While these malformations are believed to result from the effects of TSC1 or TSC2 gene mutations, the molecular mechanisms leading to tuber formation, as well as the onset of seizures, remain largely unknown.
Previous studies revealed different alterations of TSC1 and TSC2 in epilepsy-associated malformations and glio-neuronal tumors despite histopathologic similarities.
This chapter, presented arguments in favor of the hypothesis that abnormal cortical excitability originates in and around focal areas of structural malformations (i.e., cortical tubers and dysplasia) and that these "lesions" are the biologic consequences of tuberin and/or hamartin dysfunction.
Studies of how TSC1 and TSC2 function in normal and dysplastic cerebral neocortex may provide a paradigm for understanding the neurobiology of other genes that determine epilepsy-associated cerebral malformations (e.g. lissencephaly, double cortex).
The recently reported loss of heterozygosity (LOH) at the regions of the TSC1 or TSC2 locus in hamartomas obtained from different organs of patients with established tuberous sclerosis, including cortical tubers, stimulated us to examine epilepsy-associated tuberous sclerosis-like glioneuronal malformations with respect to LOH at the TSC1 and TSC2 loci of chromosomes 9q34 and 16p 13.3, respectively.