Increase in ferric and ferrous iron in the rat hippocampus with time after kainate-induced excitotoxic injury

The present study aimed to elucidate the distribution of ferric and ferrous iron in the hippocampus after kainate-induced neuronal injury. A modified Perl's or Turnbull's blue histochemical stain was used to demonstrate Fe3+ and Fe2+ respectively. Very light staining for iron was observed in the hippocampus, in normal or saline-injected rats and 1-day post-kainate-injected rats. At 1 week postinjection, a number of Fe3+-positive, but very few Fe2+-positive, cells were present, in the degenerating CA fields. At 1 month postinjection, large numbers of Fe3+-positive glial cells, and some Fe2+-positive blood vessels, were observed. At 2 months postinjection, large numbers of Fe3+- and Fe2+-positive glial cells were present. The labeled cells had light and electron microscopic features of oligodendrocytes, and were double labeled with CNPase, a marker for oligodendrocytes. The observation of an increasing number of Fe3+- and Fe2+-positive cells in the degenerating hippocampus with time is consistent with the results of a nuclear microscopic study, in which an increasing amount of iron was detected in the degenerating hippocampus after kainate injection. In addition, the present study showed a shift in the oxidation state of the accumulated iron, with more cells becoming Fe2+ at a late stage. A possible consequence of the high amounts of Fe2+ in the hippocampus after kainate injection is that it could promote free radical damage in the lesioned areas.     

Changes in glutathione in the hippocampus of rats injected with kainate: depletion in neurons and upregulation in glia

The aim of the present study was to elucidate the distribution of glutathione immunoreactivity in the normal hippocampus and after kainate-induced neuronal injury. A specific antibody was used that recognizes both the reduced (GSH) and oxidized (GSSG) forms of glutathione. Immunoreactivity to glutathione was observed in neurons, but few immunolabeled glial cells were observed in the normal hippocampus. After kainate injection, a decrease in glutathione immunoreactivity was observed in pyramidal neurons from as early as 1 day after injection. In contrast, dense staining to glutathione was observed in large numbers of reactive astrocytes at 3 days to 6 weeks after kainate injection. This suggests upregulation of glutathione synthesis in these cells. One possibility is that the high content of glutathione is protective to reactive astrocytes. Another possibility is that the high glutathione concentration in reactive astrocytes may be protective to neurons around the glial scar.     

Increased uptake of divalent metals lead and cadmium into the brain after kainite-induced neuronal injury

An increase in iron level, number of iron positive cells and ferritin expression has been observed in the rat hippocampus after neuronal injury induced by the excitotoxin, kainate. This is accompanied by an increased expression of divalent metal transporter-1 (DMT1) in the lesioned hippocampus, suggesting that the transporter may be partially responsible for the iron accumulation. DMT1 has a broad substrate range that includes other divalent metals such as lead (Pb) and cadmium (Cd), and the present study was carried out to elucidate the uptake of these metals in the kainate-injected brain. The technique of atomic absorption spectroscopy was used for analyses. Significantly higher lead and cadmium levels were detected in the hippocampus and other brain areas of intracerebroventricular kainate-injected rats treated with lead and cadmium in the drinking water, compared to intracerebroventricular saline-injected rats treated with lead and cadmium in the drinking water. Since very low levels of lead and cadmium are present in the normal animal, these results indicate increased uptake of lead and cadmium into brain areas as a result of the kainate injections. Increased iron levels were also detected in the hippocampus of the kainate-injected rats. The above results show increased uptake of divalent metals into brain areas undergoing neurodegeneration.     

Kainate-induced neuronal injury leads to persistent phosphorylation of cAMP response element-binding protein in glial and endothelial cells in the hippocampus

Intracerebroventricular kainate treatment in rats induces neuronal cell death, followed by proliferation and hypertrophy of glial cells in the lesioned area. To further understand the activated signal transduction pathways and to get insights into potential target gene activation, the present study aims to elucidate long-term effects on the phosphorylation state of cAMP response element-binding protein (CREB) in the hippocampal formation. One to four weeks after kainate injection, we found high levels of phosphorylated and hence activated CREB (pCREB) in glial cells of the degenerating CA fields. As shown by electron microscopy, pCREB immunoreactivity was present in reactive astrocytes, oligodendrocyte precursor cells and endothelial cells of blood vessels. It is postulated that pCREB could drive the expression of downstream genes in these cells to promote cell proliferation and survival.     

Heme oxgenase-1 is expressed in viable astrocytes and microglia but in degenerating pyramidal neurons in the kainate-lesioned rat hippocampus

The present study aimed to elucidate the distribution of heme oxygenase-1 (HO-1) in the hippocampus after intracerebroventricular injections of kainate. Very little or no staining of HO-1 was observed in the normal CA1, whilst moderate staining of dentate hilar neurons was observed in the dentate gyrus, in the normal hippocampus. At postinjection day 1, a slight increase in immunoreactivity in the neuropil of the lesioned CA fields and a marked increase in HO-1 immunoreactivity in glial cells of the stratum lacunosum moleculare of CA fields and the stratum moleculare of the dentate gyrus was observed. Electron microscopy showed that the glial cells had features of viable astrocytes. At postinjection day 3, glial cells in the dentate gyrus continued to express HO-1, whilst pyramidal neurons in the degenerating CA fields started to express intense HO-1 immunoreactivity in their cell bodies. At postinjection weeks 1–3, HO-1 was observed in glial cells in the center of the lesion, but also in neurons at the perifocal region of the glial scar. The glial cells were found to have features of viable astrocytes and microglia, whilst the neurons contained discontinuous cell membranes and nuclear outlines, and had features of degenerating neurons. Intense immunoreactivity was observed in the cytoplasm of the degenerating neurons. The density of staining was greater than that observed in astrocytes or microglia. Recent in vitro results on fibroblasts transfected with HO-1 cDNA showed that, despite cytoprotection with low (less than fivefold compared with untransfected cells) HO-1 activity, high levels of HO-1 expression (more than 15-fold) were associated with significant oxygen toxicity. These and the present observations suggest a destructive effect of increased expression of HO-1 in neurons, and possible novel therapeutic approaches involving overexpression of HO-1 must therefore be approached with caution. Electronic Publication     

Occurrence of complement protein C3 in dying pyramidal neurons in rat hippocampus after systemic administration of kainic acid

To evaluate the roles of complement in kainic acid (KA)-induced neuronal damages, the immunohistochemical localization of the complement protein C3 was examined in rat hippocampus after systemic KA injection. The immunoreactivity for C3 was found in glial cells in control rats, and such glial cells were increased in number after KA injection. Our confocal study showed that C3-positive glial cells were microglia. Three to seven days after KA, C3 immunoreactivity appeared in CA1 and CA3 pyramidal neurons. Double staining for C3 combined with the terminal deoxynucleotidyl transferase-mediated dUTP nick end labelling showed that occurrence of C3 immunoreactivity in neurons coincided well with that of DNA fragmentation. Western blot analysis and RT-PCR experiments suggested local synthesis of C3 by brain cells. Our results suggest that C3 contributes greatly to neuronal death after systemic KA administration, and that microglia and neurons are the local source of C3 in KA-induced brain injury.     

Changes in cytochrome P450 side chain cleavage expression in the rat hippocampus after kainate injury

Our previous study showed an increase in total cholesterol level of the hippocampus after kainate-induced injury, but whether this is further metabolized to neurosteroids is not known. The first step in neurosteroid biosynthesis is the conversion of cholesterol to pregnenolone by the enzyme cytochrome P450 side chain cleavage (P450scc). This study was carried out to elucidate the expression of this enzyme in the kainate-lesioned rat hippocampus. A net decrease in P450scc protein was detected in hippocampal homogenates by Western blots at 2 weeks post-kainate injection (time of peak cholesterol concentration after kainate injury). Immunohistochemistry showed decreased labeling of the enzyme in neurons, but increased expression in a small number of astrocytes. The level of pregnenolone was also analyzed using a newly developed gas chromatography–mass spectrometry (GC–MS) method, optimized for the rat hippocampus. A non-significant tendency to a decrease in pregnenolone level was detected 2 weeks post-lesion. This is in contrast to a large increase in oxysterols in the lesioned hippocampus at this time (He et al. 2006). Together, they indicate that increased cholesterol in the kainate lesioned hippocampus is mostly metabolized to oxysterols, and not neurosteroids. Wan-Jie Chia and Andrew M. Jenner contributed equally to this work.     

Gliosis and axonal sprouting in the hippocampus of epileptic rats are associated with an increase of tenascin-C immunoreactivity

Summary Temporal lobe epilepsy is associated with neuronal death, gliosis and sprouting of mossy fibres in the hippocampus of human and rats. In the present study we show that immunoreactivity for tenascin-C (an extracellular matrix glycoprotein) increases in the hippocampus of epileptic rats. However, this increase was only observed in the cases displaying neuronal cell loss and glial reaction (i.e. after kainate treatment but not after kindling). Tenascin-C increase was particularly striking at Ammon's horn, where the antibody labelled both reactive astrocytes (confirmed by double-labelling experiments) and axonal plasma membranes. In the molecular layer tenascin-C immunoreactivity remained unchanged in both kindled or kainate treated rats. It is interesting that increased tenascin-C immunoreactivity was observed within zones in which axonal regeneration did not occur (the CA3 area in kainate-treated animals) whereas zones in which reactive synaptogenesis occurred (such as the CA3 area of kindled rats or the molecular layer of both kindled and kainate-treated rats) were devoid of tenascin-C immunoreactivity. We infer from these results that tenascin-C impedes the terminal sprouting of mossy fibres in CA3 of kainate-treated rats.     

Glial changes following an excitotoxic lesion in the CNS--II. Astrocytes.

Astrocytes are involved, as are microglia/macrophages [Marty et al. (1991) Neuroscience 45, 529-539], in the formation of a glial scar after CNS lesions. This study was undertaken to follow the time-course of changes in the morphology and distribution of astrocytes that takes place during the formation of a glial scar after kainic acid injection in the rat thalamus. The astrocytes were identified using an antibody raised against glial fibrillary acidic protein (GFAP) and the progression of their reaction to the lesion was followed from 24 h to one year after the kainate injection. Three periods could be distinguished during the evolution of the astrocytic response in the neuron-depleted area. There was an initial appearance of a large number of GFAP+ cells. These cells displayed profound morphological differences from the normal. They were enlarged, round and devoid of processes. These GFAP+ astrocytes disappeared four days after the lesion. This increase of the GFAP+ cells in the neuron-depleted area may be due to cytoskeletal changes and thus an increased exposure of antigenic sites. In a second period between four and 14 days, the only GFAP+ elements present in the neuron-depleted area were long and straight processes. These processes entered the lesioned area from the periphery and seemed to follow axon bundles. Additionally, during the first weeks, the number of reactive astrocytes increased in a small band just around the area of neuronal loss. The third period began after two weeks. The lesioned area became gradually occupied by GFAP+ astrocytes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Quinacrine attenuates increases in divalent metal transporter-1 and iron levels in the rat hippocampus,after kainate-induced neuronal injury

The present investigation was carried out to elucidate the effect of the antimalarial drug quinacrine on levels of expression of the non-heme iron transporter, divalent metal transporter-1 (DMT1) and iron, in the hippocampus of rats after kainate treatment. The untreated hippocampus was lightly stained for DMT1, while an increase in DMT1 staining in astrocytes in the degenerating cornu ammonis (CA) fields, after kainate lesions. The increased DMT1 immunoreactivity was correlated with increased levels of Fe3+ and Fe2+ staining in the CA fields, as demonstrated by iron histochemistry (Perl's and Turnbull's blue stain for Fe3+ and Fe2+). The increases in DMT1 and iron staining were significantly attenuated by quinacrine. Rats injected with kainate and daily i.p. injections of quinacrine (5 mg/kg) for 7 days or 2 weeks showed significantly lower levels of DMT1 immunoreactivity and iron staining, compared with rats injected with kainate and saline. These results show that DMT1 expression is closely linked to iron levels, and provide further support for a crucial role that DMT1 plays in iron accumulation in the degenerating hippocampus.     

An immunocytochemical study of calpain II in the hippocampus of rats injected with kainate

The distributions of the kainate/dl-alpha-amino-3-hydroxy-5-methylisoxazolepropionic acid (KA/AMPA) receptors GluR1 and calcium-activated neutral protease II (calpain II) in the hippocampus of normal and kainate-lesioned rats were studied by immunocytochemistry. There was a reduction in GluR1 immunoreactivity and a slight increase in calpain II immunoreactivity on the dendrites of pyramidal neurons in CA fields affected by the kainate at 18 h postinjection. Calpain II immunoreactivity was associated with amyloid fibrils at electron microscopy. These fibrils were most often intracellular, in membrane-bound profiles, some of which were contacted by axon terminals and were identified as degenerating dendrites. There was extensive destruction of mitochondrial membranes in degenerating profiles, and accumulations of amyloid fibrils were often localised in mitochondria in a calpain-positive profile. This was unlike other, calpain-negative degenerating profiles, that contained tubulovesicular profiles or multilamellar bodies, where mitochondrial membranes were preserved. Many more calpain-positive profiles were observed at electron microscopy 6 days after kainate injection. The enzyme was present in macrophages and astrocytes in lesioned areas.     

Amyloid beta-protein precursor deposition in rat hippocampus lesioned by ibotenic acid injection.

Ibotenic acid was injected into 3 parts of the lateral rat hippocampus. The animals were sacrificed 100 days after treatment, and studied immunohistochemically. The lesioned side of the hippocampus was highly atrophic with extensive neuronal loss and gliosis. Although silver staining revealed no particular structures such as neurofibrillary tangles or senile plaques, globular and granular depositions of amyloid beta-protein precursor (APP) immunoreactivity was observed by immunostaining in the lesion with the monoclonal antibody (clone 22C11). Increased immunoreactivities of glial fibrillary acidic protein (GFAP) and ubiquitin were found in the lesioned area, while the immunoreactivities of microtubule-associated protein 2 (MAP2) and 200 kDa neurofilament subunit protein (NF-H) were diminished. The results indicate that APP deposition is formed in the lesioned area where neuronal degeneration is produced by ibotenic acid in rat hippocampus.     

Evolution of hippocampal epileptic activity during the development of hippocampal sclerosis in a mouse model of temporal lobe epilepsy

Unilateral intrahippocampal injection of kainic acid in adult mice reproduces most of the morphological characteristics of hippocampal sclerosis (neuronal loss, gliosis, reorganization of neurotransmitter receptors, mossy fiber sprouting, granule cell dispersion) observed in patients with temporal lobe epilepsy. Whereas some neuronal loss is observed immediately after the initial status epilepticus induced by kainate treatment, most reorganization processes develop progressively over a period of several weeks. The aim of this study was to characterize the evolution of seizure activity in this model and to assess its pharmacological reactivity to classical antiepileptic drugs.Intrahippocampal electroencephalographic recordings showed three distinct phases of paroxystic activity following unilateral injection of kainic acid (1 nmol in 50 nl) into the dorsal hippocampus of adult mice: (i) a non-convulsive status epilepticus, (ii) a latent phase lasting approximately 2 weeks, during which no organized activity was recorded, and (iii) a phase of chronic seizure activity with recurrent hippocampal paroxysmal discharges characterized by high amplitude sharp wave onset. These recurrent seizures were first seen about 2 weeks post-injection. They were limited to the injected area and were not observed in the cerebral cortex, contralateral hippocampus or ipsilateral amygdala. Secondary propagation to the contralateral hippocampus and to the cerebral cortex was rare. In addition hippocampal paroxysmal discharges were not responsive to acute carbamazepine, phenytoin, or valproate treatment, but could be suppressed by diazepam.Our data further validate intrahippocampal injection of kainate in mice as a model of temporal lobe epilepsy and suggest that synaptic reorganization in the lesioned hippocampus is necessary for the development of organized recurrent seizures.     

Response to kainic acid injections: changes in staining for zinc, FOS, cell death and glial response in the rat forebrain

A pool of zinc is present in synaptic vesicles in a population of glutamatergic neurones. Zinc appears to modulate synaptic transmission and cause neuronal death. The status of vesicular zinc, neuronal death and glial reaction in the rat forebrain was analysed after a systemic injection of kainic acid in order to establish a model for future studies on zinc function. Rats received a systemic injection of kainic acid (10 mg/kg) and were killed 3, 6, 12, 24 and 48 h post-treatment. Timm's method and zinquin staining were used to detect zinc. Immunostaining for Fos-like proteins and staining with Fluoro-Jade B were used to detect cell reaction and degeneration, respectively. Glial fibrillary acidic protein and tomato lectin were used as glial markers. Zinquin staining for zinc rose transitorily in neuronal somata 6 h after injection (not observed at 24-48 h) in the piriform and entorhinal cortices, amygdala and hippocampus. In contrast sulphide/silver staining for zinc showed virtually no rise in cytoplasmic zinc (except in cornus ammonis field 1 of the hippocampus) 6 h after injection, and a decrease (bleaching) in some terminal fields starting 12 h after injection and increasing at 24-48 h. The areas most affected by the zinc bleaching were the olfactory bulb, piriform and entorhinal cortices, endopiriform and amygdaloid nuclei. Transitory Fos immunostaining (within neuronal nuclei) was observed between 3 and 12 h after kainate treatment in many telencephalic areas: olfactory bulb, cortex (piriform, hippocampal and neocortex) and amygdaloid nuclei. This was accompanied by changes in glial markers starting 3 h after injection. Fluoro-Jade B staining in neurones (degeneration) appeared 6 h after treatment and increased later. Degenerating areas generally coincided with those showing Fos immunoreactivity. Zinquin and sulphide/silver methods revealed various pools of zinc after kainate injection: a cytoplasmic pool and a terminal field (or vesicular) pool. Cytoplasmic zinc (zinquin) was coincident, in time and location, with cell degeneration, thus implicating zinc in cell death. This zinc may not have come from presynaptic stores, since no bleaching (sulphide/silver method) was observed 6 h after injection. Future experiments altering zinc pools (e.g. by chelating agents) may elucidate the function of zinc.     

Increase in cholesterol and cholesterol oxidation products,and role of cholesterol oxidation products in kainate-induced neuronal injury

Little is known about changes in sterols, in particular cholesterol, and cholesterol oxidation products (COPs) in oxidative injury in neural tissues. We have therefore examined changes in cholesterol and COPs using a model of excitotoxic injury. Intracerebroventricular injections of kainate in rats resulted in an increase in immunoreactivity to cholesterol in the affected CA fields of the hippocampus. The increase was confirmed by increased filipin staining of cholesterol in adjacent sections from the same animals, and in hippocampal slice or neuronal cultures after kainate treatment. In neuronal cultures, addition of lovastatin, an inhibitor of cholesterol synthesis, attenuated the increased filipin staining after kainate treatment, indicating that the increase in cholesterol could involve increased cholesterol synthesis. Furthermore, gas chromatographic mass spectrometric (GC/MS) analysis of cholesterol and COPs in kainate-injected rat brain showed a marked increase in cholesterol and COPs including 7-ketocholesterol, 3 days after kainate treatment. The addition of some COPs, including 7-ketocholesterol and cholesterol epoxides to hippocampal slices resulted in neuronal injury as reflected by decreased staining of a neuronal marker in the affected CA fields. The ability of these COPs to produce neuronal injury was attenuated by glutathione, suggesting that oxidative mechanisms are involved in neuronal injury induced by these products. These results, together with GC/MS results that showed significant increase in 7-ketocholesterol at 3 days post-kainate injury suggest that 7-ketocholesterol may be a factor in aggravating oxidative damage to neurons, after the initial stages of kainate-induced neuronal injury.     

Reactive changes of retinal astrocytes and Müller glial cells in kainate-induced neuroexcitotoxicity

The aim of this study was to investigate reactive changes of astrocytes and Müller glial cells in rats subjected to kainate treatment, which leads to neuronal degeneration in the ganglion cell layer and the inner border of the inner nuclear layer as confirmed by labelling with Fluoro-Jade B, a marker for degenerating neurons and fibres. Both the astrocytes and the Müller glial cells reacted vigorously to kainate injection as shown by their up-regulated expression of nestin, glial fibrillary acidic protein and glutamine synthetase. A major finding was the induced expression of nestin together with glial fibrillary acidic protein beginning at 1 day post-injection of kainate. The marked nestin expression appeared to be most intense at 1 day and was sustained till 2 weeks as compared with the untreated/normal retina. Western blotting analysis confirmed a marked increase in expression of nestin, glial fibrillary acidic protein and glutamine synthetase as compared with untreated/normal retina. Double labelling study revealed that astrocytes and Müller glial cells expressed the radial glia marker nestin, and incorporated bromodeoxyuridine to re-enter into their cell cycle. The induced expression of these proteins in astrocytes and Müller glial cells indicated an induction of gliotic responses and de-differentiation that may be associated with regenerative efforts after kainate-induced injury. Indeed, with the acquisition of an immature molecular profile as manifested by the induced expression of brain lipid-binding protein and doublecortin in astrocytes and Müller glial cells, the potential of these cells to de-differentiate in retinal neurodegeneration is greatly amplified.     

Quinacrine abolishes increases in cytoplasmic phospholipase A<Subscript>2</Subscript> mRNA levels in the rat hippocampus after kainate-induced neuronal injury

The present investigation was carried out to study the possible effects of quinacrine in modulating cytoplasmic phospholipase A₂ (cPLA₂) mRNA levels in rat hippocampus after kainate treatment. Injections of kainate into the right lateral ventricle resulted in significant increases in cPLA₂ mRNA levels in the hippocampus, at 3 days and 7 days after injection. The elevation in cPLA₂ mRNA levels is consistent with previous observations of increased cPLA₂ immunoreactivity in degenerating neurons and astrocytes at these times. Rats that received once daily intraperitoneal injections of quinacrine (5 mg/kg) after the intracerebroventricular kainate injections showed almost complete attenuation of increased cPLA₂ expression, at both 3 and 7 days after kainate injection. These results show that in addition to its well-known effect of inhibition of PLA₂ activity, quinacrine could also inhibit cPLA₂ expression, and further supports a role for PLA₂ in kainate-induced neuronal injury. Electronic Publication     

Calcium/calmodulin kinase II activity of hippocampus in kainate-induced epilepsy

This study investigated calcium/calmodulin kinase II (CaMKII) activity related to long-standing neuronal injury of the hippocampus in kainate (KA)-induced experimental temporal lobe epilepsy. Epileptic seizure was induced by injection of KA (1 microg/microL) dissolved in phosphate buffer (0.1 M, pH 7.4) into the left amygdala. Clinical seizures, histopathologic changes and CaMKII activity of the hippocampus were evaluated. Characteristic early limbic and late seizures were developed. Hippocampal CaMKII activity increased significantly 4 and 8 weeks after intra-amygdaloid injection of KA, when late seizures developed. The histopathologic changes of the hippocampus included swelling of neuronal cytoplasm with nuclear pyknosis and loss of neurons in CA3 during this period. The increased activity of CaMKII may correlate with appearance of distant damage in the hippocampus. The above results indicate that intra-amygdaloid injection of KA produces excitatory signals for ipsilateral CA3 neurons in the hippocampus and that subsequently increased levels of CaMKII in postsynaptic neurons induce neuronal injury via phosphorylation of N-methyl-D-aspartate type glutamate receptor.