H]kainic acid. Non-neuronal tissue, like chick liver, does not show any appreciable specific binding under the same experimental conditions. 2. Specific [3H]kainic acid binding to chick cerebellar membranes increases linearly with tissue concentration, reaches the binding equilibrium almost instantaneously and is pH and temperature dependent. 3. Specifically bound [3H]kainic acid is displaced by suitable concentrations of unlabelled kainic acid, L-glutamic acid and other excitatory amino acid analogues, both agonist and antagonist. This pharmacological pattern agrees with the general pharmacological properties of kainic acid receptors. 4. Saturation kinetic studies of kainic acid binding sites show one single binding mode with an apparent dissociation constant KD = 278 nM and a maximum number of binding sites of 187 pmoles/mg of protein. 5. In view of the mentioned data and the high amount of receptor sites found in chick cerebellar membranes, as compared with related values in rat cerebellum, we suggest that these receptors play a different physiological role or that they have a different cellular localization in chick and rat cerebellum.

Kainate receptors in Xenopus central nervous system: solubilisation with n-octyl-beta-D-glucopyranoside

[3H]Kainate binding to membrane homogenates and detergent extracts prepared from Xenopus central nervous system was evaluated in 50 mM Tris-citrate buffer, pH 7.0. In membrane fragment preparations, [3H]kainate bound with a KD of 54.4 nM to a large number of sites (Bmax = 27.8 pmol/mg of protein). Up to 80% of the total number of membrane-bound binding sites were solubilised using the nonionic detergent n-octyl-beta-D-glucopyranoside. Values for the KD of [3H]kainate for solubilised binding sites were 46.0 nM and 53.6 nM derived from equilibrium and kinetic binding experiments, respectively. Competitive binding studies revealed that a variety of ligands had similar Ki values in both membranes and solubilised extracts, with domoate and kainate being the most potent inhibitors of [3H]kainate binding. The dissociation rate of [3H]kainate from solubilised binding sites was 0.022 min-1. The binding component migrated in sucrose density gradients in a single 8.6S peak. These results demonstrate that the kainate receptor in Xenopus central nervous system, although similar to the [3H]kainate binding site from goldfish brain, differs in a number of important respects. In particular, the slower dissociation rate and higher affinity of [3H]kainate suggest that Xenopus provides the most convenient model system yet investigated for biochemical analysis of kainate receptors.

A kainate binding protein in pigeon cerebellum: purification and localization by monoclonal antibody

A monoclonal antibody (mAb) was developed which precipitated kainate binding activity from detergent extract of pigeon cerebellum and was used to isolate a kainate binding protein (KBP) by immunoaffinity chromatography. It migrated at an apparent molecular weight (Mr) of 220,000 in gel filtration chromatography and at Mr = 50,000 in polyacrylamide gel electrophoresis performed under denaturing and reducing conditions. Moreover, the mAb produced an immunohistochemical staining pattern in the molecular and Purkinje cell layers which corresponded to the autoradiographic labeling pattern observed with tritiated kainate and were reported to be typical of the major kainate binding site in the pigeon cerebellum.

Solubilization and characterization of kainate receptors from goldfish brain

The binding of [3H]kainate to goldfish brain membrane fragments was investigated. Scatchard analysis revealed a single class of binding sites in Tris-HCl buffer with a Kd of 352 nM and a Bmax of 3.1 pmol/mg wet weight. In Ringer's saline, [3H]kainate bound with a Bmax of 1.8 pmol/mg wet weight and a Kd of 214 nM. Binding in Ringer's saline, but not Tris-HCl buffer, displayed positive cooperativity with a Hill coefficient of 1.15. The [3H]kainate binding sites were solubilized in Ringer's saline using the nonionic detergent n-octyl-beta-D-glucopyranoside. Approximately 30-50% of the total number of membrane-bound binding sites were recovered on solubilization. The Kd of [3H]kainate for solubilized binding sites was approximately 200 nM. The rank order of potency for glutamatergic ligands at inhibiting [3H]kainate binding was identical and the competitive ligands had similar Ki values in both membranes and solubilized extracts. In membrane preparations, [3H]kainate displayed a two component off-rate with koff values of 0.97 min-1 and 0.07 min-1; in solubilized extracts, however, only a single off-rate (koff = 0.52 min-1) was observed. The hydrodynamic properties of n-octyl-beta-D-glucopyranoside solubilized [3H]kainate binding sites was investigated by sucrose density centrifugation. A single well defined peak was detected which yielded a sedimentation coefficient of 8.3 S. The results presented in this report suggest that goldfish brain may provide an ideal system in which to study kainate receptor biochemistry.

Solubilization of kainic acid binding sites from rat brain

Kainic acid binding sites were solubilized from rat brain using a combination of Triton X-100 and digitonin. The highest percentage of solubilized binding sites (45%) was obtained by treating brain membranes with 1% Triton-X-100 and 0.2% digitonin in 0.5 M potassium phosphate containing 20% glycerol. The solubilized binding sites were stable and amenable to analysis by gel filtration and lectin affinity chromatography. Computer assisted analyses demonstrated that the solubilized sites displayed high- and low-affinity binding constants similar to the membrane-bound sites. Competition experiments further supported the pharmacological similarities of the solubilized and membrane-bound sites. Gel filtration chromatography of the solubilized binding site indicated that the detergent-bound complex had a Stokes radius of 82.7 A. The [3H]kainic acid binding site appears to be glycosylated based on its capability to bind to lectins. The lectin, wheatgerm agglutinin, proved to be a potentially useful tool for characterization because the solubilized binding sites were bound and eluted in relatively high yield.

Kainate binding sites in the hippocampal mossy fibers: localization and plasticity

The regional distribution of high affinity binding sites for kainic acid has been determined in rat hippocampi by quantitative autoradiography. Selective lesions were made in order to determine the exact localization of these sites in the mossy fiber system, and to evaluate whether the sprouting and synaptic reorganization of the mossy fibers are associated with alterations in the distribution of these binding sites. The results show that kainate binding sites in the stratum lucidum are more vulnerable to destruction of the granules and their mossy fibers by intrahippocampal colchicine injections than to destruction of the CA3/CA4 pyramidal cells by injection of kainate into the amygdala. This suggests that a substantial proportion of the kainate binding sites is associated with the mossy fiber terminals (i.e. the presynaptic elements). Furthermore, in keeping with an earlier study, destruction of the pyramidal neurons of CA3 by intracerebral kainate produced a dark Timm positive band in the supragranular zone which is due to the sprouting of mossy fibers. This was associated with an increase in the density of kainate binding sites, which further stresses the parallelism between the distribution of these sites and mossy fiber terminals.

The distribution of [3H]kainate binding sites in primate hippocampus is similar to the distribution of both Ca2+-sensitive and Ca2+-insensitive [3H]kainate binding sites in rat hippocampus

The distribution of [3H]kainate binding sites was determined by quantitative autoradiography in three vertebrate species: rat, monkey, and human. These animals displayed a similar pattern of binding site density in the hippocampus. Highest levels were found within the stratum lucidum and moderate levels in the inner portion of the dentate gyrus molecular layer. Although the distribution is similar, there is a lower density of binding sites in the stratum lucidum of primates than in rodents. Experiments using rat brain synaptic plasma membrane fractions indicated that inclusion of Ca2+ ions results in a selective reduction in binding at the high affinity sites. The Ca2+-inhibited and Ca2+-inhibited binding sites in the high affinity sites. The Ca2+ -inhibited and Ca2+ -insensitive binding sites in the rat hippocampus exhibited a similar distribution. Together, these results suggest that in a variety of mammalian species kainate receptors exhibit similar regional distributions, and that the high and low affinity kainate binding sites also exhibit similar regional distributions.

Distribution of kainic acid receptor binding sites in the goldfish CNS: evidence for the existence of intracellular sites

The density of binding sites for kainic acid was measured both in fresh slices and in the particulate fraction of the homogenate from various zones of the CNS of goldfish. Binding in the homogenate fraction was always found higher than in the corresponding slices, which should be representative of receptors located on the outer surface of the cellular membrane. The hypothesis is discussed that the sites demonstrated by homogenization are located in the intracellular compartment.

The binding properties and regional ontogeny for [3H]glutamic acid Na+-independent and [3H]kainic acid binding sites in chick brain

The binding kinetics, pharmacological properties and regional ontogeny of L-[3H]glutamic acid Na+-independent and [3H]kainic acid binding sites were studied in preparations of chick brain. One binding component was found for L-[3H]glutamic acid with a Kd value of 176 x 10(9) M. For [3H]kainic acid two binding components were found in the hemispheres, optic lobes and brain stem, one with high affinity and a Kd value of 12.5 x 10(9) M and one with low affinity and a Kd value of 260 x 10(9) M. In cerebellum only one binding site was detected for [3H]kainic acid with a Kd value of 144 x 10(9) M. The ontogeny of L-[3H]glutamic acid and [3H]kainic acid binding sites was studied using membrane preparations (48,000 g pellet) of hemispheres, optic lobes, brain stem and cerebellum. Binding of L-[3H]glutamic acid was already significant in all brain regions by embryonic day 11 but major increases in total receptor number per brain region or per mg of protein were apparent by embryonic day 19 and especially after hatching. Cerebral hemispheres, optic lobes and brain stem showed few [3H]kainic acid binding sites by day 13 in ovo. An increase follows which, in hemispheres and optic lobes, continues at the same rate during the first two weeks after hatching. In cerebellum, by contrast, the kainic acid binding site is almost undetectable until embryonic day 15. The appearance of these binding sites in cerebellum takes place during the restricted period between days 15 in ovo and 5 post-hatching. This pattern of development of [3H]kainic acid binding sites almost parallels the developmental patterns of the molecular layer of chick cerebellum and it is consistent with the results of our autoradiographic study showing that the great majority of kainic acid binding sites are localized in the molecular layer.

[3H] kainic acid binding sites in the synaptosomal-mitochondrial (P2) fraction from goldfish brain

Binding of [3H]kainic acid to the synaptosomal-mitochondrial fraction (P2) of the goldfish brain was studied. Specific binding to this fraction represents about half of the total binding capability of the homogenate particulate material and is enriched in synaptic membranes; it is greater by about two orders of magnitude than those given for rat brain and pigeon optic tectum membranes. Association of the ligand-site complex has a time constant lower than 1 min and the same is true for the main component of the dissociation process. The binding equilibrium is apparently not affected by substances contained in the fraction material. The analysis of the dose-response data showed a main receptor population (B max = 139 pmol/mg protein) which displayed positive cooperativity (nH = 1.29). The same behaviour was shown by washed membranes from the same fraction but, in this case, the affinity for the ligand was lower (apparent affinity constants: K'D = 0.28 nM for the intact fraction and K'D = 0.38 nM for membranes). A smaller population of sites with higher affinity was also detected both in the intact fraction and in membranes. Among the substances tested as displacers of kainic acid from the synaptosomal sites, the most effective were quisqualate and L-glutamate. Folic acid and its dihydro and tetrahydro derivatives were half as potent as glutamate whereas methyltetrahydrofolic acid and folinic acid had a very weak action. The difference between these sites and those detected on rat brain membrane preparations is discussed.

Kainic acid differentially affects the synaptosomal release of endogenous and exogenous amino acidic neurotransmitters

Presynaptic actions of kainic acid have been tested on uptake and release mechanisms in synaptosome-enriched preparations from rat hippocampus and goldfish brain. Kainic acid increased in a Ca2+-dependent way the basal release of endogenous glutamate and aspartate from both synaptosomal preparations, with the maximum effect (40-80%) being reached at the highest concentration tested (1 mM). In addition, kainic acid potentiated, in an additive or synergic way, the release of excitatory amino acids stimulated by high K+ concentrations. Kainic acid at 1 mM showed a completely opposite effect on the release of exogenously accumulated D-[3H]aspartate. The drug, in fact, caused a marked inhibition of both the basal and the high K+-stimulated release. Kainic acid at 0.1 mM had no clear-cut effect, whereas at 0.01 mM it caused a small stimulation of the basal release. The present results suggest that kainic acid differentially affects two neurotransmitter pools that are not readily miscible in the synaptic terminals. The release from an endogenous, possibly vesiculate, pool of excitatory amino acids is stimulated, whereas the release from an exogenously accumulated, possibly cytoplasmic and carrier-mediated, pool is inhibited or slightly stimulated, depending on the external concentration of kainic acid. Kainic acid, in addition, strongly inhibits the high-affinity uptake of L-glutamate and D-aspartate in synaptic terminals. All these effects appear specific for excitatory amino acids, making it likely that they are mediated through specific recognition sites present on the membranes of glutamatergic and aspartatergic terminals. The relevance of the present findings to the mechanism of excitotoxicity of kainic acid is discussed.

Effects of bath-applied excitatory amino acids and their analogs on spinal interneurons of the lamprey

Depolarizations, conductance increases and time courses of the responses to bath application of glutamate, aspartate, DL-homocysteate, N-methyl-DL-aspartate (NMDLA), quisqualate and kainate were determined in interneurons of the isolated spinal cord of the lamprey, one of the most primitive vertebrates. Conductance increases produced by these excitants in perfusate containing tetrodotoxin (0.5 microgram/ml), 4-aminopyridine (1 mM) and without Ca2+ were very small in comparison with those produced by glycine or GABA. NMDLA-induced depolarizations were associated with conductance decreases and rhythmic oscillations in membrane potentials in this perfusate. Quisqualate was strongest among these amino acids in producing depolarizations and conductance increases. Responses induced by analogs were slower than those produced by glutamate and aspartate. Phylogenetic distribution of N-methyl-D-aspartate receptors on neurons and muscles is discussed.

Especial considerations for neurotoxicological research

In recent years, there has been much impetus toward a definition of behavior in terms of underlying biological events. Such correlations have been attempted in several areas ranging from learning and memory to neurological disease. Increased information concerning the relation between behavior and neurobiological mechanisms is especially important in the area of neurotoxicology. It is often abnormal behavior that is a first sign of exposure to a neurotoxic agent and such changes may give clues as to the anatomical or chemical sites of attack on the nervous system. These clues might also lead to the development of a therapeutic treatment as to the development of tests designed to reveal exposure to a toxic agent at levels below those causing gross behavioral change. Unfortunately, there is a relatively small amount of literature reporting on both behavioral and biological disturbances caused by a toxic agent in the same experimental animal. However, a variety of methodological advances combined with a growing interest in neurotoxicology is gradually changing this. Increased information concerning the role of defined nerve pathways and the means of action of their chemical constituents offers an opportunity to bring about a deepening understanding of neurotoxic events. This review will suggest how new pharmacological findings can be applied to neurotoxicology. Examples of human and animal exposure to toxic materials will be used and current problems will be shown to be major determinants of future research directions.

Maturation of kainic acid seizure-brain damage syndrome in the rat. III. Postnatal development of kainic acid binding sites in the limbic system

The progressive appearance of [3H]kainic acid binding sites with age has been studied in membrane suspensions prepared from various regions of the rat limbic system, and by autoradiography. Binding sites with fast dissociation rate appeared earlier than binding sites with slow dissociation rate. Scatchard analysis demonstrated apparent receptor heterogeneity for both subclasses. High affinity components were detected in the hippocampus as early as 10 days after birth, but in the amygdala + piriform lobe were found only towards the end of the third week, when animals also respond to parenteral kainic acid, for the first time, with limbic seizures accompanied by metabolic activation of the amygdala. Slice autoradiography revealed distinct labelling of the hippocampal CA3 region by postnatal day 10. A comparison with the ontogenesis of the kainic acid-induced seizure-brain damage syndrome suggests a role of high affinity receptors as mediators of metabolic nerve cell activation by kainic acid. However, this receptor interaction per se does not result in neuronal damage to the vulnerable region of the Ammon's horn, which will only occur at an age when also the amygdala is activated by the neurotoxin.

Are convulsant and toxic properties of folates of the kainate type?

Intra-amygdaloid injections of folic acid (FA) in rats induce behavioural, metabolic (assessed using the 2-deoxyglucose method) and neuropathological changes which, however, differ considerably from those produced by kainic acid (KA). Thus FA, in contrast to KA, does not readily induce limbic motor seizures, fails to activate the entire limbic system and does not readily reproduce the local and distant damage induced by KA, notably in the Ammon's horn of the hippocampus. The results argue against the hypothesis that KA acts at folate receptors to induce its limbic epileptic/brain damage syndrome.

Benzodiazepine selectively antagonize kainate-induced activation in the rat hippocampus

Low intravenous doses of two benzodiazepines, lorazepam and diazepam, antagonized the activation of dorsal hippocampus CA1 pyramidal neurons by kainate to a greater extent than the activations produced by glutamate and acetylcholine. A similar effect was obtained with microiontophoretic application of two water-soluble benzodiazepines, flurazepam and chlordiazepoxide. Chlorpromazine and phenobarbital did not exert any consistent effect on kainate-induced activation. RO 15-1788, a benzodiazepine antagonist, prevented the effect of lorazepam on kainate-induced activation. The regional selectivity of this effect was indicated by the failure of lorazepam to produce a sustained reduction of kainate action in the CA3 hippocampal region and in the cerebral cortex. This selective antagonism by benzodiazepines of the excitation of selected limbic neurons via 'kainate-sensitive' receptors might be related to their anxiolytic effect.

Autoradiographic visualization of [3H]kainic acid receptor subtypes in the rat hippocampus

Unfixed, slide-mounted tissue sections from the rat forebrain have been incubated in the presence of 20 and 100 nM [3H]kainic acid ([3H]KA). For the last 2 min of incubation, 10 micrometers unlabelled KA was added to displace [3H]KA from binding sites with high on-off rate. Washed and dried slices were exposed on [3H]Ultrofilm for 178 days. Our results confirm the high density of KA receptors in the terminal field of the hippocampal mossy fibre system which is shown to be due to receptors with slow dissociation rate. Furthermore, the concentration dependency of the specific labelling, as quantified by microdensitometry, allows some suggestions concerning the local binding affinities involved.

gamma-D-glutamylglycine as an antagonist of kainic acid on leech Retzius neurones

Intracellular recordings were made from Retzius cells from the segmental ganglia of the leech, Hirudo medicinalis, gamma-D-Glutamylglycine, (50 microM), reversibly and preferentially antagonised the excitatory action of kainate, having no effect on actions of quisqualate or carbachol but at this concentration the antagonism was of short duration, reversing prior to washing off the gamma-D-glutamylglycine. However, higher concentrations of gamma-D-glutamylglycine (250-500 microM) reversibly antagonised both quisqualate and carbachol-induced excitatory responses, indicating a lack of specificity. The value of gamma-D-glutamylglycine in determining the possible site of action of kainate on leech Retzius cells is discussed.