Hippocampal mossy fiber zinc deficit in mice genetically selected for ethanol withdrawal seizure susceptibility

Hippocampal neural progenitor cells play a distinct role in fear memory retrieval in male and female CIE rats

Adult male and female GFAP-TK transgenic rats experienced six weeks of chronic intermittent ethanol vapor inhalation (CIE). During the last week of CIE, a subset of male and female TK rats were fed with Valcyte to ablate neural progenitor cells (NPCs). Seventy-two hours after CIE cessation, all CIE and age-matched ethanol naïve controls experienced auditory trace fear conditioning (TFC). Twenty-four hours later all animals were tested for cue-mediated retrieval in the fear context. Adult male CIE rats showed a significant burst in NPCs paralleled by reduction in fear retrieval compared to naïve controls and Valcyte treated CIE rats. Adult female CIE rats did not show a burst in NPCs and showed similar fear retrieval compared to naïve controls and Valcyte treated CIE rats, indicating that CIE-mediated impairment in fear memory and its regulation by NPCs was sex dependent. Valcyte significantly reduced Ki-67 and NeuroD labeled cells in the dentate gyrus (DG) in both sexes, demonstrating a role for NPCs in reduced fear retrieval in males. Valcyte prevented adaptations in GluN2A receptor expression and synaptoporin density in the DG in males, indicating that NPCs contributed to alterations in plasticity-related proteins and mossy fiber projections that were associated with reduced fear retrieval. These data suggest that DG NPCs born during withdrawal and early abstinence from CIE are aberrant, and could play a role in weakening long-term memory consolidation dependent on the hippocampus.

Zinc at glutamatergic synapses

It has long been known that the mammalian forebrain contains a subset of glutamatergic neurons that sequester zinc in their synaptic vesicles. This zinc may be released into the synaptic cleft upon neuronal activity. Extracellular zinc has the potential to interact with and modulate many different synaptic targets, including glutamate receptors and transporters. Among these targets, NMDA receptors appear particularly interesting because certain NMDA receptor subtypes (those containing the NR2A subunit) contain allosteric sites exquisitely sensitive to extracellular zinc. The existence of these high-affinity zinc binding sites raises the possibility that zinc may act both in a phasic and tonic mode. Changes in zinc concentration and subcellular zinc distribution have also been described in several pathological conditions linked to glutamatergic transmission dysfunctions. However, despite intense investigation, the functional significance of vesicular zinc remains largely a mystery. In this review, we present the anatomy and the physiology of the glutamatergic zinc-containing synapse. Particular emphasis is put on the molecular and cellular mechanisms underlying the putative roles of zinc as a messenger involved in excitatory synaptic transmission and plasticity. We also highlight the many controversial issues and unanswered questions. Finally, we present and compare two widely used zinc chelators, CaEDTA and tricine, and show why tricine should be preferred to CaEDTA when studying fast transient zinc elevations as may occur during synaptic activity.

Neural Overexcitation and Implication of NMDA and AMPA Receptors in a Mouse Model of Temporal Lobe Epilepsy Implying Zinc Chelation

PURPOSE

Zinc chelation with diethyldithiocarbamate (DEDTC) during nondamaging kainic acid administration enhances excitotoxicity to the level of cell damage. The objective of this work was to study the developing of the lesion in this model of temporal lobe epilepsy and the implications of the different types of glutamate receptors.

METHODS

The antagonist of the N-methyl-D-aspartate (NMDA) receptor MK-801, and the antagonist of the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) receptor GYKI52466, were used concomitantly with intraperitoneal administration of kainic acid (15 mg/kg) followed by DEDTC (150 mg/kg) in mouse. The animals were killed at different times from 4 h to 7 days. Fos proteins were used as markers of cell overexcitation; heat-shock protein 72 (HSP72) as marker of cell stress.

RESULTS

Neither kainic acid nor DEDTC alone, at the doses used, led to cell loss, HSP72 expression, or permanent Fos protein induction. When combined, the hilus and cornu ammonis were damaged; principal cells in these areas coexpressed c-Fos and HSP72, with the exception of CA2; interneurons did not express HSP72 in any area. MK-801 completely abolished damage and HSP72 expression from the hippocampus. GYKI52466 blocked CA1 damage and HSP72 expression in the CA1 but not in the CA3.

CONCLUSIONS

Synaptic zinc increases the tolerance of hippocampus to overexcitation. All the areas that are fated to die are determined simultaneously; the damage in the CA1 is not an extension of the damage in the CA3. Damage of the CA3 is dependent on kainate and NMDA receptors, whereas the damage of the CA1 depends on AMPA and NMDA receptors.

Zinc inhibition of gamma-aminobutyric acid transporter 4 (GAT4) reveals a link between excitatory and inhibitory neurotransmission

gamma-Aminobutyric acid (GABA) transporters (GATs) play an important role in inhibitory neurotransmission by clearing synaptically released GABA and by maintaining low resting levels of GABA in synaptic and extrasynaptic regions. In certain brain regions, vesicular zinc is colocalized and coreleased with glutamate and modulates the behavior of a number of channels, receptors, and transporters. We examined the effect of zinc on expressed GATs (GAT1, GAT2, GAT3, and GAT4) in Xenopus laevis oocytes by using tracer flux and electrophysiological methods. We show that zinc is a potent inhibitor of GAT4 (K(i) of 3 muM). Immunolocalization of GAT4 in the hippocampus revealed dense localization in the CA1 and CA3 regions of the hippocampus, regions which are known to be heavily populated by zinc-containing glutamatergic neurons. The results suggest a physiological role of synaptically released zinc in the hippocampus, because zinc released from hyperactive glutamatergic neurons may simultaneously bring about elevated GABAergic inhibition. Therefore, this mode of zinc function signifies a link between excitatory and inhibitory neurotransmission and may play a neuroprotective role against glutamate-induced excitotoxicity.

Zinc chelation during non-lesioning overexcitation results in neuronal death in the mouse hippocampus

In the hippocampus, chelatable zinc is accumulated in vesicles of glutamatergic presynaptic terminals, abounding specially in the mossy fibers, from where it is released with activity and can exert a powerful inhibitory action upon N-methyl-D-aspartate receptors. Zinc is therefore in a strategic situation to control overexcitation at the zinc-rich excitatory synapses, and consequently zinc removal during high activity might result in excitotoxic neuronal damage. We analyzed the effect of zinc chelation with sodium dietyldithiocarbamate under overexcitation conditions induced by non-lesioning doses of kainic acid in the mouse hippocampus, to get insight into the role of zinc under overexcitation. Swiss male mice were injected with kainic acid (15 mg/kg, i.p.) 15 min prior to sodium dietyldithiocarbamate (150 mg/kg, i.p.), and left to survive for 6 h, 1 day, 4 days, or 7 days after the treatment. Cell damage was analyzed with the hematoxylin-eosin and acid fuchsin stainings. Neither control animals treated only with kainic acid nor those treated only with sodium dietyldithiocarbamate suffered seizures or neuronal damage. By contrast, the kainic acid+sodium dietyldithiocarbamate-treated animals showed convulsive behavior and cell death involving the hilus, CA3, and CA1 regions. Pretreatment with the N-methyl-D-aspartate receptor antagonist MK801 (1 mg/kg, i.p.) completely prevented neuronal damage. Experiments combining different doses of sodium dietyldithiocarbamate and kainic acid with different administration schedules demonstrated that the overlap of zinc chelation and overexcitation is necessary to trigger the observed effects. Moreover, the treatment with a high dose of sodium dietyldithiocarbamate (1000 mg/kg), which produced a complete bleaching of the Timm staining for approximately 12 h, highly increased the sensitivity of animals to kainic acid. Altogether, our results indicate that the actions of sodium dietyldithiocarbamate are based on a reduction of zinc levels, which under overexcitation conditions induce seizures and neuronal damage. These findings fully support a protective role for synaptically released zinc during high neuronal activity, most probably mediated by its inhibitory actions on N-methyl-D-aspartate receptors, and argue against a direct action of synaptic zinc on the observed neuronal damage.

Zinc, magnesium and copper profiles in three experimental models of epilepsy

Trace metals are involved in the mechanisms of CNS excitability, including epilepsy. In this study, atomic absorption spectrophotometry was used to determine concentrations of Mg(2+), Cu(2+) and Zn(2+) in plasma (microg/ml) and hair (microg/g) samples. Differential profiles of trace metals were detected in rats displaying three different kinds of seizures, i.e. acute audiogenic seizures (generalized tonic-clonic type GTC) and audiogenic kindling (limbic type; LS) in Wistar Audiogenic Rats (WARs) and electroshock-induced seizures (ES) in Wistar non-epileptic rats (resistant). Significantly lower Zn(2+) concentrations were observed in the plasma of WARs (0.80+/-0.02) compared with resistants (0.89+/-0.03) in the basal (non-seizing) condition. After GTC, WARs showed lower Zn(2+) levels (0.64+/-0.12) while both Mg(2+) (12.56+/-1.51) and Cu(2+) (0.81+/-0.14) were higher than in non-seizing WARs. After ES-induced seizures only Mg(2+) changed, being higher than in the basal condition (11.78+/-2.25 and 8.90+/-0.95). In hair, basal levels of Mg(2+) and Cu(2+) (192.49+/-36.73 and 13.33+/-1.76) were higher whereas Zn(2+) (136.53+/-15.67) was lower in WARs than in resistants. WARs submitted to 0, 3 and 25 stimuli presented higher Mg(2+) concentrations as the number of stimuli increased. In animals receiving the same number of stimuli, Zn(2+) levels were higher for animals displaying GTC (151.09+/-5.53) than those displaying LS (128.07+/-8.51). In conclusion, seizure type (limbic or generalized tonic-clonic) and number of stimuli seem to be the determinant factors for changes in Zn(2+) and Mg(2+) levels, respectively.

Seizures and neuronal damage in mice lacking vesicular zinc

Synaptically released zinc has neuromodulatory capabilities that could result in either inhibition or enhancement of neuronal excitability. To determine the net effects of vesicular zinc release in the brain in vivo, we examined seizure susceptibility and seizure-related neuronal damage in mice with targeted disruption of the gene encoding the zinc transporter, ZnT3 (ZnT3-/- mice). ZnT3-/- mice, which lack histochemically reactive zinc in synaptic vesicles, had slightly higher thresholds to seizures elicited by the GABA(A) antagonist, bicuculline, and no differences in seizure threshold were seen in response to pentylenetetrazol or flurothyl. However, ZnT3-/- mice were much more susceptible than wild-type mice to limbic seizures elicited by kainic acid, suggesting that the net effect of hippocampal zinc on acute seizures in vivo is inhibitory. The hippocampi of ZnT3-/- mice showed typical seizure-related neuronal damage in response to kainic acid, demonstrating that damage to the targets of zinc-containing neurons can occur independently of synaptically released zinc. Mice lacking the neuronal zinc-binding protein metallothionein III (MT-III) are also more susceptible to kainic acid-induced seizures. Double knockout (ZnT3 and MT3) mice show the same response to kainic acid as ZnT3-/- mice, suggesting that ZnT3 and MT-III function in the same pathway.

Immunocytochemical analysis of glutamate and GABA in selectively bred mice

Withdrawal Seizure Prone (WSP) and Withdrawal Seizure Resistant (WSR) mice have been selectively bred for differential ethanol withdrawal handling-induced convulsions (HICs). In addition, it has been observed that WSP mice exhibit drug-naive HICs. This latter finding suggests that WSP and WSR mice differ in their susceptibility to HICs. Alterations in the glutamate and gamma-aminobutyric acid (GABA) systems have been implicated in convulsive activity and have been proposed to underlie the manifestation of ethanol withdrawal symptoms. It is therefore possible that WSP and WSR mice are genetically different with respect to their glutamatergic and/or GABAergic systems. To test this hypothesis, we have analyzed WSP and WSR mice that are both drug- and HIC-naive for differences in the density of nerve terminal glutamate and GABA immunoreactivity within the CA1 subfield of the hippocampus (CA1) and layer II of the somatosensory cortex (SSC). The major finding of this study is that drug- and HIC-naive WSP mice exhibit a significantly greater density of presynaptic glutamate immunoreactivity associated with asymmetric synapses within the CA1, but not the SSC, when compared to WSR mice. The density of GABA immunoreactivity within nerve terminals associated with symmetric synapses does not differ between the selected lines in either brain region. Since prior drug exposure and HICs cannot account for the observed differences in these naive mice, the results strongly suggest that the density of nerve terminal glutamate immunoreactivity within the CA1 is a reflection of inherent genetic differences between WSP and WSR mice. Furthermore, an elevated density of presynaptic glutamate immunoreactivity may be an underlying neurochemical correlate to increased susceptibility to drug-naive and ethanol withdrawal convulsions.

Disruption of the metallothionein-III gene in mice: analysis of brain zinc, behavior, and neuron vulnerability to metals, aging, and seizures

Metallothionein-III (MT-III), a brain-specific member of the metallothionein family of metal-binding proteins, is abundant in glutamatergic neurons that release zinc from their synaptic terminals, such as hippocampal pyramidal neurons and dentate granule cells. MT-III may be an important regulator of zinc in the nervous system, and its absence has been implicated in the development of Alzheimer's disease. However, the roles of MT-III in brain physiology and pathophysiology have not been elucidated. Mice lacking MT-III because of targeted gene inactivation were generated to evaluate the neurobiological significance of MT-III. MT-III-deficient mice had decreased concentrations of zinc in several brain regions, including hippocampus, but the pool of histochemically reactive zinc was not disturbed. Mutant mice exhibited normal spatial learning in the Morris water maze and were not sensitive to systemic zinc or cadmium exposure. No neuropathology or behavioral deficits were detected in 2-year-old MT-III-deficient mice, but the age-related increase in glial fibrillary acidic protein expression was more pronounced in mutant brain. MT-III-deficient mice were more susceptible to seizures induced by kainic acid and subsequently exhibited greater neuron injury in the CA3 field of hippocampus. Conversely, transgenic mice containing elevated levels of MT-III were more resistant to CA3 neuron injury induced by seizures. These observations suggest a potential role for MT-III in zinc regulation during neural stimulation.

Zinc deficiency and corticosteroids in the pathogenesis of alcoholic brain dysfunction--a review

Chronic alcoholism is associated with hypercortisolemia and low serum zinc (Zn). Hypercortisolemia could be responsible for alcoholic cerebral atrophy and is also associated with enhanced NMDA neurotoxicity. It is hypothesized that low brain Zn, noted in chronic alcoholics, enhances NMDA excitotoxicity and ethanol withdrawal seizure susceptibility. Also, Zn deficiency can produce neuronal damage through increased free radical formation. Clinically, Zn replacement therapy may be a rational approach to the treatment of alcohol withdrawal seizures and alcohol-related brain dysfunction.

Audiogenic seizure susceptibility in WSP and WSR mice

Mice selectively bred for susceptibility (WSP, withdrawal seizure prone) and resistance (WSR, withdrawal seizure resistant) to ethanol (EtOH) withdrawal seizures were tested for susceptibility to audiogenic seizures (AGS). The seizure response of mice was studied at four ages: 17, 22, 28, and 71-78 days. WSR mice exhibited no response at any age, whereas WSP mice were sensitive on days 17, 22, and 28. The maximum number of WSP mice responding to audiogenic stimulation was observed on day 22. However, the frequency and severity of responses by WSP mice was less than that of DBA/2J mice tested under identical conditions (60 vs. 100% showing at least some response). Overall, these data suggest that susceptibility to AGS and handling-induced convulsions (HIC) during EtOH withdrawal may share some common genetic determinants and presumably some common neurochemical systems. Various treatments have been shown to enhance HIC more in WSP as compared with WSR mice. Acoustic stimulation did not induce AGS in adult mice, but the treatment significantly enhanced HIC in WSP but not WSR mice. These data strongly imply that some common neurochemical pathway may regulate susceptibility to HIC elicited by diverse treatments.

Genetic animal models of alcohol and drug abuse

Behavioral and pharmacological responses of selectively bred and inbred rodent lines have been analyzed to elucidate many features of drug sensitivity and the adverse effects of drugs, the underlying mechanisms of drug tolerance and dependence, and the motivational states underlying drug reward and aversion. Genetic mapping of quantitative trait loci (QTLs) has been used to identify provisional chromosomal locations of genes influencing such pharmacological responses. Recent advances in transgenic technology, representational difference analysis, and other molecular methods now make feasible the positional cloning of QTLs that influence sensitivity to drugs of abuse. This marks a new period of synthesis in pharmacogenetic research, in which networks of drug-related behaviors, their underlying pharmacological, physiological, and biochemical mechanisms, and particular genomic regions of interest are being identified.

Chelation of zinc by diethyldithiocarbamate facilitates bursting induced by mixed antidromic plus orthodromic activation of mossy fibers in hippocampal slices

The effect of chelation of zinc by diethyldithiocarbamate (DEDTC) on bursting of CA3 pyramidal cells induced by mixed antidromic plus orthodromic activation of mossy fibers (MP) in hippocampal slices was studied. Slices perfused in artificial cerebrospinal fluid (ACSF) with high (2.5 mM) Ca2+ rarely exhibited triggered bursting following a series of stimulus trains similar to those used in kindling. In contrast, slices perfused with DEDTC (0.1 mM) in ACSF and subsequently perfused with ACSF alone prior to initiating the stimulus trains exhibited robust triggered bursting following the stimulus trains. However, if slices perfused with ACSF containing DEDTC were then perfused with ACSF containing zinc chloride (0.5 microM) followed by ACSF alone, triggered bursting was not induced subsequent to delivering stimulus trains. It is concluded that release of zinc from the mossy fibers induced by tetanic stimulation serves to obtund bursting in CA3 pyramidal cells.

Olfactory bulb kindling in mice susceptible and resistant to ethanol withdrawal

The relation between kindling and susceptibility to ethanol withdrawal seizures was investigated using withdrawal seizure-prone (WSP) and withdrawal seizure-resistant (WSR) mice. These lines were developed by selective breeding to be prone and resistant, respectively, to handling-induced convulsions after chronic exposure to ethanol. Development of kindled seizures in response to electrical stimulation of the olfactory bulb was investigated in mice aged 2 and 8 months with no exposure to ethanol. Older WSP mice kindled more slowly than older WSR mice, requiring significantly more stimulations to reach the first stage 3 and the first stage 5 seizures. In younger mice, there was no significant difference between the two lines in the rate of kindling. The lower kindling rate in mature WSP mice is in contrast to their higher sensitivity to handling-induced convulsions on withdrawal from ethanol and other agents. This finding suggests that separate genetic factors underlie these two models of mouse seizures.

Selective breeding for alcohol withdrawal severity

Mouse lines have been genetically selected to be alcohol Withdrawal Seizure Prone (WSP) or Resistant (WSR). The selection index is the severity of withdrawal handling-induced convulsions seen after removal of mice from chronic exposure to ethanol vapor. Behavioral, pharmacological, and neurochemical results from a replicated bidirectional selection project are reviewed. In reciprocal F1 crosses of the WSP and WSR lines, substantial dominance for resistance to withdrawal was found in both replicated sets of lines. WSP and WSR mice differ principally, and markedly, in traits related to the severity of withdrawal from alcohols and other drugs with depressant properties. This suggests that genes influencing severity of withdrawal from chronic ethanol exposure also pleiotropically influence genetic susceptibility to dependence on other drugs of abuse. However, the results of WSP vs. WSR comparisons for traits related to ethanol sensitivity and tolerance development suggest control in large part by genes different from those influencing withdrawal severity.

Neurons of origin of zinc-containing pathways and the distribution of zinc-containing boutons in the hippocampal region of the rat

Recent methods allow the study of neurons that contain zinc in synaptic vesicles of their boutons (Timm-stainable boutons) by the intravital precipitation (local or throughout the CNS) of the vesicular zinc with selenium compounds and its subsequent retrograde transport to the parent neurons, where the precipitate can be silver enhanced. The present study is a description of the distribution of zinc-containing neurons, their possible connections and their terminal fields within the hippocampal region of the rat. Problems inherent to the methods are addressed. Finally, based on the results and a review of literature, the possible function of zinc in the hippocampal region is considered. Neurons which contain silver-enhanced precipitates were observed in layers II, V and VI of the lateral entorhinal area and in layers V and VI of the medial entorhinal area. In the parasubiculum, labeled cells were seen in layer II/III of the parasubiculum a and in layer V. Labeled cells in the presubiculum were concentrated in layers III and V, in the hippocampal pyramidal cell layer and the dentate granule cell layer, but neurons containing precipitates were largely absent from the subiculum. Zinc-containing axonal boutons defined subpopulations within principal hippocampal neuron populations. Within layer II of the lateral entorhinal cortex and the pyramidal cell layer for regio inferior deeply situated neurons were labeled, whereas superficially placed pyramidal cells were labeled in regio superior. The neuropil staining described in the present study corresponded to that found in earlier studies. However, glial and vascular staining or unspecific background were largely absent, and the neuropil staining could unequivocally be identified light microscopically. Methodological problems are most prominently reflected in unstained mossy fibers in some animals. Based on series from animals treated with decreasing doses of sodium selenite and increased survival times, this problem can be related to small amounts of circulating reactive selenium and a competition of zinc compartments (vesicles) for the selenium. Staining will fail where the competition prevents individual compartments from reaching a threshold amount of zinc precipitate for silver amplification. A guide to evaluate histological material is provided. The distribution of zinc-containing boutons and their cells of origin indicate that zinc-containing and zinc-negative projections are not organized as parallel pathways. The mossy fibers provide an example of a pure zinc-containing pathway. Projections from regio superior to the dorsal presubiculum are likely to be zinc-negative while projections from the same area to the subiculum are zinc-containing.(ABSTRACT TRUNCATED AT 400 WORDS)

Genetic approaches to drug dependence

Pharmacogenetic studies with drugs of abuse are proliferating. Many genetic animal models are now available for studies of the mechanisms of action of a variety of drugs. These models provide unique, genetically defined populations of extremely sensitive and insensitive animals for neuropharmacological analyses. John Crabbe and John Belknap describe how molecular biological methods are being applied to these models in combination with more traditional genetic mapping strategies to identify single genes of importance to drug effects. Pharmacogenetic approaches offer the hope of establishing commonalities of mechanisms among abused drugs.