domoic-acid and Nerve-Degeneration

Domoic acid (DA), an agonist of non-N-methyl-D-aspartate (non-NMDA) receptor subtype including kainate receptor, was identified as a potent neurotoxin showing involvement in neuropathological processes like neuronal degeneration and atrophy. In the past decade evidence indicating a role for excitatory amino acids in association with neurological disorders has been accumulating. Although the mechanisms underlying the neuronal damage induced by DA are not yet fully understood, many intracellular processes are thought to contribute towards DA-induced excitotoxic injury, acting in combination leading to cell death. In this review article, we report the leading hypotheses in the understanding of DA-induced neurotoxicity, which focus on the role of DA in neuropathological manifestations, the formation of the retrograde messenger molecule nitric oxide (NO) for the production of free radicals in the development of neuronal damage, the activation of glial cells (microglia and astrocytes) in response to DA-induced neuronal damage and the neuroprotective role of melatonin as a free radical scavenger or antioxidant in DA-induced neurotoxicity. The possible implications of molecular mechanism underlying the neurotoxicity in association with necrosis, apoptosis, nitric oxide synthases (nNos and iNOS) and glutamate receptors (NMDAR1 and GluR2) related genes and their expression in DA-induced neuronal damage in the hippocampus have been discussed.

Topics: Animals; Bivalvia; Hippocampus; Humans; Kainic Acid; Nerve Degeneration; Neurotoxins; Rats; Shellfish

Endogenous excitatory amino acids (EAAs) such as glutamic or aspartic acids have been proposed to mediate the brain damage to EAA receptor-rich brain sites that is caused by a variety of external toxic agents (glutamic acid, domoic acid, kainic acid, ibogaine, trimethyltin (TMT), 3-nitropropionic acid (3-NPA)), as well as from such naturally-occurring age-related neurodegenerative diseases as Alzheimer's disease, Huntington's chorea, and Parkinson's disease. Sites often damaged include the hypothalamus (glutamate), the hippocampal and neocortical pyramidal neurons (domoic acid), the cerebellar Purkinje neurons (ibogaine) and the corpus striatum (3-NPA, amphetamine). The excitotoxic damage occurs to neuronal cell bodies and their dendrites, resulting in a characteristics appearance of pyknotic neurons surrounded by their vacuolated, swollen dendrites. Axons passing through the region that lack EAA receptors are completely spared. However, astrocytes with swollen perikarya and nuclei (Alzheimer's type II "reactive" astrocytes) are often observed in the vicinity of the lesions. Animal and human "Prion Diseases" or "Transmissible Spongiform Encephalopathies" (TSEs) result (after a period of months to years) in a neurodegenerative picture characterized by pyknotic neurons surrounded by vacuoles with numerous reactive astrocytes in the vicinity of the damage. In addition, amyloid deposits composed of a protease-resistant protein (PrPSc) characteristic of the particular host species with the disease are found near the degenerating neurons. By using different strains of the scrapies TSE agent to inoculate hamsters and mice, reproducible models of hypothalamic, hippocampal, or cerebellar damage resulting in the appropriate functional deficits may be obtained. Because of the close similarity in the appearance, localization, and functional consequences from TSE neuropathology compared to some of the well-known EAA syndromes, we propose that excitotoxic mechanisms may play a role in the pathogenesis of TSE neurodegenerative diseases. The similarity in pathogenesis of the neurodegenerative processes in excitotoxicity compared to TSE diseases also implies that neuroprotective strategies against excitotoxicity may also be effective against TSEs.

Topics: Animals; Brain; Cricetinae; Glutamic Acid; Humans; Hypothalamus; Ibogaine; Kainic Acid; Mice; N-Methylaspartate; Nerve Degeneration; Neurotoxins; Prion Diseases

We have monitored real-time alterations in [Ca(2+)](i) in fluo-3-loaded cerebellar granule neurons exposed to domoate, and ascertained the influence of pharmacological blockers of various Ca(2+) entry pathways on intracellular Ca(2+) accumulation, excitatory amino acid (EAA) release and neuronal death. Domoate produced a rapid and concentration-dependent increase in [Ca(2+)](i), the magnitude of which correlated closely with the severity of neuron loss. The increase in [Ca(2+)](i) was derived from activation of NMDA receptors, L-type voltage-sensitive calcium channels (VSCC) and the reversed mode of operation of the Na(+)/Ca(2+) exchanger. When the level of neuroprotection conferred by pharmacological manipulation of these calcium entry pathways was regressed with the corresponding reductions in [Ca(2+)](i) load, it was observed that neuronal vulnerability is controlled preferentially by NMDA receptors. This observation is consistent with our previous study of brevetoxin-induced autocrine excitotoxicity and with the source specificity hypothesis of others [J. Neurochem. 71 (1998) 2349], which suggests that elevation of [Ca(2+)](i) in the vicinity of the NMDA receptor ion channel activates processes leading to neuronal death.

Topics: Aniline Compounds; Animals; Animals, Newborn; Calcium Channel Blockers; Calcium Channels; Calcium Signaling; Cell Death; Cells, Cultured; Cerebellar Cortex; Dose-Response Relationship, Drug; Enzyme Inhibitors; Excitatory Amino Acid Antagonists; Excitatory Amino Acids; Fluorescent Dyes; Kainic Acid; L-Lactate Dehydrogenase; Nerve Degeneration; Neuromuscular Depolarizing Agents; Neurons; Neurotoxins; Rats; Rats, Sprague-Dawley; Receptors, N-Methyl-D-Aspartate; Sodium-Calcium Exchanger; Xanthenes

The telomeric copy of the survival motor neuron gene (SMN1) is deleted or mutated in all spinal muscular atrophy (SMA) patients and these patients present mainly a loss in spinal motoneurons. Although studies performed in HeLa cells suggest that SMN may be involved in the biogenesis and possibly in recycling of spliceosomal small nuclear ribonucleoproteins (snRNPs), no link has been established between this function and the consequence of the absence of SMN in the specific loss of motoneurons. We attempted to answer the question of whether SMN plays a direct role in motoneuron survival by transducing cultured motoneurons with lentiviral vectors coding either for an antisense Smn mRNA or for full-length or truncated forms of SMN. We studied their effect on survival under different anti- or proapoptotic culture conditions. Our results show that increased levels of SMN are unable to protect motoneurons from death induced by trophic deprivation or by excitotoxicity. These results suggest that SMN is not a survival factor per se for motoneurons. In addition, overexpression of a truncated form of SMN shown to induce a modified subcellular localization and to exert a dominant-negative effect on snRNP biogenesis and RNA splicing in HeLa cells was ineffective in modifying both localization and survival in motoneurons.

Topics: Animals; Cell Survival; Cells, Cultured; Cyclic AMP Response Element-Binding Protein; Fetus; Genetic Vectors; Humans; Kainic Acid; Lentivirus; Motor Neurons; Nerve Degeneration; Nerve Growth Factors; Nerve Tissue Proteins; Neurotoxins; Rats; RNA-Binding Proteins; RNA, Antisense; SMN Complex Proteins; Spinal Cord; Spinal Muscular Atrophies of Childhood; Survival of Motor Neuron 1 Protein; Transduction, Genetic

The expression of aromatase, the enzyme that catalyzes the biosynthesis of estrogens from precursor androgens, is increased in the brain after injury, suggesting that aromatase may be involved in neuroprotection. In the present study, the effect of inactivating aromatase has been assessed in a model of neurodegeneration induced by the systemic administration of neurotoxins. Domoic acid, at a dose that is not neurotoxic in intact male mice, induced significant neuronal loss in the hilus of the hippocampal formation of mice with reduced levels of aromatase substrates as a result of gonadectomy. Furthermore, the aromatase substrate testosterone, as well as its metabolite estradiol, the product of aromatase, were able to protect hilar neurons from domoic acid. In contrast, dihydrotestosterone, the 5 alpha-reduced metabolite of testosterone and a nonaromatizable androgen, was not. These findings suggest that aromatization of testosterone to estradiol may be involved in the neuroprotective action of testosterone in this experimental model. In addition, aromatase knock-out mice showed significant neuronal loss after injection of a low dose of domoic acid, while control littermates did not, indicating that aromatase deficiency increases the vulnerability of hilar neurons to neurotoxic degeneration. The effect of aromatase on neuroprotection was also tested in male rats treated systemically with the specific aromatase inhibitor fadrozole and injected with kainic acid, a well characterized neurotoxin for hilar neurons in the rat. Fadrozole enhanced the neurodegenerative effect of kainic acid in intact male rats and this effect was counterbalanced by the administration of estradiol. Furthermore, the neuroprotective effect of testosterone against kainic acid in castrated male rats was blocked by fadrozole. These findings suggest that neuroprotection by aromatase is due to the formation of estradiol from its precursor testosterone. Finally, a role for local cerebral aromatase in neuroprotection is indicated by the fact that intracerebral administration of fadrozole enhanced kainic acid induced neurodegeneration in the hippocampus of intact male rats. These findings indicate that aromatase deficiency decreases the threshold for neurodegeneration and that local cerebral aromatase is neuroprotective. Brain aromatase may therefore represent a new target for therapeutic approaches to neurodegenerative diseases.

Topics: Animals; Aromatase; Aromatase Inhibitors; Brain; Cell Death; Dihydrotestosterone; Enzyme Inhibitors; Estradiol; Fadrozole; Kainic Acid; Male; Mice; Mice, Inbred C57BL; Nerve Degeneration; Neurons; Neuroprotective Agents; Neurotoxins; Orchiectomy; Testosterone

Domoic acid (DA), a potent neurotoxin, administered intravenously (0.75 mg/kg body weight) in adult rats evoked seizures accompanied by nerve cell damage in the present study. Neuronal degeneration and microglial reaction in the hippocampus were investigated, and the temporal profile of bcl-2, bax, and caspase-3 genes in cell death or survival was assessed following the administration of DA. Nissl staining showed darkly stained degenerating neurons in the hippocampus following the administration of DA at 1-21 days, the degeneration being most severe at 5 days. Ultrastructural study in CA1 and CA3 regions of hippocampus revealed two types of neuronal degeneration, cells that exhibited swollen morphology and shrunken electron-dense cells. Immunoreactivity of Bcl-2 and Bax was increased considerably at 16 hr and 24 hr in the neurons of the hippocampus following DA administration. No significant change was observed in the immunoreactivity of caspase-3 in the controls and DA-treated rats at any time interval. Microglial cells in the hippocampus showed intense immunoreaction with the antibodies OX-42 and OX-6 at 1-21 days after DA administration, indicating the up-regulation of complement type 3 receptors and major histocompatibility complex type II antigens for increased phagocytic activity and antigen presentation, respectively. Terminal deoxynucleotidyl-transferase-mediated dUTP nick end labeling (TUNEL) showed occasional positive neurons in the CA1 and CA3 regions at 5 days after DA administration, with no positive cells in the controls. RT-PCR analysis revealed that bcl-2 and bax mRNA transcripts in the hippocampus were significantly increased at 16 hr and gradually decreased at 24 hr following the administration of DA. Although bax and bcl-2 mRNA expression is rapidly induced at early stages, in situ hybridization analysis revealed complete loss of bcl-2, bax, and caspase-3 mRNA at 24 hr after DA administration in the region of neuronal degeneration in the hippocampus. These results indicate that the pattern of neuronal degeneration observed during DA-induced excitotoxic damage is mostly necrotic.

Topics: Animals; Apoptosis; bcl-2-Associated X Protein; Caspase 3; Caspases; Convulsants; Gene Expression Profiling; Gene Expression Regulation; Genes, bcl-2; Hippocampus; Histocompatibility Antigens Class II; In Situ Hybridization; In Situ Nick-End Labeling; Kainic Acid; Macrophage-1 Antigen; Male; Marine Toxins; Microglia; Microscopy, Electron; Nerve Degeneration; Nerve Tissue Proteins; Neurons; Neurotoxins; Phagocytosis; Proto-Oncogene Proteins; Proto-Oncogene Proteins c-bcl-2; Rats; Rats, Wistar; Reverse Transcriptase Polymerase Chain Reaction; RNA, Messenger; Seizures; Time Factors; Up-Regulation

Domoic acid (Dom) is a glutamate analog and a seafood toxin that has caused neurological disturbance and death in humans. Brain lesions caused by Dom have been documented in the literature, but the effect of Dom on the spinal cord has not been investigated as extensively. Systemic administration of glutamate agonists (i.e., homocysteate, kainate, and a-amino-3-hydroxy-5-methylisoxazole-4-propionic acid) caused spinal cord lesions in infant rats. In the present study, the toxic effects of Dom on the developing spinal cord are examined. Neonatal rats on Postnatal Day 7 were administered Dom subcutaneously at doses of 0.10, 0.17, 0.25, 0.33, 0.42, and 0.50 mg/kg, respectively. Motor seizures characterized by scratching, tail flicking, and swimming-like movement were induced by Dom at all doses. High doses of Dom (> or = 0.33 mg/kg) further induced a hindlimb paralysis, a forelimb tremor, and death that occurred in less than 2 hours. The percentages of death and paralysis induced by 0.33 mg/kg Dom were 47% and 65%, respectively (n = 17). At this dose, electrocorticogram was recorded and synchronized interrupted electrical activities in brains of these animals were detected. However, no brain damage was detected in these rats. Spinal cord lesions characterized by focal hemorrhage, neuronal swelling, and neuronal vacuolization were found in 73% of the animals that had shown the paralysis/tremor in their extremities, as examined 1 to 2 hours after Dom injection. These lesions were seen at all spinal cord levels. Neuronal degeneration was mainly found in the ventral and intermediate gray matter, whereas cells in the dorsal portion of the spinal cord were relatively spared. Data suggest that observed behavioral changes were due to spinal cord damage rather than seizures or brain lesions.

Topics: Animals; Animals, Newborn; Dose-Response Relationship, Drug; Electroencephalography; Extremities; Injections, Subcutaneous; Kainic Acid; Nerve Degeneration; Neuromuscular Depolarizing Agents; Neurotoxins; Paralysis; Rats; Rats, Sprague-Dawley; Spinal Cord; Tremor

Using the seafood contaminant domoic acid (an AMPA/kainate receptor agonist), we demonstrate a distinct excitotoxic sequence of events leading to acute neuronal damage in the hippocampal slice as measured by (1) loss of the evoked CA1 field potential, (2) irreversible changes in light transmittance, (3) histopathology, and (4) lucifer yellow injection of single CA1 pyramidal neurons. Change in light transmittance (LT) through the submerged slice indirectly measures altered cell volume, both neuronal and glial. At 37 degrees C, a 1-min superfusion of 10 mu M domoate induced a prolonged reversible increase in LT, primarily in the dendritic regions of CA1 and dentate granule cells (GC), but not in the CA3 region. Spectral analysis (400-800 nm) revealed a wide-band transmittance increase, indicating cell swelling as a major source of the intrinsic signal. The evoked field potential recorded in the CA1 cell body region (PYR) was lost as LT peaked, but completely recovered upon return to the baseline LT level. Increasing domoate exposure to 10 min elicited a different and distinct LT sequence in CA1 and dentate regions. An initial LT increase in dendritic regions evolved in an irreversible decrease in LT. At the same time, LT irreversibly increased in cell body regions (CA1 PYR and GC) and the evoked field potential was irretrievably lost. Also, there was histological damage to cell body and dendritic regions of CA1 and granule cells. Injection of lucifer yellow into single CA1 neurons in slices displaying the irreversible LT sequence revealed extensive dendritic beading, whereas CA1 cells in control slices displayed a smoothly contoured arbor. Consistent with acute neuronal damage, the optical changes generated by domoate did not require extracellular Ca2+, and lowering the temperature protected the slice from irreversible damage to CA1 and GC regions. Although glial changes may also occur, we conclude that imaging light transmittance reveals dynamic and compartmentalized excitotoxic changes in neuronal volume. Beading of the dendritic arbor increases light scatter, thereby decreasing LT and highlighting damaged dendritic regions.

Topics: Animals; Calcium Chloride; Dendrites; Electrophysiology; Fluorescent Dyes; Hippocampus; Image Cytometry; Image Processing, Computer-Assisted; Isoquinolines; Kainic Acid; Male; Membrane Potentials; Microinjections; Nerve Degeneration; Neuromuscular Depolarizing Agents; Neurons; Neurotoxins; Optics and Photonics; Organ Culture Techniques; Rats; Rats, Sprague-Dawley; Receptors, AMPA

Domoic acid is a potent excitotoxin produced by diatoms which is subsequently passed along the marine food chain. Its chemical structure and toxicological properties are similar to kainic acid. Like kainic acid, exposure results in extensive hippocampal degeneration. The effect of domoic acid on other primate brain structures, however, is less resolved. In an attempt to clarify this issue, the present study applied a degeneration specific histochemical technique (de Olmos' cupric-silver method) to reveal degeneration within the brains of domoic acid-dosed cynomolgus monkeys. Degenerating neuronal cell bodies and terminals were found not only within the hippocampus, but also within a number of other 'limbic' structures including the entorhinal cortex, the subiculum, the piriform cortex, the lateral septum, and the dorsal lateral nucleus of the thalamus. Although the hippocampus is a component of the original limbic circuit of Papez, other components such as the mammillary bodies, the anterior nucleus of the thalamus and the cingulate cortex contained no degeneration, while a number of more recently documented efferent targets of the hippocampal formation revealed extensive degeneration. The pattern of degeneration generally correlated with those regions containing high densities of kainate receptors.

Topics: Animals; Entorhinal Cortex; Female; Hippocampus; Kainic Acid; Macaca mulatta; Male; Nerve Degeneration; Neuromuscular Depolarizing Agents; Prosencephalon; Pyramidal Cells

We have investigated the action of domoic acid in the mouse brain following systemic exposure. Domoic acid increased c-fos mRNA within 15 min and its translational product (c-Fos) within 1 h. c-Fos immunoreactivity was most prominent in the hippocampal formation, lateral septal nucleus, olfactory bulb, area postrema and the nucleus of the solitary tract. We next examined irreversible toxic effects of domoic acid. Domoic acid caused extensive degeneration in CA1-2 of the hippocampus, lateral septal nucleus and olfactory bulb. No degeneration was evident in the dentate gyrus or brain stem. These studies demonstrate that domoic acid has only neuroexcitatory effects on brain stem regions associated with visceral function whereas it has permanent neurotoxic effects on brain regions associated with memory formation.

Topics: Animals; Blotting, Northern; Brain; Brain Chemistry; Brain Stem; Female; Immunohistochemistry; Kainic Acid; Mice; Mice, Inbred ICR; Nerve Degeneration; Neurons; Neurotoxins; Proto-Oncogene Proteins c-fos; Silver Staining

Domoic acid is a tricarboxylic amino acid (structurally related to kainic acid and glutamic acid) that is found in the environment as a contaminant of some seafood. To determine the nature of any neurological damage caused by domoate, as well as the minimum neurotoxic dose, juvenile and adult monkeys were dosed intravenously with domoate at one of a range of doses from 0.25 to 4 mg/kg. When animals were perfused one week later, histochemical staining using a silver method to reveal degenerating axons and cell bodies showed two distinct types of hippocampal lesions. One lesion, termed 'Type A', was a small focal area of silver grains restricted to CA2 stratum lucidum, the site of greatest kainic acid receptor concentration in the brain. Type A lesions occurred over a dose range of 0.5 to 2.0 mg/kg in juvenile animals and 0.5 to 1.0 mg/kg in adult animals. No mortality occurred in any of the juvenile monkeys, but one juvenile animal that received 4.0 mg/kg sustained a second type of lesion, termed 'Type B', characterized by widespread damage to pyramidal neurons and axon terminals of CA4, CA3, CA2, CA1, and subiculum subfields of the hippocampus. Doses of more than 1.0 mg/kg in the adult monkeys either proved lethal or resulted in Type B lesions. Induction of c-fos protein had occurred in the hippocampal dentate gyrus and CA1 regions of moribund animals perfused within hours of their initial dose.(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Animals; Dose-Response Relationship, Drug; Female; Hippocampus; Kainic Acid; Macaca fascicularis; Male; Marine Toxins; Nerve Degeneration; Nerve Endings; Neurons; Neurotoxins; Silver Staining

Domoic acid (DA), an analog of kainic acid, produces attentional deficits in humans who have ingested shell fish contaminated with this excitotoxin. The thalamic reticular nucleus (RT), by virtue of its location, connections and intrinsic properties, has been implicated in attentional processes. This study demonstrated the vulnerability of RT neurons following intrathalamic DA injections in rats. Lesions were characterized by almost total neuronal loss throughout the RT and sparing of adjacent populations of relay neurons in the VL and VPL. Los of RT neurons may underlie some types of attentional deficits observed in humans following DA poisoning.

Topics: Animals; Dopamine; In Vitro Techniques; Injections; Kainic Acid; Male; Motor Activity; Nerve Degeneration; Neuromuscular Depolarizing Agents; Rats; Reticular Formation; Thalamic Nuclei; Thalamus

Recent evidence implicates excitatory amino acids (EAAs), acting as excitotoxic agents, in the pathogenesis of neurological disorders involving the spinal cord. In this study, we used the chick embryo spinal cord as an in vitro model for studying the sensitivity of spinal neurons to the excitotoxic effects of EAA agonists. Compounds tested include the prototypic receptor-specific agonists, N-methyl-D-aspartate (NMDA), quisqualic acid (Quis), and kainic acid (KA), and the plant-derived excitotoxic food poisons, beta-N-oxalylamino-L-alanine, beta-N-methylamino-L-alanine, and domoic acid. Each agonist induced concentration-dependent acute degeneration of neurons distributed throughout the spinal cord. These cytopathological changes consisted of acute edematous degeneration of dendrosomal structures in the dorsal horn and intermediate zone, and dark cell changes with intracytoplasmic vacuolization of motor neurons; this damage is identical to that induced by excitotoxin agonists in other regions of the central nervous system. The NMDA receptor-specific antagonist MK-801 completely blocked toxicity of NMDA, and the nonNMDA antagonist CNQX preferentially blocked the toxicity of Quis- and KA-type agonists in the spinal cord. Our findings suggest that (1) the majority of spinal neurons have all three subtypes of EAA receptors, making them acutely vulnerable to excitotoxin exposure; and (2) EAA antagonists are effective in preventing excitotoxin-induced damage of the spinal cord.

Topics: 6-Cyano-7-nitroquinoxaline-2,3-dione; alpha-Amino-3-hydroxy-5-methyl-4-isoxazolepropionic Acid; Amino Acids, Diamino; Animals; beta-Alanine; Chick Embryo; Cyanobacteria Toxins; Dizocilpine Maleate; Glutamates; Glutamic Acid; Ibotenic Acid; Kainic Acid; Motor Neurons; N-Methylaspartate; Nerve Degeneration; Neurotoxins; Quinoxalines; Quisqualic Acid; Spinal Cord