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

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.

Opiates: biphasic dose responses

It was shown that biphasic responses are commonly reported for opiates with respect to a broad range of animal models and endpoints. These endpoints include such diverse functions as blood pressure, muscle tension, breathing rates, hCG production, HIV production, neutrophil migration, ACTH production, protein binding, and neuronal functioning. Quantitative features of the dose-response relationships indicated that the maximum stimulatory responses were < or = 3-fold greater than the controls with most being between 10 to 70% greater than the controls. In contrast to the striking similarity in the maximum stimulatory response, there was marked variation with respect to the dose range of the stimulatory responses that varied from 10(1) to 10(10). Mechanistic assessments were conducted for most biphasic dose-response relationships and are addressed in detail.

Predominant expression of group-II metabotropic glutamate receptors in the goldfish brain

Group-II metabotropic glutamate (mGlu) receptors (mGlu2/3 receptors) were highly expressed in various regions (telencephalon, optic tectum, and cerebellum, but not vagal lobe) of the goldfish brain. In the goldfish telencephalon, expression of mGlu2/3 receptors was even higher than in the rat cerebral cortex. In contrast, mGlu5 receptors showed low levels of expression in all goldfish brain regions, whereas mGlu1a receptors were only expressed in the goldfish cerebellum. Pharmacological activation of group-II mGlu receptors with the selective agonists, 2R,4R-4-aminopyrrolidine-2, 4-dicarboxylic acid and (2S,2'R,3'R)-2-(2,3-dicarboxycyclopropyl) glycine, reduced the evoked release of glutamate from goldfish brain synaptosomes, whereas agonists of group-I and -III mGlu receptors (3, 5-dihydroxyphenylglycine and L-2-amino-4-phosphonobutanoate) were inactive. The predominance of group-II over group-I mGlu receptors in the goldfish brain may provide a natural defense against excitotoxic neuronal death and contribute to the unusually high resistance of goldfish against hypoxic brain damage.

Molecular and electrophysiological characterizations of fGluR3 alpha, an ionotropic glutamate receptor subunit of a teleost fish

Here we report the cloning and functional analysis of a cDNA encoding a functional glutamate receptor subunit of Oreochromis sp., a freshwater teleost fish. The deduced amino acid sequence of this cDNA clone, fGluR3 alpha, displays the highest sequence identity to that of the mammalian GluR3 subunit. Results of quantitative reverse-transcriptase polymerase chain reaction (RT-PCR) analysis indicated that the expression level of fGluR3 alpha in the cerebellum was much less than that in the telencephalon and optical lobe. Similar to its mammalian counterpart, variants of fGluR3 alpha were created by alternative splicing and RNA editing at the R/G site. The channel properties of homomeric fGluR3 alpha expressed in Xenopus oocytes were similar to those of the mammalian alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA)-preferring receptors. The rank order of agonist potency of the expressed fGluR3 alpha is AMPA > or = glutamate > or = quisqualate > domoate > or = kainate. This is the first functional glutamate receptor of teleost fish being demonstrated to be sensitive to AMPA. Furthermore, this study suggested a strong functional conservation of AMPA-preferring receptors in vertebrates.

Solving inconsistencies in the analysis of receptor-ligand interactions

According to the occupation model, the observed sigmoidicity in receptor-binding studies frequently yields non-integer values for the number of molecules that bind per receptor, which may suggest inconsistencies of the model. Here, Bertil Tuk and Michael van Oostenbruggen re-examine the derivation of the model and pinpoint the origin of the observed inconsistencies, thereby demonstrating that these inconsistencies may lead to substantial error in estimates of receptor affinity, number of molecules that bind per receptor and cooperativity. A reformulated model allows more information to be derived from receptor-binding experiments, yielding integer estimates of the number of molecules that bind per receptor and quantitatively estimating the degree of cooperativity.

An endogenous ligand for the kainate-type binding sites from rat brain

Extracts from the rat brain were screened to identify a putative endogenous ligand for the binding sites of the neuroexcitant kainic acid (KA). The extracted substances were separated by chromatographic techniques and tested for their ability to inhibit KA binding to fish synaptosomes and to membranes from rat brain. A substance isolated in this way (rat kainate-binding inhibitor, RKBI) display a competitive interaction with KA for the low-affinity binding sites in rat brain membranes. According to the separation behavior in the purification step, RKBI is distinct from an inhibitor formerly isolated from fish nervous tissue (KBI). The substance exhibits positive co-operativity with KA for a very-low-affinity site population, particularly concentrated in the cerebellum, and could play a physiological role in this area.

[3H]resiniferatoxin binding to pig dorsal horn membranes displays positive cooperativity

In the present report we have reevaluated specific [3H]resiniferatoxin (RTX) binding, thought to represent the vanilloid (capsaicin) receptor, to whole spinal cord and dorsal horn membranes of the pig using a modified [3H]RTX binding assay. The high nonspecific [3H]RTX binding of the original protocol was reduced by the addition of alpha 1-acid glycoprotein (AGP), a plasma protein that binds RTX, to the assay mixture after the binding reaction had been terminated. Specific [3H]RTX binding to pig whole spinal cord and dorsal horn membranes followed sigmoidal saturation kinetics indicating apparent positive cooperativity. The cooperativity index determined by fitting the data to the Hill equation was 2.31 +/- 0.24 in the spinal cord and 2.27 +/- 0.13 in the dorsal horn. The apparent dissociation constants in spinal cord and dorsal horn membranes were 87.8 +/- 2.7 and 103.9 +/- 1.9 pM; the receptor densities were 23 +/- 3 and 203 +/- 5 fmol/mg protein, respectively. In parallel experiments, rat spinal cord membranes bound [3H]RTX with 2 - 3 fold higher affinity, equal positive cooperativity, and a 49 +/- 6 fmol/mg receptor density. As predicted by the modified Hill equation, at low receptor occupancy nonradioactive RTX produced biphasic competition curves. Capsaicin and the competitive antagonist capsazepine also fully displaced specifically bound [3H]RTX from pig dorsal horn membranes with Ki values of 9.7 +/- 1.7 microM and 6.8 +/- 0.7 microM, respectively; the corresponding Hill coefficients were 1.81 +/- 0.17 and 2.32 +/- 0.11. [3H]RTX binding was not inhibited by resiniferonol 9, 13, 14-orthophenylacetate, the biologically inactive parent diterpene of RTX. These findings suggest that the vanilloid receptor present in the dorsal horn of the pig, like those present in human and in the rat, is a receptor cluster in which the subunits cooperate.

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.

Effects of excitotoxins on free radical indices in mouse brain

Excitotoxins and free radicals individually have been implicated in several neurological disorders including those associated with aging. We observed that systemically administered domoic acid enhanced mouse brain superoxide dismutase activity with either an associated decrease or no change in mouse brain lipid peroxidation. These findings reflect a state of adequately compensated oxidative stress induced by excitotoxins. In homogenates containing disrupted cells from various regions of mouse brain, however, kainic acid produced a 2 to 5-fold increase in lipid peroxidation. This suggests that excitotoxins cause lipid peroxidation possibly by acting at intracellular loci which become more accessible following disruption of cells in vitro and by extrapolation, possibly in vivo due to cellular permeability changes during the edematous stage of ischemic and other related neuropathological conditions.

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.

[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.

Lack of excitatory amino acid-induced effects on calcium fluxes measured with 45Ca2+ in rat cerebral cortex synaptosomes

Ca2+ uptake was measured in purified rat cerebral cortex synaptosomes (P3 pellets) using 45Ca2+ as a tracer. Ca2+ influx increased in time, and with an increase in external K+ concentration and temperature. The net (external K+-induced, depolarization-dependent) uptake follows a two-component course. The exponential term, due to the opening of voltage-operated calcium channels (VOC), has a rate constant which increases with an increase in the depolarization level (1.04 versus 0.54 nmol/s/mg protein for 50 mM - versus 15 mM [K+]-dependent net influx). The linear term, due to the Na+/Ca2+ exchange system, has a similar rate constant at all depolarization levels (0.16 +/- 0.05 and 0.11 +/- 0.02 nmol/s/mg protein). Excitatory amino acids (glutamate, kainate and n-methyl-d-aspartate-NMDA-) were tested on this preparation at doses ranging between 5 x 10(-5) M and 5 x 10(-3) M and at multiple incubation times, under resting conditions and under two depolarizing conditions (partial depolarization: 15 mM external K+ and maximal depolarization: 50 mM external K+). NMDA was also tested in the absence of Mg2+. No effect was detectable under any of these experimental conditions. Hypotheses to interpret these data are discussed. Further studies on other preparations are needed in order to directly investigate the presynaptic effects of excitatory amino acids.

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.

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.

The toxin kainic acid: a study of avian nerve and glial cell response utilizing tritiated kainic acid and electron microscopic autoradiography

Three questions are asked regarding the toxin kainic acid (KA). Does it destroy specific glial cells as well as neurons? Does KA gain access to the cytoplasm in intact cells and to which organelles does it bind? Intracerebral injections of tritiated KA into the pigeon (Columba livia) paleostriatal complex (basal ganglia) coupled with electron microscopic autoradiography revealed the following major points. Kainic acid destroyes oligodendrocytes, with pathophysiology apparent by 30 min after challenge with KA leading to cell destruction by 4 h. The response of astrocytes at the longest observation period (4 h) involves swelling of perivascular endfeet and processes in the neuropil. Reactive microglial-like cells show an accumulation of label in their cytoplasm, but no apparent morphological changes. The label appears in the cytoplasm of intact cells, both glia and neurons early after challenge with the toxin. Label is associated (bound) with mitochondria at an incidence significantly above chance at 30 min, 2 and 4 h after challenge with KA. Two hours after exposure to KA is the critical period where metabolic, physiological and morphological changes occur that lead to cell death. Cell destruction may be a consequence of KA-induced energy depletion. Kainate may interfere with adequate energy production by uncoupling glycolysis and the Krebs cycle in the mitochondria.

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.