Systemic Administration Of Kainate Research Articles

Prophylactic Administration of Cannabidiol Reduces Microglial Inflammatory Response to Kainate-Induced Seizures and Neurogenesis

Microglia, the dynamic innate immune cells of the central nervous system, become activated in epilepsy. The process of microglial activation in epilepsy results in the creation of an inflammatory environment around the site of seizure onset, which contributes to the epileptogenic process and epilepsy progression. Cannabidiol (CBD) has been effective for use as an adjunctive treatment for two severe pediatric seizure disorders. Newly recognized as an Food and Drug Administration (FDA)-approved drug treatment in epilepsy, it has gained in popularity primarily for pain management. Although CBD is readily available in stores and online retailers, its mechanism of action and specifically its effects on microglia and their functions are yet fully understood. In this study, we examine the effects of commercially available CBD on microglia inflammatory activation and neurogenic response, in the presence and absence of seizures. We use systemic administration of kainate to elicit seizures in mice, which are assessed behaviorally. Artisanal CBD is given in different modes of administration and timing to dissect its effect on seizure intensity, microglial activation and aberrant seizure-related neurogenesis. CBD significantly dampens microglial migration and accumulation to the hippocampus. While long term artisanal CBD use does not prevent or lessen seizure severity, CBD is a promising adjunctive partner for its ability to depress epileptogenic processes. These studies indicate that artisanal CBD is beneficial as it both decreases inflammation in the CNS and reduces the number of ectopic neurons deposited in the hippocampal area post seizure.

Inverse Agonism of Cannabinoid Receptor Type 2 Confers Anti-inflammatory and Neuroprotective Effects Following Status Epileptics.

Prolonged status epilepticus (SE) in humans causes high mortality and brain inflammation-associated neuronal injury and morbidity in survivors. Currently, the only effective treatment is to terminate the seizures swiftly to prevent brain damage. However, reliance on acute therapies alone would be imprudent due to the required short response time. Follow-on therapies that can be delivered well after the SE onset are in an urgent need. Cannabinoid receptor type 2 (CB2), a G protein-coupled receptor that can be expressed by activated brain microglia, has emerged as an appealing anti-inflammatory target for brain conditions. In the current study, we reported that the CB2 inverse agonism by our current lead compound SMM-189 largely prevented the rat primary microglia-mediated inflammation and showed moderate neuroprotection against N-methyl-D-aspartic acid (NMDA) receptor-mediated excitotoxicity in rat primary hippocampal cultures containing both neurons and glia. Using a classical mouse model of epilepsy, in which SE was induced by systemic administration of kainate (30mg/kg, i.p.) and proceeded for 1h, we demonstrated that SE downregulated the CB1 but slightly upregulated CB2 receptor in the hippocampus. Transient treatment with SMM-189 (6mg/kg, i.p., b.i.d.) after the SE was interrupted by diazepam (10mg/kg, i.p.) prevented the seizure-induced cytokine surge in the brain, neuronal death, and behavioral impairments 24h after SE. Our results suggest that CB2 inverse agonism might provide an adjunctive anti-inflammatory therapy that can be delivered hours after SE onset, together with NMDA receptor blockers and first-line anti-convulsants, to reduce brain injury and functional deficits following prolonged seizures.

Neuroprotective and anti-inflammatory roles of the phosphatase and tensin homolog deleted on chromosome Ten (PTEN) Inhibition in a Mouse Model of Temporal Lobe Epilepsy.

Excitotoxic damage represents the major mechanism leading to cell death in many human neurodegenerative diseases such as ischemia, trauma and epilepsy. Caused by an excess of glutamate that acts on metabotropic and ionotropic excitatory receptors, excitotoxicity activates several death signaling pathways leading to an extensive neuronal loss and a consequent strong activation of astrogliosis. Currently, the search for a neuroprotective strategy is aimed to identify the level in the signaling pathways to block excitotoxicity avoiding the loss of important physiological functions and side effects. To this aim, PTEN can be considered an ideal candidate: downstream the excitatory receptors activated in excitotoxicity (whose inhibition was shown to be not clinically viable), it is involved in neuronal damage and in the first stage of the reactive astrogliosis in vivo. In this study, we demonstrated the involvement of PTEN in excitotoxicity through its pharmacological inhibition by dipotassium bisperoxo (picolinato) oxovanadate [bpv(pic)] in a model of temporal lobe epilepsy, obtained by intraperitoneal injection of kainate in 2-month-old C57BL/6J male mice. We have demonstrated that inhibition of PTEN by bpv(pic) rescues neuronal death and decreases the reactive astrogliosis in the CA3 area of the hippocampus caused by systemic administration of kainate. Moreover, the neurotoxin administration increases significantly the scanty presence of mitochondrial PTEN that is significantly decreased by the administration of the inhibitor 6 hr after the injection of kainate, suggesting a role of PTEN in mitochondrial apoptosis. Taken together, our results confirm the key role played by PTEN in the excitotoxic damage and the strong anti-inflammatory and neuroprotective potential of its inhibition.

Intermittent Hypobaric Hypoxia Induces Neuroprotection in Kainate-Induced Oxidative Stress in Rats

Severe hypoxia induces oxidative stress, which can lead to brain injury. In this study, we wanted to determine whether intermittent hypobaric hypoxia induces oxidative stress in the brain. In adult rats exposed to 380 mmHg in a hypobaric chamber for 3 h/day for 6 days, we determined the levels of malondialdehyde and nitric oxide derivatives in the brain, which indicated that there was no oxidative stress. The levels of N-acetylaspartate indicated that there was no neuronal loss or mitochondrial dysfunction and finally because apoptotic proteins such as caspase-3 and nuclear factor-kappa B (NF-κB) were not activated, apoptosis was probably not induced. The increase in the expression of erythropoietin (EPO) in the brain of rats exposed to hypoxia confirms the efficacy of the method used to induce hypoxia in the brain. Because EPO have antioxidant effects on the brain, the results suggest that intermittent hypoxia can increase the antioxidant capacity of the brain. This effect of intermittent hypoxia was studied using the systemic administration of kainate, as a model of brain oxidative stress. Kainate treatment induces oxidative stress in the brain, which is measured by an increase in lipid peroxidation and nitric oxide. Furthermore, in rats treated with kainate, both caspase-3 and NF-κB activity increased. However, in rats previously exposed to intermittent hypobaric hypoxia, 3 h per day for 6 days, the effect of kainate treatment resulted in the reduction of both oxidative stress and apoptotic activity. This study demonstrates that intermittent hypobaric hypoxia can increase brain antioxidant capacity in rats and induces neuroprotection in kainate-induced oxidative injury.

New mechanism for glutamate hypothesis in epilepsy

Epilepsy is a broad range of neurological conditions that are manifested as seizures. Two major hypotheses—glutamate and potassium—have been proposed for the mechanism of epilepsy development (Fisher et al., 1976; During and Spencer, 1993). Although both hypotheses have some evidence to support, the relative contribution of potassium and glutamate to epilepsy has not been determined. Glutamate is a major excitatory neurotransmitter in the brain and an immediate precursor for GABA in neurons and glutamine in astrocytes. Glutamate is differentially compartmentalized and metabolized via different enzymes by astrocytes and neurons and exogenous and endogenous glutamate is handled distinctively by them (McKenna, 2007). Elevated levels of glutamate have been reported in human brain tissues and animal models of epilepsy, and it is known that glutamate-induced excitotoxicity causes the neuronal death in epilepsy (Haglid et al., 1994; Coulter and Eid, 2012 for detail). The glutamate-glutamine cycle is a major recycling mechanism of glutamate and GABA in the brain. A glutamate degrading enzyme, glutamine synthetase (GS) has been shown to be deficient in astrocytes in the epileptogenic hippocampal formation in a subset of patients with temporal lobe epilepsy (TLE) (Eid et al., 2004). This GS deficiency leads to increased glutamate levels in astrocytes as well as elevated concentrations of extracellular glutamate. Rats chronically infused with methionine sulfoximine, a GS inhibitor, showed increased glutamate in astrocytes (Perez et al., 2012). Increased glutamate release from neurons and astrocytes and/or impaired removal of glutamate in the extra-cellular space (e.g., synaptic cleft) could raise glutamate level. Glutamate clearance is mainly performed by glutamate transporters that move glutamate and potassium across the plasma membrane (Had-Aissouni, 2012). The astroglial sodium-dependent glutamate transporter-1 (GLT-1 a.k.a. EAAT2) is the major glutamate uptake molecule in the brain, and either malfunction and/or down-regulation of GLT-1 could cause elevated glutamate level. The fact that GLT-1 null mice are epileptic supports GLT-1 involvement for increased glutamate (Tanaka et al., 1997). However, findings of GLT-1 level in animal models and human TLE are not consistent, and they do not seem to fully explain the elevated glutamate (Mathern et al., 1999; Crino et al., 2002; Proper et al., 2002; van der Hel et al., 2005). It is evident that astrocytes are potential sources of the excessive glutamate in TLE, however, the mechanism(s) for glutamate release from astrocytes has been controversial; either vesicular exocytosis or channel/transporter-mediated and whether calcium is involved or not (Tian et al., 2005). A recent study demonstrating two different modes of glutamate release in astrocytes provides a new way of thinking for epilepsy: TREK-1, a two-pore potassium channel, can be responsible for fast glutamate release induced by GPCR (G-protein coupled receptors) activation and Bestrophin-1 (Best1), a calcium activated anion channel for slow release (Woo et al., 2012). To detect released glutamate from astrocytes, a technique called “sniffer-patch” was used: electrophysiological recording of HEK293T cells expressing a non-desensitizing mutant (GluR1-L497Y) of AMPA receptors were co-cultured with dissociated hippocampal astrocytes. An agonist peptide for PAR1 (protease-activated receptor 1) was applied to activate G-protein in astrocytes. Thus, glutamate released from astrocytes can be measured via AMPA receptor currents. Differential subcellular localization of these two channels also raises the possibility of distinct mode of their operations in epilepsy. TREK-1 is preferentially expressed at cell bodies and processes of astrocytes, while Best1 is present close to synapses. It remains to be seen whether their expression and localization in the brain is altered in epilepsy. The involvement of TREK-1, which was identified as a potassium channel, here is particularly interesting. The potassium hypothesis of epilepsy was proposed about a half century ago (Green, 1964; Fisher et al., 1976) and inactivation mutations of several potassium channels cause human and rodent epilepsies (Benarroch, 2009). Impaired spatial potassium buffering by astrocytes will result in stronger and prolonged depolarization of glial cells and neurons in response to activity-dependent potassium release, and may thus contribute to seizure generation in this particular condition of human TLE (Hinterkeuser et al., 2000). TREK-1 null mice have increased seizure susceptibility to systemic kainate administration. Is the pore of TREK-1 permeable both to potassium and glutamate? Is there any selective mechanism of TREK-1 for one molecule over the other depending on the activating signals? The answers to these questions may aid in dissecting the relative contribution of these two molecules to hyperexcitability and epilepsy. As for Best1, the question is whether enhanced calcium signals in astrocytes directly affect Best1's function in epilepsy models (Heurteaux et al., 2004; Ding et al., 2007). Therefore, it will be very intriguing to examine the workings of TREK-1 and Best1 in animal models and human TLE.

Galanin Receptor 1 Deletion Exacerbates Hippocampal Neuronal Loss after Systemic Kainate Administration in Mice

BackgroundGalanin is a neuropeptide with a wide distribution in the central and peripheral nervous systems and whose physiological effects are mediated through three G protein-coupled receptor subtypes, GalR1, GalR2, and GalR3. Several lines of evidence indicate that galanin, as well as activation of the GalR1 receptor, is a potent and effective modulator of neuronal excitability in the hippocampus.Methodology/Principal FindingsIn order to test more formally the potential influence of GalR1 on seizure-induced excitotoxic cell death, we conducted functional complementation tests in which transgenic mice that exhibit decreased expression of the GalR1 candidate mRNA underwent kainate-induced status epilepticus to determine if the quantitative trait of susceptibility to seizure-induced cell death is determined by the activity of GalR1. In the present study, we report that reduction of GalR1 mRNA via null mutation or injection of the GalR1 antagonist, galantide, prior to kainate-induced status epilepticus induces hippocampal damage in a mouse strain known to be highly resistant to kainate-induced neuronal injury. Wild-type and GalR1 knockout mice were subjected to systemic kainate administration. Seven days later, Nissl and NeuN immune- staining demonstrated that hippocampal cell death was significantly increased in GalR1 knockout strains and in animals injected with the GalR1 antagonist. Compared to GalR1-expressing mice, GalR1-deficient mice had significantly larger hippocampal lesions after status epilepticus.Conclusions/SignificanceOur results suggest that a reduction of GalR1 expression in the C57BL/6J mouse strain renders them susceptible to excitotoxic injury following systemic kainate administration. From these results, GalR1 protein emerges as a new molecular target that may have a potential therapeutic value in modulating seizure-induced cell death.

An Electron Spin Resonance Study for Real-time Detection of Ascorbyl Free Radicals After Addition of Dimethyl Sulfoxide in Murine Hippocampus or Plasma During Kainic Acid-Induced Seizures

Electron spin resonance (ESR)-silent ascorbate solutions generate a detectable, likely concentration-dependent signal of ascorbyl free radicals (AFR) immediately upon addition of a molar excess of dimethyl sulfoxide (DMSO). We aimed to perform quantitative ESR analysis of AFR in real time after addition of DMSO (AFR/DMSO) to evaluate ascorbate concentrations in fresh hippocampus or plasma following systemic administration of kainate in mice. Use of a special tissue-type quartz cell allowed immediate detection of AFR/DMSO ESR spectra in fresh tissues from mice. AFR/DMSO content was increased significantly in fresh hippocampus or plasma obtained during kainate-induced seizures of mice, reaching maximum levels at 90 min after intraperitoneal administration of 50 mg/kg kainic acid. This suggests that oxidative injury of the hippocampus resulted from the accumulation of large amounts of ascorbic acid in the brain after kainic acid administration. AFR/DMSO content measured on an ESR spectrometer can be used for real-time evaluation of ascorbate content in fresh tissue. Due to the simplicity, good performance, low cost and real-time monitoring of ascorbate, this method may be applied to clinical research and treatment in the future.

Estrogen receptors increased expression during hippocampal neuroprotection in lactating rats

Estrogen receptor (ER)-mediated neuroprotection has been demonstrated in both in vitro and in vivo model systems. Two types of estrogen receptors, ERα and ERβ, are the major mediators of the biological functions of estrogens. In the hippocampus, ERβ is prevalent over ERα. Recently, we reported that during the final phase of lactation there is a neuroprotective mechanism in the hippocampus of the adult female rat against neuronal damage induced by systemic kainic acid administration vs. virgin (metestrus) rats. In this study, we assessed differential ER expression and localization in CA1, CA3 and dentate gyrus regions of dorsal hippocampus of metestrus and lactating adult rats at day 19 of lactation, during basal conditions (metestrus and L19, respectively) and 24 h after systemic kainate administration. ERs were assessed by western blot and immunohistochemistry. We found a significant increase in the expression of ERs in the hippocampus during lactation as compared with metestrus. ERβ was significantly increased in the CA1 and CA3 of lactating rats after the kainic acid insult. In addition, we observed a relocalization of ERβ from the cytoplasm to the nucleus of neuronal cells. Our results suggest that there is a strong correlation between expression of ERs, especially ERβ, in lactating CA1 and CA3 hippocampus regions in response to kainate administration, and neuroprotection observed during this reproductive period. This may be one of the mechanisms involved in the protection of the maternal brain to ensure offspring survival.

The direct excitatory effect of IL-1β on cerebellar Purkinje cell

Interleukin (IL)-1β is one of the important proinflammatory cytokines in neural as well as immune systems, and plays a pivotal role in the neuroinflammation. We previously demonstrated that cerebellar IL-1β is involved in kainate-induced ataxia, i.e., IL-1β was activated in the cerebellum with systemic administration of kainate, and its type I receptor (IL-1R) was expressed at a soma of cerebellar Purkinje cells. In this study, we examined the effect of IL-1β on cerebellar Purkinje cell function by recording extracellular neuronal activities in anesthetized mice. Systemic administration of kainate increased the firing rates of cerebellar Purkinje cells in normal mice but showed little effect in IL-1R-knockout (IL-1R-KO) mice. Moreover, microiontophoretic administration of IL-1β to cerebellar Purkinje cells increased the firing rates promptly in response to IL-1β. The present results demonstrate that IL-1 system exerts a direct modulatory effect on cerebellar Purkinje cells.

Galectin-1 promotes basal and kainate-induced proliferation of neural progenitors in the dentate gyrus of adult mouse hippocampus

We examined the expression of galectin-1, an endogenous lectin with one carbohydrate-binding domain, in the adult mouse hippocampus after systemic kainate administration. We found that the expression of galectin-1 was remarkably increased in activated astrocytes of the CA3 subregion and dentate gyrus of the hippocampus, and in nestin-positive neural progenitors in the dentate gyrus. Quantitative reverse transcription PCR (RT-PCR) analysis revealed that the galectin-1 mRNA level in hippocampus began to increase 1 day after kainate administration and that a 13-fold increase was attained within 3 days. Western blotting analysis confirmed that the level of galectin-1 protein increased to more than three-fold a week after the exposure. We showed that isolated astrocytes express and secrete galectin-1. To clarify the significance of the increased expression of galectin-1 in hippocampus, we compared the levels of hippocampal cell proliferation in galectin-1 knockout and wild-type mice after saline or kainate administration. The number of 5-bromo-2'-deoxyuridine (BrdU)-positive cells detected in the subgranular zone (SGZ) of galectin-1 knockout mice decreased to 62% with saline, and to 52% with kainate, as compared with the number seen in the wild-type mice. Most of the BrdU-positive cells in SGZ expressed doublecortin and neuron-specific nuclear protein, indicating that they are immature neurons. We therefore concluded that galectin-1 promotes basal and kainate-induced proliferation of neural progenitors in the hippocampus.

Protective Effect of IL-18 on Kainate- and IL-1β-Induced Cerebellar Ataxia in Mice

The pathogenesis of sporadic cerebellar ataxia remains unknown. In this study, we demonstrate that proinflammatory cytokines, IL-18 and IL-1beta, reciprocally regulate kainate-induced cerebellar ataxia in mice. We show that systemic administration of kainate activated IL-1beta and IL-18 predominantly in the cerebellum of mice, which was accompanied with ataxia. Mice deficient in caspase-1, IL-1R type I, or MyD88 were resistant to kainate-induced ataxia, while IL-18- or IL-18R alpha-deficient mice displayed significant delay of recovery from ataxia. A direct intracerebellar injection of IL-1beta-induced ataxia and intracerebellar coinjection of IL-18 counteracted the effect of IL-1beta. Our data firstly show that IL-18 and IL-1beta display differential direct regulation in kainate-induced ataxia in mice. Our results might contribute toward the development of a new therapeutic strategy for cerebellar ataxia in humans.

Enhancement of PAI-1 mRNA in cardiovascular cells after kainate injection is mediated through the sympathetic nervous system

Plasminogen activator inhibitor-1 (PAI-1) is a major physiological regulator of the fibrinolytic system and is thought to promote vascular diseases. Recently, we have reported that PAI-1 gene expression was markedly enhanced locally in cardiovascular cells immediately after injecting (i.p.) mice with kainate, an analog of glutamate, which is the principal excitatory neurotransmitter in the central nervous system. Here we investigated whether the induction of PAI-1 mRNA by kainate could be mediated through sympathetic versus parasympathetic efferent neurons. To this end, we used a group of drugs known to interfere with the aforementioned pathways. PAI-1 gene expression was monitored in the heart via in situ hybridization using 35S-labeled PAI-1-specific riboprobes. We have found that the elevation of PAI-1 mRNA levels, as detected 3 h after systemic administration of kainate, was reduced by mecamylamine, guanethidine and phentolamine, but not by propranolol or atropine. In addition, the adrenergic agonists phenylephrine and adrenaline themselves, but not clonidine, induced PAI-1 with a spatial distribution similar to that of kainate (i.e. in coronary arteries throughout the heart, and in cardiocytes in the left ventricular and atrial myocardium). Collectively, these results show that kainate activated the PAI-1 gene in cardiovascular cells primarily through the sympathetic nervous system (SNS), via the α1-adrenergic receptor. Hence, the results suggest that PAI-1 is likely to be increased during enhanced sympathetic efferent neuronal activity, such as occurring in heart failure or cardiac hypertrophy. The results also reinforce the previously reported linkage of PAI-1 to physiological stress. Furthermore, to our knowledge, this is the first demonstration that glutamate can enhance gene expression in a peripheral tissue. Thus, these findings raise the possibility that glutamate, acting via the SNS, can affect cardiovascular homeostasis and pathology by modulating gene expression in cardiac myocytes and vascular cells.

Immunohistochemical detection by immersion fixation with Carnoy solution of particular non- N-methyl- d-aspartate receptor subunits in murine hippocampus

Immunoblotting analysis revealed heterologous distribution profiles of the non- N-methyl- d-aspartate (NMDA) receptor subunits, GluR1, GluR2 and GluR6, in membrane fractions prepared from murine discrete brain structures including hippocampus. In coronal sections fixed with paraformaldehyde (PA) solution after dissection from mice perfused with 4% PA, however, no marked immunoreactivity was detected to GluR6 subunit in any hippocampal subregions, with high immunoreactivities to both GluR1 and GluR2 subunits in the strata oriens, radiatum and lacunosum-moleculare of the CA1 and CA3 subfields and the stratum moleculare of the dentate gyrus in hippocampus. In coronal, sagittal and horizontal sections fixed with Carnoy solution after dissection from animals decapitated, by contrast, high immunoreactivity was additionally detected to GluR6 subunit in the stratum lucidum of hippocampus. The systemic administration of kainate not only resulted in marked neuronal losses along the CA1–CA4 pyramidal layers 1 week later, but also led to significant decreases in immunoreactivities to GluR1, GluR2 and GluR6 subunits in the CA1 and CA3 subfields on brain coronal sections prepared by immersion fixation with Carnoy solution. These results suggest that immersion fixation with Carnoy solution may be suitable and appropriate for reproducible and quantitative immunohistochemical detection of particular non-NMDA receptor subunits in murine hippocampus.

Concomitant distribution shift of glial GABA transporter and S100 calcium-binding proteins in the rat retina after kainate-induced excitotoxic injury

The goal of this study was to elucidate the involvement of neuronal and glial calcium-binding proteins in the stimulation of γ-aminobutyric acid (GABA) transport system by kainate-induced excitotoxicity in the rat retina. We used immunohistochemical method to assess the localization of GABA reuptake and calcium-binding proteins. After systemic administration of kainate, the neuronal GABA transporter does not show an association with calbindin D-28K. However, the localization of the GAT-3 transport system in Müller glial cells is closely correlated with the S100 proteins interacting with glial fibrillary acidic protein (GFAP) in response to kainate injury. Furthermore, we demonstrate that kainate-mediated excitotoxicity induced concomitant distribution shift of glial GABA transporter, S100 proteins and GFAP in the distal processes and endfeet of glial cells during the first 48 h.

Concomitant distribution shift of glial GABA transporter and S100 calcium-binding proteins in the rat retina after kainate-induced excitotoxic injury

The goal of this study was to elucidate the involvement of neuronal and glial calcium-binding proteins in the stimulation of γ-aminobutyric acid (GABA) transport system by kainate-induced excitotoxicity in the rat retina. We used immunohistochemical method to assess the localization of GABA reuptake and calcium-binding proteins. After systemic administration of kainate, the neuronal GABA transporter does not show an association with calbindin D-28K. However, the localization of the GAT-3 transport system in Müller glial cells is closely correlated with the S100 proteins interacting with glial fibrillary acidic protein (GFAP) in response to kainate injury. Furthermore, we demonstrate that kainate-mediated excitotoxicity induced concomitant distribution shift of glial GABA transporter, S100 proteins and GFAP in the distal processes and endfeet of glial cells during the first 48 h.

Selective calcification of rat brain lesions caused by systemic administration of kainic acid.

Dystrophic calcification of previously damaged areas of nervous tissue occurs in a wide range of human diseases. The relationship between astroglial and microglial reactions and deposits of calcium salts was studied for up to five months in rats with a brain lesion produced by systemic administration of kainate. The morphology and atomic composition of the calcium salt deposits was also studied. Two types of lesions, sclerotic and liquefactive, were observed. In sclerotic lesions hyperplasia and hypertrophy of astrocytes partially substituted for the lost neurons, reaching a maximum in about twenty-five days after treatment. In liquefactive lesions, the astrocytic reaction occurred only around the liquefactive area. Microglial reaction was similar in both types of lesion and reached its highest expression in about twenty-five days. Calcium deposits were observed in the sclerotic but not in the liquefactive lesions. Clearly distinguishable granules of calcium salts were observed in sclerotic lesions under scanning electron microscopy after only five days post-injection. The size of calcified granules increased with time reaching 40 micro m or more in diameter at five months. The atomic composition of these deposits, studied by X-ray microanalysis, showed a time-dependent increase in calcium concentration. While there was no clear relationship between astroglial and microglial reactions and calcium salt deposits, the systemic injection of kainate produced progressively larger and more concentrated calcium deposits in sclerotic, but not in liquefactive lesions.

Immersion fixation with Carnoy solution for conventional immunohistochemical detection of particular N-methyl-D-aspartate receptor subunits in murine hippocampus.

Immunoblotting analysis revealed heterologous distribution profiles of the N-methyl-D-aspartate (NMDA) receptor subunits GluR zeta-1, GluR epsilon-1, and GluR epsilon-2 in membrane preparations of different murine brain structures, with exclusive detection of GluR epsilon-3 subunit in cerebellar preparations. Mice were anesthetized and perfused with 4% paraformaldehyde (PA), Zamboni, or Carnoy solution for subsequent immunohistochemical detection of these NMDA receptor subunits. In coronal brain sections from animals perfused with 4% PA and Zamboni solutions, high immunoreactivity was detected exclusively with GluR zeta-1, GluR epsilon-1, GluR epsilon-2, and GluR epsilon-3 subunits in the pyramidal and dentate granular layers, where the GluR epsilon-3 subunit is supposed to be absent. By contrast, high immunoreactivity was detected with GluR zeta-1, GluR epsilon-1, and GluR epsilon-2, but not GluR epsilon-3, subunits in the strata oriens and radiatum of the CA1 subfield without immunoreactivity along the pyramidal and granular layers when sections were prepared by immersion fixation with Carnoy solution after dissection from brains of mice decapitated. On these sections, relatively high immunoreactivity was found also with GluR zeta-1, GluR epsilon-1, and GluR epsilon-2 subunits in the stratum lacunosum-moleculare of the CA1 region, the strata oriens, radiatum, and lacunosum-moleculare of the CA3 region, and the stratum moleculare of the dentate gyrus, respectively. The systemic administration of kainate led to significant decreases in immunoreactivity to GluR zeta-1, GluR epsilon-1, and GluR epsilon-2 subunits in the CA1 and CA3 subfields on brain sections prepared by immersion fixation with Carnoy solution. These results suggest that immersion fixation with Carnoy solution may be suitable and appropriate for reproducible and quantitative immunohistochemical detection of particular NMDA receptor subunits in murine hippocampus.

In vivo neuroprotective role of NMDA receptors against kainate-induced excitotoxicity in murine hippocampal pyramidal neurons.

Activation of NMDA receptors has been shown to induce either neuronal cell death or neuroprotection against excitotoxicity in cultured cerebellar granule neurons in vitro. We have investigated the effects of pretreatment with NMDA on kainate-induced neuronal cell death in mouse hippocampus in vivo. The systemic administration of kainate (30 mg/kg), but not NMDA (100 mg/kg), induced severe damage in pyramidal neurons of the hippocampal CA1 and CA3 subfields 3-7 days later, without affecting granule neurons in the dentate gyrus. An immunohistochemical study using an anti-single-stranded DNA antibody and TdT-mediated dUTP nick end labeling analysis both revealed that kainate, but not NMDA, induced DNA fragmentation in the CA1 and CA3 pyramidal neurons 1-3 days after administration. Kainate-induced neuronal loss was completely prevented by the systemic administration of NMDA (100 mg/kg) 1 h to 1 day previously. No pyramidal neuron was seen with fragmented DNA in the hippocampus of animals injected with kainate 1 day after NMDA treatment. The neuroprotection mediated by NMDA was prevented by the non-competitive NMDA receptor antagonist MK-801. Taken together these results indicate that in vivo activation of NMDA receptors is capable of protecting against kainate-induced neuronal damage through blockade of DNA fragmentation in murine hippocampus.

Localization of activator protein-1 complex with DNA binding activity in mitochondria of murine brain after in vivo treatment with kainate.

To elucidate mechanisms underlying mitochondrial dysfunctions induced by glutamate, we have examined the effects of in vivo treatment with the ionotropic glutamate receptor agonist kainate on localization of the transcription factor activator protein-1 (AP-1) in mitochondria as well as nuclei of murine brain. A systemic administration of kainate dramatically enhanced AP-1 DNA binding in both mitochondrial and nuclear extracts of mouse cerebral cortex and hippocampus 1 hr to 3 d later. Unlabeled AP-1 probe selectively competed for AP-1 DNA binding in mitochondrial extracts of cortex and hippocampus obtained from mice injected with kainate. Supershift and immunoblotting analyses revealed participation of c-Fos, Fos-B, and Jun-B proteins in potentiation by kainate of mitochondrial AP-1 DNA binding in cortex and hippocampus. An immunohistochemical study demonstrated marked expression by kainate of c-Fos protein in the pyramidal and dentate granular layers, whereas an immunoelectron microscopic analysis showed localization of c-Fos protein within mitochondria, as well as nuclei, of the CA1 pyramidal and dentate granular cells in hippocampus obtained 2 hr after the administration of kainate. Mitochondrial AP-1 DNA binding was inhibited by particular unlabeled oligonucleotides containing sequences similar to the AP-1 site found in the noncoding region of mitochondrial DNA. Kainate markedly potentiated binding of radiolabeled oligonucleotide probes containing sequences effective in competing for AP-1 DNA binding in hippocampal mitochondrial extracts. These results suggest that kainate may facilitate expression of the AP-1 complex and subsequent translocation into mitochondria to participate in mechanisms associated with transcriptional regulation of mitochondrial DNA in murine hippocampus.

Localization of Activator Protein-1 Complex with DNA Binding Activity in Mitochondria of Murine Brain afterIn VivoTreatment with Kainate

To elucidate mechanisms underlying mitochondrial dysfunctions induced by glutamate, we have examined the effects ofin vivotreatment with the ionotropic glutamate receptor agonist kainate on localization of the transcription factor activator protein-1 (AP-1) in mitochondria as well as nuclei of murine brain. A systemic administration of kainate dramatically enhanced AP-1 DNA binding in both mitochondrial and nuclear extracts of mouse cerebral cortex and hippocampus 1 hr to 3 d later. Unlabeled AP-1 probe selectively competed for AP-1 DNA binding in mitochondrial extracts of cortex and hippocampus obtained from mice injected with kainate. Supershift and immunoblotting analyses revealed participation of c-Fos, Fos-B, and Jun-B proteins in potentiation by kainate of mitochondrial AP-1 DNA binding in cortex and hippocampus. An immunohistochemical study demonstrated marked expression by kainate of c-Fos protein in the pyramidal and dentate granular layers, whereas an immunoelectron microscopic analysis showed localization of c-Fos protein within mitochondria, as well as nuclei, of the CA1 pyramidal and dentate granular cells in hippocampus obtained 2 hr after the administration of kainate. Mitochondrial AP-1 DNA binding was inhibited by particular unlabeled oligonucleotides containing sequences similar to the AP-1 site found in the noncoding region of mitochondrial DNA. Kainate markedly potentiated binding of radiolabeled oligonucleotide probes containing sequences effective in competing for AP-1 DNA binding in hippocampal mitochondrial extracts. These results suggest that kainate may facilitate expression of the AP-1 complex and subsequent translocation into mitochondria to participate in mechanisms associated with transcriptional regulation of mitochondrial DNA in murine hippocampus.