PDGFRß(+) cells in human and experimental neuro-vascular dysplasia and seizures.

INTRODUCTION: Neuro-vascular rearrangement occurs in brain disorders, including epilepsy. Platelet-derived growth factor receptor beta (PDGFRß) is used as a marker of perivascular pericytes. Whether PDGFRß(+) cell reorganization occurs in regions of neuro-vascular dysplasia associated with seizures is unknown. METHODS: We used brain specimens derived from epileptic subjects affected by intractable seizures associated with focal cortical dysplasia (FCD) or temporal lobe epilepsy with hippocampal sclerosis (TLE-HS). Tissues from cryptogenic epilepsy, non-sclerotic hippocampi or peritumoral were used for comparison. An in vivo rat model of neuro-vascular dysplasia was obtained by pre-natal exposure to methyl-axozy methanoic acid (MAM). Status epilepticus (SE) was induced in adult MAM rats by intraperitoneal pilocarpine. MAM tissues were also used to establish organotypic hippocampal cultures (OHC) to further assess pericytes positioning at the dysplastic microvasculature. PDGFRß and its colocalization with RECA-1 or CD34 were used to segregate perivascular pericytes. PDGFRß and NG2 or IBA1 colocalization were performed. Rat cortices and hippocampi were used for PDGFRß western blot analysis. RESULTS: Human FCD displayed the highest perivascular PDGFRß immunoreactivity, indicating pericytes, and presence of ramified PDGFRß(+) cells in the parenchyma and proximal to microvessels. Tissues deriving from human cryptogenic epilepsy displayed a similar pattern of immunoreactivity, although to a lesser extent compared to FCD. In TLE-HS, CD34 vascular proliferation was paralleled by increased perivascular PDGFRß(+) pericytes, as compared to non-HS. Parenchymal PDGFRß immunoreactivity co-localized with NG2 but was distinct from IBA1(+) microglia. In MAM rats, we found pericyte-vascular changes in regions characterized by neuronal heterotopias. PDGFRß immunoreactivity was differentially distributed in the heterotopic and adjacent normal CA1 region. The use of MAM OHC revealed microvascular-pericyte dysplasia at the capillary tree lining the dentate gyrus (DG) molecular layer as compared to control OHC. Severe SE induced PDGFRß(+) immunoreactivity mostly in the CA1 region of MAM rats. CONCLUSION: Our descriptive study points to microvascular-pericyte changes in the epileptic pathology. The possible link between PDGFRß(+) cells, neuro-vascular dysplasia and remodeling during seizures is discussed.

Effect of status epilepticus and antiepileptic drugs on CYP2E1 brain expression.

P450 metabolic enzymes are expressed in the human and rodent brain. Recent data support their involvement in the pathophysiology of epilepsy. However, the determinants of metabolic enzyme expression in the epileptic brain are unclear. We tested the hypothesis that status epilepticus (SE) or exposure to phenytoin or phenobarbital affects brain expression of the metabolic enzyme CYP2E1. SE was induced in C57BL/6J mice by systemic kainic acid. Brain CYP2E1 expression was evaluated 18-24h after severe SE by immunohistochemistry. Co-localization with neuronal nuclei (NEUN), glial fibrillary acidic protein (GFAP) and CD31 was determined by confocal microscopy. The effect of phenytoin, carbamazepine and phenobarbital on CYP2E1 expression was evaluated in vivo or by using organotypic hippocampal cultures in vitro. CYP2E1 expression was investigated in brain resections from a cohort of drug-resistant epileptic brain resections and human endothelial cultures (EPI-EC). Immunohistochemistry showed an increase of CYP2E1 expression limited to hippocampal CA2/3 and hilar neurons after severe SE in mice. CYP2E1 expression was also observed at the astrocyte-vascular interface. Analysis of human brain specimens revealed CYP2E1 expression in neurons and vascular endothelial cells (EC). CYP2E1 was expressed in cultured human EC and over-expressed by EPI-EC. When analyzing the effect of drug exposure on CYP2E1 expression we found that, in vivo or in vitro, ethanol increased CYP2E1 levels in the brain and liver. Treatment with phenytoin induced localized CYP2E1 expression in the brain whereas no significant effects were exerted by carbamazepine or phenobarbital. Our data indicate that the effect of acute SE on brain CYP2E1 expression is localized and cell specific. Exposure to selected anti-epileptic drugs could play a role in determining CYP2E1 brain expression. Additional investigation is required to fully reproduce the culprits of P450 enzyme expression as observed in the human epileptic brain.

Sequential expression of surface antigens and transcription factor NFkappaB by hippocampal cells in excitotoxicity and experimental epilepsy.

Neurodegeneration and gliosis have been extensively described after long-lasting seizures; evidence for cytokine involvement in neuron-glia interactions does exist. We have therefore studied the hippocampal expression of molecules responsible for immune and inflammatory reactions, at different time-points following either experimental status epilepticus (SE) or direct excitotoxic damage. Experiments consisting of immunohistochemical labeling of glial markers, major histocompatibility complex (MHC) and nuclear factor kappaB (NFkappaB), were performed. NFkappaB nuclear translocation was controlled and measured using the electrophoretic mobility shift assay. One day after SE, neurodegeneration was obvious in CA3 pyramidal layers; NFkappaB staining in neurons and its translocation to the nucleus enhanced. From day 4 to at least day 8 post-SE, MHC-positive microglia, NFkappaB over-expression in thickened astrocytes, and increased levels of its activated form could be observed. The excitotoxic model caused more severe lesions, but NFkappaB and MHC expression were similar in both models. These results suggest that during long-lasting seizures: (i) neuronal firing activates NFkappaB expression and translocation; (ii) microglia expresses MHC; (iii) astrocytes, probably stimulated by microglial cytokines, over-express NFkappaB, the activation of which induces a cascade of reactions, particularly the transcription of cytokines and or neuroprotective molecules. Further clarification of the toxic or protective consequences of delayed inflammatory responses may be interesting in therapy of epilepsy.