Hyperexcitability and cell loss in kainate-treated hippocampal slice cultures

Kainic acid induced hyperexcitability in thalamic reticular nucleus that initiates an inflammatory response through the HMGB1/TLR4 pathway

OBJECTIVE

To explore the relationship between the proinflammatory factor high-mobility group box 1 (HMGB1) and glutamatergic alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors in the development of epilepsy.

METHODS

Thalamic reticular nucleus (TRN) slices were treated with kainic acid (KA) to simulate seizures. Action potentials and spontaneous inhibitory postsynaptic currents (sIPSCs) were recorded within TRN slices using whole-cell patch clamp techniques. The translocation of HMGB1 was detected by immunofluorescence. The HMGB1/TLR4 signaling pathway and its downstream inflammatory factors (IL-1β and NF-κB) were detected by RTPCR, Western blot and ELISA.

RESULTS

KA-evoked spikings were observed in TRN slices and blocked by perampanel. sIPSCs in the TRN were enhanced by KA and reduced by perampanel. The translocation of HMGB1 in the TRN was promoted by KA and inhibited by perampanel. The expression of the HMGB1/TLR4 signaling pathway was promoted by KA and suppressed by perampanel.

CONCLUSION

KA induced hyperexcitability activates the HMGB1/TLR4 pathway, which potentially leading to neuroinflammation in epilepsy.

CD8 T cells require gamma interferon to clear borna disease virus from the brain and prevent immune system-mediated neuronal damage

Borna disease virus (BDV) frequently causes meningoencephalitis and fatal neurological disease in young but not old mice of strain MRL. Disease does not result from the virus-induced destruction of infected neurons. Rather, it is mediated by H-2(k)-restricted antiviral CD8 T cells that recognize a peptide derived from the BDV nucleoprotein N. Persistent BDV infection in mice is not spontaneously cleared. We report here that N-specific vaccination can protect wild-type MRL mice but not mutant MRL mice lacking gamma interferon (IFN-gamma) from persistent infection with BDV. Furthermore, we observed a significant degree of resistance of old MRL mice to persistent BDV infection that depended on the presence of CD8 T cells. We found that virus initially infected hippocampal neurons around 2 weeks after intracerebral infection but was eventually cleared in most wild-type MRL mice. Unexpectedly, young as well as old IFN-gamma-deficient MRL mice were completely susceptible to infection with BDV. Moreover, neurons in the CA1 region of the hippocampus were severely damaged in most diseased IFN-gamma-deficient mice but not in wild-type mice. Furthermore, large numbers of eosinophils were present in the inflamed brains of IFN-gamma-deficient mice but not in those of wild-type mice, presumably because of increased intracerebral synthesis of interleukin-13 and the chemokines CCL1 and CCL11, which can attract eosinophils. These results demonstrate that IFN-gamma plays a central role in host resistance against infection of the central nervous system with BDV and in clearance of BDV from neurons. They further indicate that IFN-gamma may function as a neuroprotective factor that can limit the loss of neurons in the course of antiviral immune responses in the brain.

Sprouting of mossy fibers and presynaptic inhibition by group II metabotropic glutamate receptors in pilocarpine-treated rat hippocampal slice cultures

Mossy fibre sprouting (MFS) is a phenomenon observed in the epileptic hippocampus. We have studied MFS, in 7, 14 and 21 day in vitro (DIV) organotypic slice cultures, or in slice cultures treated with pilocarpine (0.5 mM) or pilocarpine and atropine (0.1 mM or 0.5 mM) for 48-72 h at 5 DIV and tested at 21 DIV. Acute application of pilocarpine directly activated hilar neurons and elicited epileptic-like discharges in CA3 pyramids and mossy cells of 5-8 DIV cultures, without causing substantial cell death, as assessed by lactate dehydrogenase measurements. Timm staining revealed increases in MFS in chronic pilocarpine-treated cultures, which was prevented by prior application of atropine. Extracellular synaptic responses were recorded in the granule cell layer and elicited by antidromic mossy fibre stimulation. The GABA(A) antagonist 6-imino-3-(4-methoxyphenyl)-1(6H)-pyridazinebutanoic acid (1 microM) induced a greater increase in the coastline bursting index in pilocarpine-treated cultures than in 21 DIV controls. However, there was no significant increase in the frequency of spontaneous or miniature synaptic events recorded in granule cells from pilocarpine-treated cultures. Granule cells were filled with biocytin and morphometric analysis revealed that the length of axon collaterals in the granule and molecular layer was longer in pilocarpine-treated cultures than in 21 DIV controls. Dual recordings between granule cells and between granule and hilar neurons showed that pilocarpine-treated cultures had a larger proportion of monosynaptic and polysynaptic connections. The group II metabotropic glutamate receptor (mGluR) agonist LY354740 (0.5 microM) suppressed excitatory but not inhibitory monosynaptic currents. LY354740 also inhibited antidromically evoked action currents in granule cells from pilocarpine- and to a lesser extent in pilocarpine and atropine-treated cultures, suggesting that group II mGluRs can reside along the axon and suppress action potential invasion. We provide direct evidence for the development of functional MFS and suggest a novel, axonal mechanism by which presynaptic group II mGluRs can inhibit selected synapses.

GluR5 kainate receptors, seizures, and the amygdala

The amygdala is a critical brain region for limbic seizure activity, but the mechanisms underlying its epileptic susceptibility are obscure. Several lines of evidence implicate GluR5 (GLU(K5)) kainate receptors, a type of ionotropic glutamate receptor, in the amygdala's vulnerability to seizures and epileptogenesis. GluR5 mRNA is abundant in temporal lobe structures including the amygdala. Brain slice recordings indicate that GluR5 kainate receptors mediate a portion of the synaptic excitation of neurons in the rat basolateral amygdala. Whole-cell voltage-clamp studies demonstrate that GluR5 kainate receptor-mediated synaptic currents are inwardly rectifying and are likely to be calcium permeable. Prolonged activation of basolateral amygdala GluR5 kainate receptors results in enduring synaptic facilitation through a calcium-dependent process. The selective GluR5 kainate receptor agonist ATPA induces spontaneous epileptiform bursting that is sensitive to the GluR5 kainate receptor antagonist LY293558. Intra-amygdala infusion of ATPA in the rat induces limbic status epilepticus; in some animals, recurrent spontaneous seizures occur for months after the ATPA treatment. Together, these observations indicate that GluR5 kainate receptors have a unique role in triggering epileptiform activity in the amygdala and could participate in long-term plasticity mechanisms that underlie some forms of epileptogenesis. Accordingly, GluR5 kainate receptors represent a potential target for antiepileptic and antiepileptogenic drug treatments. Most antiepileptic drugs do not act through effects on glutamate receptors. However, topiramate at low concentrations causes slow inhibition of GluR5 kainate receptor-mediated synaptic currents in the basolateral amygdala, indicating that it may protect against seizures, at least in part, through suppression of GluR5 kainate receptor responses.

Mice transgenically overexpressing sulfonylurea receptor 1 in forebrain resist seizure induction and excitotoxic neuron death

The ability of the sulfonylurea receptor (SUR) 1 to suppress seizures and excitotoxic neuron damage was assessed in mice transgenically overexpressing this receptor. Fertilized eggs from FVB mice were injected with a construct containing SUR cDNA and a calcium-calmodulin kinase IIalpha promoter. The resulting mice showed normal gross anatomy, brain morphology and histology, and locomotor and cognitive behavior. However, they overexpressed the SUR1 transgene, yielding a 9- to 12-fold increase in the density of [(3)H]glibenclamide binding to the cortex, hippocampus, and striatum. These mice resisted kainic acid-induced seizures, showing a 36% decrease in average maximum seizure intensity and a 75% survival rate at a dose that killed 53% of the wild-type mice. Kainic acid-treated transgenic mice showed no significant loss of hippocampal pyramidal neurons or expression of heat shock protein 70, whereas wild-type mice lost 68-79% of pyramidal neurons in the CA1-3 subfields and expressed high levels of heat shock protein 70 after kainate administration. These results indicate that the transgenic overexpression of SUR1 alone in forebrain structures significantly protects mice from seizures and neuronal damage without interfering with locomotor or cognitive function.

Synaptic connections from multiple subfields contribute to granule cell hyperexcitability in hippocampal slice cultures

Limbic status epilepticus and preparation of hippocampal slice cultures both produce cell loss and denervation. This commonality led us to hypothesize that morphological and physiological alterations in hippocampal slice cultures may be similar to those observed in human limbic epilepsy and animal models. To test this hypothesis, we performed electrophysiological and morphological analyses in long-term (postnatal day 11; 40-60 days in vitro) organotypic hippocampal slice cultures. Electrophysiological analyses of dentate granule cell excitability revealed that granule cells in slice cultures were hyperexcitable compared with acute slices from normal rats. In physiological buffer, spontaneous electrographic granule cell seizures were seen in 22% of cultures; in the presence of a GABA(A) receptor antagonist, seizures were documented in 75% of cultures. Hilar stimulation evoked postsynaptic potentials (PSPs) and multiple population spikes in the granule cell layer, which were eliminated by glutamate receptor antagonists, demonstrating the requirement for excitatory synaptic transmission. By contrast, under identical recording conditions, acute hippocampal slices isolated from normal rats exhibited a lack of seizures, and hilar stimulation evoked an isolated population spike without PSPs. To examine the possibility that newly formed excitatory synaptic connections to the dentate gyrus contribute to granule cell hyperexcitability in slice cultures, anatomical labeling and electrophysiological recordings following knife cuts were performed. Anatomical labeling of individual dentate granule, CA3 and CA1 pyramidal cells with neurobiotin illustrated the presence of axonal projections that may provide reciprocal excitatory synaptic connections among these regions and contribute to granule cell hyperexcitability. Knife cuts severing connections between CA1 and the dentate gyrus/CA3c region reduced but did not abolish hilar-evoked excitatory PSPs, suggesting the presence of newly formed, functional synaptic connections to the granule cells from CA1 and CA3 as well as from neurons intrinsic to the dentate gyrus. Many of the electrophysiological and morphological abnormalities reported here for long-term hippocampal slice cultures bear striking similarities to both human and in vivo models, making this in vitro model a simple, powerful system to begin to elucidate the molecular and cellular mechanisms underlying synaptic rearrangements and epileptogenesis.

Acidosis induces necrosis and apoptosis of cultured hippocampal neurons

Acidosis, hypoxia, and hypoglycemia rapidly and transiently appear after reduction of cerebral blood flow. Acidosis also accompanies head trauma and subarachnoid hemorrhage. These insults result in necrotic and apoptotic loss of neurons. We previously demonstrated that transient acidification of intracellular pH from 7.3 to 6.5 induces delayed neuronal loss in cultured hippocampal slices (49). We now report that acidosis induced both necrotic and apoptotic loss of neurons. Necrosis and apoptosis were distinguished temporally and pharmacologically. Necrosis appeared rapidly and was dose dependent with the duration of the acidosis treatment. Apoptosis was delayed with maximal number of apoptotic cells seen with a 30-min acidosis treatment. Apoptotic neuronal loss was accompanied by DNA fragmentation and was blocked by inhibitors of protein and RNA synthesis, ectopic expression of the anti-apoptotic gene bcl-2, or an inhibitor of caspases, proteases known to be activated during apoptosis. Necrotic neuronal loss was unaffected by these treatments. Hypothermia, a treatment known to attenuate neuronal loss following a variety of insults, blocked both acidosis-induced necrosis and apoptosis. These results indicate that acidosis is neurotoxic in vitro and suggest that acidosis contributes to both necrotic and apoptotic neuronal loss in vivo.

Seizures, cell death, and mossy fiber sprouting in kainic acid-treated organotypic hippocampal cultures

Sprouting of the mossy fiber axons of the dentate granule cells is a structural neuronal plasticity found in the mature brain of epileptic humans and experimental animals. Mossy fiber sprouting typically arises in experimental animals after repeated seizures and may contribute to the hyperexcitability of the epileptic brain. Investigation of the molecular triggers and spatial cues involved in mossy fiber sprouting has been hampered by the lack of an optimal in vitro model for studying this rearrangement. For an in vitro model to be feasible, the circuitry and receptors involved in convulsant-induced mossy fiber sprouting would have to be localized near the granule cells, rather than being dependent on long-range brain interconnections. However, it is not known whether this is the case. We report here that that application of the convulsant, kainic acid, to organotypic hippocampal explant cultures induces seizures, neuronal cell death, and subsequent dramatic mossy fiber sprouting with a similar laminar preference and time-course to that seen in intact animals. Prolonged (48 h) but not transient (4 h) kainic acid treatment caused regionally selective neuronal cell death. Cultures treated with kainic acid for a prolonged period displayed a time- and dose-dependent increase in supragranular Timm staining reflective of increased mossy fiber innervation to this area. Direct visualization of mossy fiber axons with neurobiotin-labeling revealed that mossy fibers in kainic acid-treated cultures exhibited a dramatic increase in supragranular axonal branch points and synaptic boutons. The cellular and molecular determinants required for kainic acid-induced cell death and subsequent mossy fiber reorganization thus appear to be intrinsic to the hippocampal slice preparation, and are preserved in culture. Given the ease with which functional inhibitors or pharmacological agents may be utilized in this system, slice cultures may provide a powerful model in which to study the molecular components involved in triggering mossy fiber outgrowth and underlying its laminar specificity. Elucidation of these molecular pathways will likely have both specific utility in clarifying the functional consequences of mossy fiber sprouting, as well as general utility in understanding of synaptic reorganization in the mature central nervous system.

Hippocampal alterations of apolipoprotein E and D mRNA levels in vivo and in vitro following kainate excitotoxicity

Alteration in the expression of apolipoprotein E (ApoE) and apolipoprotein D (ApoD) genes was evaluated in rat, 7 days following status epilepticus (SE) induced by intra-amygdala injection of kainate (KA), and in organotypic hippocampal cultures, 2 days after a single 1 h exposure to KA. Global polyadenylated RNA (poly A+) steady state, assessing global regulation of mRNA transcription was first measured in cortices and hippocampi from each animal and in the organotypic cultures. No alteration due to KA treatment was observed and individual concentrations of ApoE and ApoD mRNA species were therefore measured and comparative analysis performed. In the cortices of KA-treated animals, ApoE and ApoD mRNA levels did not show statistically significant changes. In contrast, in hippocampi, 7 days after SE, ApoE and ApoD mRNA levels were significantly increased, respectively, by 123 and 138%. This in vivo effect was confirmed in vitro on organotypic cultures, where KA treatment increased ApoE and ApoD mRNA expressions, respectively, by 72 and 61%. These observations indicate that lipidic metabolism is modified in the lesioned structure and suggest an increased traffic of lipids and a need for more ApoE and D in the hippocampus during the period of recovery and restructuration that follows severe seizures.

Residual granule cells can maintain susceptibility of CA3 pyramidal cells to kainate-induced epileptiform discharges

Slices of adult rat hippocampus made from animals exposed neonatally to X-ray irradiation were studied with electrophysiological techniques. A single dose of 6 Gy irradiation of the pup's head significantly but unevenly reduced the number of granule cells in the dentate gyrus. A larger reduction was detected in the septal than in the temporal hippocampus. The number of hilar cells decreased also. Effects of irradiation were confirmed with histological techniques. Field potential responses to mossy fiber stimulation in the pyramidal layer of the CA3 subfield was smaller in irradiated than in normal rats. Superfusion of the slices with kainic acid (KA, 300-500 nM) induced spontaneously recurrent paroxysmal activity (SRPA) in about 40% of irradiated slices in contrast with nearly 90% of slices cut from nonirradiated rats. Intracellular recordings from CA3 pyramidal cells in irradiated rats revealed recurrent bursts of action potentials on top of large depolarizing waves after KA application. Cells impaled in slices from the septal half of hippocampus of irradiated rats failed more often to respond with bursts to KA than cells in slices cut from the temporal half. Removal of mossy fiber input can therefore reduce KA induced hyperexcitability of CA3 pyramidal cells, but quantitative factors such as proportional loss of granule and hilar cells may explain the considerable differences found among cells and slices. Removal of 80% of granule cells reduces hyperexcitability consistently, while SRPA can be found in slices where as much as 50% of granule cells are missing. Intracellular findings suggest that failures of detection of SRPA following KA application to hippocampal slices of irradiated rats does not necessarily mean that CA3 pyramidal cells are no longer responding to KA with epileptiform bursting.

Tetanus toxin-enhanced GABA immunoreactivity in living neurons

Analysis of the connectivity between different neuronal cell types is dependent on an appreciation of their dendritic and axonal arborizations. A detailed study of the dendrites and axons of GABAergic neurons has been thwarted by the lack of a suitable technique for enhancing GABA immunoreactivity. This article describes a procedure using tetanus toxin which, when applied to organotypic hippocampal cultures, considerably enhances the immunoreactivity in the dendrites and axons of the GABA- and somatostatin-containing neurons and clearly demonstrates the co-localization of GABA and somatostatin immunoreactivities in the same neuron. Tetanus toxin was applied to the culture medium on Day 14 for a 24-hr period and the cultures were fixed at the end of Day 18. Tetanus toxin-treated cultures (n = 30) or untreated cultures (n = 40) were incubated for either GABA or somatostatin immunoreactivity. Tetanus toxin-treated cultures used for co-localization studies (n = 20) were incubated for both GABA and somatostatin immunoreactivity.

Calpain-mediated proteolysis of GluR1 subunits in organotypic hippocampal cultures following kainic acid treatment

The present study examined changes in GluR1 subunits after kainic acid (KA) treatment of organotypic hippocampal cultures. Immunoblots labeled with antibodies directed at the C-terminal domain of GluR1 revealed a large decrease in GluR1 immunoreactivity at 6 h and 24 h, while immunoblots labeled with antibodies directed at the N-terminal domain indicated that KA treatment produced changes in structure but not amount of GluR1 protein. Changes in GluR1 subunits were significantly reduced by the calpain inhibitor, calpeptin. These results indicate that KA-induced changes in GluR1 properties are mediated by calpain activation.

Expression of the calcium-binding protein, parvalbumin, in cultured cortical neurons using a HSV-1 vector system enhances NMDA neurotoxicity

Calcium-binding proteins (CaBPs) are a family of proteins having a unique distribution in the brain and are thought to be important in buffering intracellular calcium. Glutamate neurotoxicity is a process by which the over-activation of glutamate receptors can cause the influx of excessive extracellular calcium and neuronal cell death. It has been proposed that neurons containing CaBP may be more resistant to glutamate neurotoxicity due to their increased ability to buffer calcium. Using a herpes simplex virus-1 (HSV-1) vector system we packaged the CaBP gene, parvalbumin, or the marker gene, beta-galactosidase (beta-gal), correctly in viron particles, which were found upon infection to express mRNA specific to these vectors. PC12 and neocortical cultures showed strong immunohistochemical staining for either beta-gal or parv. The cortical cultures stained positively for endogenous glutamate decarboxylase, a marker for GABAergic neurons, but not for endogenous parvalbumin, indicating that parvalbumin was being expressed ectopically from the HSV-1 vector. Interestingly, the expression of parvalbumin increased cortical culture's susceptibility to N-methyl-D-aspartate-induced neurotoxicity. This increase in neurotoxicity was not due to the wild-type virus or the helper virus which accompanies the packaging of these vectors. We speculate that the ectopic expression of parvalbumin in cortical cultures may be increasing glutamate release which in turn increases cell death.

Pre-exposure to subtoxic levels prevents kainic acid lesions in organotypic hippocampal slice cultures: effects of kainic acid on parvalbumin-immunoreactive neurons and expression of heat shock protein 72 following the induction of tolerance

The effects of kainic acid on the survival of principal neurons and parvalbumin-immunoreactive (PARV-IR) neurons, and on the expression of heat shock protein 72 immunoreactivity (HSP72-IR) were investigated in organotypic hippocampal slice cultures. Untreated cultures displayed an organotypic organization and the development and morphology of PARV-IR neurons in the hippocampus paralleled that reported to occur in vivo, with the exception of the hilar region of the dentate gyrus which exhibited a marked lack of PARV-IR neurons. No constitutive expression of HSP72 was found in untreated cultures. The lesion of CA3 neurons and the reduction in numbers of PARV-IR neurons in both CA3 and CA1 after chronic exposure to 5 microM kainic acid were similar to those reported to occur in vivo. Exposure to 1 microM doses of kainic acid resulted in a widespread appearance of HSP72-IR and the induction of tolerance to a previously toxic dose of kainic acid. These results suggest the presence of endogenous neuroprotective mechanisms, activated by a stress response which induces HSP72, and is reminiscent of the induced tolerance reported to occur after a mild ischaemic insult.

A role for mossy fiber activation in the loss of CA3 and hilar neurons induced by transduction of the GluR6 kainate receptor subunit

Transduction of a viral vector expressing the GluR6 receptor subunit (HSVGluR6) to cultured hippocampal slices resulted in loss of CA3 and hilar neurons. Synaptic activity was required for this neuronal loss. This study investigates which synaptic connections were needed. Slice cultures responded heterogenously to HSVGluR6; cultures originating from the septal hippocampus showed greater neuronal loss than temporal cultures. Septal cultures also exhibited mossy fiber sprouting suggesting that activation of mossy fiber synapses contributed to neuronal loss. This was tested by transection of fiber tracts between the dentate gyrus and CA3 stratum pyramidale. Neuronal loss was blocked in transected cultures even though HSVGluR6-induced epileptiform activity was unaltered. These data suggest a role for mossy fiber activation in selective neuronal loss.