Kainic Acid-induced Neuronal Death Research Articles

TCD, a triterpenoid isolated from wild bitter gourd, reduces synaptosomal release of glutamate and protects against kainic acid-induced neuronal death.

3β,7β,25-Trihydroxycucurbita-5,23(E)-dien-19-al (TCD) is a triterpenoid isolated from wild bitter gourd that is a common tropical vegetable with neuroprotective effects. Because excessive glutamate release is a major cause of neuronal damage in various neurological disorders, the aims of this study were to examine the effect of TCD on glutamate release in vitro and to examine the effect of TCD in vivo. In rat cerebrocortical synaptosomes, TCD reduced 4-aminopyridine (4-AP)-stimulated glutamate release and Ca2+ concentration elevation, but had no effect on plasma membrane potential. TCD-mediated inhibition of 4-AP-induced glutamate release was dependent on the presence of extracellular calcium; persisted in the presence of the glutamate transporter inhibitor dl-TBOA, P/Q-type Ca2+ channel blocker ω-agatoxin IVA, and intracellular Ca2+-releasing inhibitors dantrolene and CGP37157; and was blocked by the vesicular transporter inhibitor bafilomycin A1 and the N-type Ca2+ channel blocker ω-conotoxin GVIA. Molecular docking studies have demonstrated that TCD binds to N-type Ca2+ channels. TCD-mediated inhibition of 4-AP-induced glutamate release was abolished by the Ca2+-dependent protein kinase C (PKC) inhibitor Go6976, but was unaffected by the Ca2+-independent PKC inhibitor rottlerin. Furthermore, TCD considerably reduced the phosphorylation of PKC, PKCα, and myristoylated alanine-rich C kinase substrate, a major presynaptic substrate for PKC. In a rat model of kainic acid (KA)-induced excitotoxicity, TCD pretreatment substantially attenuated KA-induced neuronal death in the CA3 hippocampal region. These results suggest that TCD inhibits synaptosomal glutamate release by suppressing N-type Ca2+ channels and PKC activity and exerts protective effects against KA-induced excitotoxicity in vivo.

Melatonin Mediates Protective Effects against Kainic Acid-Induced Neuronal Death through Safeguarding ER Stress and Mitochondrial Disturbance.

Kainic acid (KA)-induced neuronal death is linked to mitochondrial dysfunction and ER stress. Melatonin is known to protect hippocampal neurons from KA-induced apoptosis, but the exact mechanisms underlying melatonin protective effects against neuronal mitochondria disorder and ER stress remain uncertain. In this study, we investigated the sheltering roles of melatonin during KA-induced apoptosis by focusing on mitochondrial dysfunction and ER stress mediated signal pathways. KA causes mitochondrial dynamic disorder and dysfunction through calpain activation, leading to neuronal apoptosis. Ca2+ chelator BAPTA-AM and calpain inhibitor calpeptin can significantly restore mitochondrial morphology and function. ER stress can also be induced by KA treatment. ER stress inhibitor 4-phenylbutyric acid (PBA) attenuates ER stress-mediated apoptosis and mitochondrial disorder. It is worth noting that calpain activation was also inhibited under PBA administration. Thus, we concluded that melatonin effectively inhibits KA-induced calpain upregulation/activation and mitochondrial deterioration by alleviating Ca2+ overload and ER stress.

Notch signaling in response to excitotoxicity induces neurodegeneration via erroneous cell cycle reentry.

Neurological disorders such as Alzheimer's disease, stroke and epilepsy are currently marred by the lack of effective treatments to prevent neuronal death. Erroneous cell cycle reentry (CCR) is hypothesized to have a causative role in neurodegeneration. We show that forcing S-phase reentry in cultured hippocampal neurons is sufficient to induce neurodegeneration. We found that kainic-acid treatment in vivo induces erroneous CCR and neuronal death through a Notch-dependent mechanism. Ablating Notch signaling in neurons provides neuroprotection against kainic acid-induced neuronal death. We further show that kainic-acid treatment activates Notch signaling, which increases the bioavailability of CyclinD1 through Akt/GSK3β pathway, leading to aberrant CCR via activation of CyclinD1-Rb-E2F1 axis. In addition, pharmacological blockade of this pathway at critical steps is sufficient to confer resistance to kainic acid-induced neurotoxicity in mice. Taken together, our results demonstrate that excitotoxicity leads to neuronal death in a Notch-dependent manner through erroneous CCR.

Microglial repopulation model reveals a robust homeostatic process for replacing CNS myeloid cells

Under most physiological circumstances, monocytes are excluded from parenchymal CNS tissues. When widespread monocyte entry occurs, their numbers decrease shortly after engraftment in the presence of microglia. However, some disease processes lead to focal and selective loss, or dysfunction, of microglia, and microglial senescence typifies the aged brain. In this regard, the long-term engraftment of monocytes in the microglia-depleted brain remains unknown. Here, we report a model in which a niche for myeloid cells was created through microglia depletion. We show that microglia-depleted brain regions of CD11b-HSVTK transgenic mice are repopulated with new Iba-1-positive cells within 2 wk. The engrafted cells expressed high levels of CD45 and CCR2 and appeared in a wave-like pattern frequently associated with blood vessels, suggesting the engrafted cells were peripheral monocytes. Although two times more numerous and morphologically distinct from resident microglia up to 27 wk after initial engraftment, the overall distribution of the engrafted cells was remarkably similar to that of microglia. Two-photon in vivo imaging revealed that the engrafted myeloid cells extended their processes toward an ATP source and displayed intracellular calcium transients. Moreover, the engrafted cells migrated toward areas of kainic acid-induced neuronal death. These data provide evidence that circulating monocytes have the potential to occupy the adult CNS myeloid niche normally inhabited by microglia and identify a strong homeostatic drive to maintain the myeloid component in the mature brain.

Acupuncture suppresses kainic acid-induced neuronal death and inflammatory events in mouse hippocampus

The administration of kainic acid (KA) causes seizures and produces neurodegeneration in hippocampal CA3 pyramidal cells. The present study investigated a possible role of acupuncture in reducing hippocampal cell death and inflammatory events, using a mouse model of kainic acid-induced epilepsy. Male C57BL/6 mice received acupuncture treatments at acupoint HT8 or in the tail area bilaterally once a day for 2days and again immediately after an intraperitoneal injection of KA (30mg/kg). HT8 is located on the palmar surface of the forelimbs, between the fourth and fifth metacarpal bones. Twenty-four hours after the KA injection, neuronal cell survival, the activations of microglia and astrocytes, and mRNA expression of two proinflammatory cytokines, interleukin-1β (IL-1β) and tumor necrosis factor-α (TNF-α), were measured in the hippocampus. Acupuncture stimulation at HT8, but not in the tail area, significantly reduced the KA-induced seizure, neuron death, microglial and astrocyte activations, and IL-1β mRNA expression in the hippocampus. The acupuncture stimulation also decreased the mRNA expression of TNF-α, but it was not significant. These results indicate that acupuncture at HT8 can inhibit hippocampal cell death and suppress KA-induced inflammatory events, suggesting a possible role for acupuncture in the treatment of epilepsy.

Neuroserpin Protects Neurons from Ischemia-Induced Plasmin-Mediated Cell Death Independently of Tissue-Type Plasminogen Activator Inhibition

The serine proteinase tissue-type plasminogen activator (tPA) and the serine proteinase inhibitor neuroserpin are both expressed in areas of the brain with the highest vulnerability to hypoxia/ischemia. In vitro studies show that neuroserpin inhibits tPA and, to a lesser extent, urokinase-type plasminogen activator and plasmin. Experimental middle cerebral artery occlusion (MCAO) increases tPA activity and neuroserpin expression in ischemic tissue, and genetic deficiency of tPA or either treatment with or overexpression of neuroserpin decreases the volume of the ischemic lesion following MCAO. These findings have led to the hypothesis that neuroserpin's neuroprotection is mediated by inhibition of tPA's alleged neurotoxic effect. Ischemic preconditioning is a natural adaptive process whereby exposure to a sublethal insult induces tolerance against a subsequent lethal ischemic injury. Here we demonstrate that exposure to sublethal hypoxia/ischemia increases the neuroserpin expression in the hippocampal CA1 layer and cerebral cortex, and that neuroserpin induces ischemic tolerance and decreases the volume of the ischemic lesion following MCAO in wild-type and tPA-deficient (tPA-/-) neurons and mice. Plasmin induces neuronal death, and this effect is abrogated by either neuroserpin or the NMDA receptor antagonist MK-801. Neuroserpin also attenuated kainic acid-induced neuronal death. Our data indicate that the neuroprotective effect of neuroserpin is due to inhibition of plasmin-mediated excitotoxin-induced cell death and is independent of neuroserpin's ability to inhibit tPA activity.

The time-dependent effect of lipopolysaccharide on kainic acid-induced neuronal death in hippocampal CA3 region: possible involvement of cytokines via glucocorticoid

It has been reported that glucocorticoid (Gc) can induce neuronal cell toxicity in the hippocampus. In addition, we examined that serum Gc increased by restraint stress aggravated kainic acid (KA)-induced neuronal death in hippocampal CA3 region. However, the effect of other stressful stimulus like lipopolysaccharide (LPS) increasing serum Gc on KA-induced neuronal death was not elucidated until now. Thus, we examined the time course effect of LPS on KA-induced neuronal death in the hippocampal CA3 region of mice, especially to address the role of Gc and inflammatory mediators. In the present study, we found that an aggravating effect of LPS on KA-induced neuronal death was correlated with an alteration of hippocampal IL-1β mRNA level at all time points, and the serum Gc and hippocampal IL-1β mRNA level was peak at 90 min after LPS treatment (LPS 90 min) when the aggravating effect of LPS on KA-induced neuronal death was maximum. In addition, RU38486 (glucocorticoid receptor antagonist) decreased the hippocampal IL-1β mRNA level and abolished the aggravating effect of LPS on KA-induced neuronal death at LPS 90 min and 24 h. In the immunohistochemical study, we found activated and ramified microglia (OX-42) and astrocyte (GFAP) at 24 h after LPS treatment (LPS 24 h) in the hippocampus. These results suggest that Gc itself, cytokines triggered by Gc, or both appears to be involved in the LPS effect depending on LPS pretreatment time.

Kainic Acid-induced Neuronal Death is Attenuated by Aminoguanidine but Aggravated by L-NAME in Mouse Hippocampus

Nitric oxide (NO) has both neuroprotective and neurotoxic effects depending on its concentration and the experimental model. We tested the effects of NG-nitro-L-arginine methyl ester (L-NAME), a nonselective nitric oxide synthase (NOS) inhibitor, and aminoguanidine, a selective inducible NOS (iNOS) inhibitor, on kainic acid (KA)-induced seizures and hippocampal CA3 neuronal death. L-NAME (50 mg/kg, i.p.) and/or aminoguanidine (200 mg/kg, i.p.) were administered 1 h prior to the intracerebroventricular (i.c.v.) injection of KA. Pretreatment with L-NAME significantly increased KA-induced CA3 neuronal death, iNOS expression, and activation of microglia. However, pretreatment with aminoguanidine significantly suppressed both the KA-induced and L-NAME-aggravated hippocampal CA3 neuronal death with concomitant decreases in iNOS expression and microglial activation. The protective effect of aminoguanidine was maintained for up to 2 weeks. Furthermore, iNOS knockout mice (iNOS(-/-)) were resistant to KA-induced neuronal death. The present study demonstrates that aminoguanidine attenuates KA-induced neuronal death, whereas L-NAME aggravates neuronal death, in the CA3 region of the hippocampus, suggesting that NOS isoforms play different roles in KA-induced excitotoxicity.

Edaravone prevents kainic acid-induced neuronal death

There is growing evidence that free radical generation may play a key role in the neuronal damage induced by prolonged convulsions. Free radical scavengers are known to inhibit neuronal death induced by exposure to excitotoxins. However, this neuroprotective effect has not been demonstrated with treatment after seizures had been stopped. We investigated whether 3-methyl-1-phenyl-2-pyrazolin-5-one, edaravone (Ed), a newly developed free radical scavenger that has been used clinically to treat cerebral infarction, could prevent neuronal loss when administered after the occurrence of seizures in a kainic acid (KA)-induced seizure model. Compared with KA alone, cell loss was significantly reduced when animals received Ed (10 mg/kg i.v.) just after seizures, and when Ed was administered both 60 min before (30 mg/kg i.p.) and after KA injection. Combined before-and-after treatment with Ed significantly ameliorated the KA-induced decrease of glutathione and blocked the KA-induced increase of 4-hydroxy-2-nonenal (HNE). Because before-and-after treatment with Ed significantly lessened the KA-induced increase of HNE, Ed may exert its neuroprotective effect by inhibiting lipid peroxidation. However, post-treatment with Ed prevented neuronal cell loss, while HNE and glutathione levels did not differ from those in animals without Ed, so a mechanism other than free radical scavenging must be involved in the prevention of cell loss. Patients who develop status epilepticus are unlikely to receive adequate antioxidant therapy before the onset, so it is an advantage that Ed can prevent neuronal death even when administered after seizures.

Protective effects of betaxolol in eyes with kainic acid-induced neuronal death

In the present study, we investigated whether betaxolol, a selective β 1-adrenoceptor antagonist, has neuroprotective effect on kainic acid (KA)-induced retinal damage. Neurotoxicities were induced in adult male rats by intravitreal injection of KA (total amount, 6 nmol). To examine the neuroprotective effects of betaxolol, rats were pretreated with betaxolol topically 60 min before KA injection to the rat eyes and twice daily for 1, 3, and 7 days after KA injection. The neuroprotective effects of betaxolol were estimated by measuring the thickness of the various retinal layers, and by counting the number of choline acetyltransferase (ChAT)- and tyrosine hydroxylase (TH)-positive cells in each retinal layer. The retina is highly vulnerable to KA-induced neuronal damage. Morphometric analysis of retinal damage in KA injected eyes, the thickness of the retinal layers decreased markedly after KA injection period of both 3 and 7 days. Furthermore, the numbers of ChAT- and TH-positive cells were significantly reduced by intravitreal injection of KA. However, when two drops of betaxolol, once before KA injection and twice daily for 7 days after KA injection, were continuously administered, the reductions in the retinal thickness and the retinal ChAT- and TH-positive cells were significantly attenuated. The present study suggests that topically applied betaxolol has neuroprotective effect on the retinal cell damage due to KA-induced neurotoxicity.

Differential roles of cyclooxygenase isoforms after kainic acid-induced prostaglandin E 2 production and neurodegeneration in cortical and hippocampal cell cultures

Prostaglandins, which are cyclooxygenase (COX) products, are pathologically up-regulated, and have been proven to be closely associated with neuronal death. In this study, we investigated a role of COX isoforms (COX-1 and COX-2) in kainic acid-induced neuronal death in cultured murine cortical or hippocampal neurons. In primary cortical neurons, both indomethacin (COX-1/-2 nonselective inhibitor) and aspirin (COX-1 preferential inhibitor) reduced basal and kainic acid-induced PGE 2 production significantly and prevented neuronal cell death after kainic acid treatment. In contrast, NS398 (COX-2 selective inhibitor) had no effect on kainic acid-induced neuronal cell death. In hippocampal neurons, however, COX-2 inhibitors prevented both kainic acid-induced neuronal death and PGE 2 production. COX-2 expression was remarkably up-regulated by kainic acid in hippocampal neurons; whereas in cortical neurons, COX-2 expression was comparatively less significant. Astrocytes were unresponsive to kainic acid in terms of PGE 2 production and cell death. In conclusion, we suggest that the release of PGE 2 induced by kainic acid occurred through COX-1 activity rather than COX-2 in cortical neurons. The inhibition of PGE 2 release by COX-1 inhibitors prevented kainic acid-induced cortical neuronal death, while in the hippocampal neurons, COX-2 inhibitors prevented kainic acid-induced PGE 2 release and hippocampal neuronal death.

Regulation of X-Chromosome-Linked Inhibitor of Apoptosis Protein in Kainic Acid-Induced Neuronal Death in the Rat Hippocampus

XIAP (X-chromosome-linked inhibitor of apoptosis protein) is an antiapoptotic protein which inhibits the activity of caspases and suppresses cell death. However, little is known about the presence and function of XIAP in the nervous system. Here we report that XIAP mRNA is expressed in developing and adult rat brain. Using a specific antibody, we observed XIAP-immunoreactive cells in different brain regions, among others, in the hippocampus and cerebral cortex. Kainic acid, which induces delayed cell death of specific neurons, increased the levels of XIAP in the CA3 region of hippocampus. XIAP was, however, largely absent in cells undergoing cell death, as shown by TUNEL labeling and staining for active caspase-3. In cultured hippocampal neurons, XIAP was initially upregulated by kainic acid and then degraded in a process blocked by the caspase-3 inhibitor DEVD. Similarly, recombinant XIAP is cleaved by active caspase-3 in vitro. The results show that there is biphasic regulation of XIAP in the hippocampus following kainic acid and that XIAP becomes a target for caspase-3 activated during cell death in the hippocampus. The degradation of XIAP by kainic acid contributes to neuronal cell death observed in vulnerable neurons of the hippocampus after caspase activation.

The neuroprotective effects of the recombinant interleukin–1 receptor antagonist rhIL–1ra after excitotoxic stimulation with kainic acid and its relationship to the amyloid precursor protein gene

The cytokine interleukin–1 (IL–1) and its endogenous antagonist (IL–1ra) have important functions in the central nervous system. Recent experimental observations have suggested that recombinant IL–1RA (rhIL–1ra) has neuroprotective properties in ischaemia, excitotoxicity, and trauma. We wished to see what effect rhIL–1ra had on kainic acid-induced neuronal death and to investigate how this might relate to changes in expression of the amyloid precursor protein gene (APP) and glial fibrillary acid protein (GFAP) using in situ hybridization. Wistar rats were treated by intracerebroventricular administration with rhIL–1ra at doses of 10, 20 and 40 μg given 10 min before and 10 min after intraperitoneal kainic acid 10 mg/kg. Behaviour was measured and, after 10 days, the brains were removed for histology and in situ hybridization. There were no anticonvulsant effects on kainic acid-induced wet dog shakes or limbic motor seizures. There were no differences in the effects of rhIL–1ra at all doses tested on hippocampal temperature, blood pressure, blood gases, pH, and glucose in comparison to control. With rhIL–1ra 10 μg given twice, there was significant protection of neurons in the CA1 and CA3 field of the hippocampus and dorsal thalamus, but not in the primary olfactory cortex-amygdaloid region. Small, but insignificant, neuroprotective effects were observed in the same anatomical regions with a dose of 20 μg given twice, and no neuroprotective effects were observed with 40 μg. The enhanced neuronal survival in CA1, CA3 and the dorsal thalamus was associated with preservation of APP 695 mRNA (neuronal form) and lack of stimulation of APP 770 (glial form) and GFAP messages. Where there was no neuroprotection APP 695 mRNA was reduced and stimulation of both APP 770 and GFAP mRNAs was observed. In conclusion, rhIL–1ra has dose- and region-dependent effects on neuronal survival after kainic acid and prevents damage-induced changes in APP and GFAP mRNAs.

Kainic acid-induced neuronal death is associated with DNA damage and a unique immediate-early gene response in c-fos-lacZ transgenic rats

Previously, we established that persistent upregulation of c-fos expression preceded kainic acid (KA)-induced neuronal death in mice. To discriminate between events that are products of the seizures elicited by KA and those that are specifically associated with its neurotoxic actions, we have examined the expression of cellular immediate-early genes (cIEGs) following KA or pentylenetetrazol (PTZ) treatment in c-fos-lacZ transgenic rats. While both chemoconvulsants elicit seizures, only KA causes selective neuronal death. Following treatment of transgenic rats with KA there was a protracted expression of Fos-lacZ that lasted for 2-3 d. In contrast, PTZ elicited a transient increase in the transgene product that lasted about 6 hr. Normally, Fos and Fos-lacZ were detected only in neuronal nuclei. However, 6 hr following kainic acid (but not PTZ) administration, beta-galactosidase activity appeared in the cytoplasm of neurons within vulnerable regions (as determined by the terminal transferase biotinylated-UTP nick end labeling (TUNEL) procedure). Like c-fos, transcripts for other cIEGs were elevated for longer periods in the KA-treated rat hippocampus. In addition, fra-1 and fra-2 were only induced in the KA-treated rat. These changes in mRNA levels were paralleled by a sustained increase in AP-1 DNA binding activity. Thus, quantitative and qualitative changes in AP-1 DNA binding complexes accompany neurotoxic cell death that are not observed following seizures.

Co-expression of HSP72 and c-fos in rat brain following kainic acid treatment.

The relationship between heat shock protein 72 (HSP72) and c-fos gene expression following systemic administration of kainic acid was investigated by combining immunocytochemistry for HSP72 with in situ hybridization for c-fos. Increased HSP72 expression was detected in adult rat hippocampus 4 h after seizure-onset. Transient co-expression of c-fos and HSP72 occurred in neurons that are resistant to kainic acid, whereas prolonged co-expression was observed in vulnerable neurons. The spatial distribution and developmental time course of kainic acid-induced HSP72 expression were similar to those of kainic acid-induced neurodegeneration. The results demonstrate a relationship between c-fos and HSP72 gene expression and suggest that prolonged co-expression of these genes plays a role in kainic acid-induced neuronal death.