Altered Astrocyte-Neuron Interactions and Epileptogenesis in Tuberous Sclerosis Complex Disorder

Abstract

While the molecular basis of TSC is well established, far less is known about the pathogenetic mechanisms of epileptogensis in TSC, shich is found in the vast majority of patients. We introduce the novel concept that this follows from a disruption of normal synaptic pruning that is due to TSC mutation in astrocytes, the major non-neuronal cell type of the brain. Previous studies mostly focused on focal epileptogenisis in cortical tubers. In this study, we propose that nontuber cortex may present an abnormally excitable neuronal network that could underlie seizure generation. We will concentrate on a non-neuronal mechanism may exist in regulating synaptic function and thus epileptogenisis in TSC. To explore this aim, we will use a wide variety of experimental approaches, including electrophysiological (patch-clamping in culture cells and slice preparations to in vivo video-EEG monitoring), histological (conventional and fluorescent assays), molecular biological (Western blotting, biotinylation), and modern cellular imaging (confocal and two-photon microscopy of tissue preparations) techniques. We will measure biomarkers for astrocyte and neuronal functions and provide an index of glial transmission in the cortex of TSC deficient mouse models and peri-tuber or non-tuber tissue from TSC human brain. We will determine whether astrocyte dysfunction will lead to a failure in pruning excessive excitatory synapses during development, which underlies epilepsy in young TSC patients.

Document Details

Document Type

Technical Report

Publication Date

Jun 01, 2013

Accession Number

ADA585804

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