Epilepsy affects more than 0.5% of the population worldwide, and genetic factors play an important role in the idiopathic generalized epilepsy syndromes (IGEs). Many monogenic mutations associated with IGEs are in ion channel genes. GABAA receptors (GABAARs) are the major inhibitory receptors in the brain and mutations in GABAAR subunit genes (GABRs) coding for the γ2, α1 and ß3 subunits are associated with IGEs. We have classified the known monogenic GABR mutations into 6 classes: those that reduce subunit expression due to: 1) impaired transcription; 2) impaired translation, 3) misfolding and degradation, 4) truncation and ER retention with or without a dominant negative effect on other subunits or 5) ER retention of functional receptors. A final class of mutations 6) reduces surface receptor function. This classification is useful for developing treatment strategies for severe IGEs. Mutations in GABRB3 (P11S, S15F) and GABRG2 (N79S, R82Q, P83S, R177G) have been associated with IGEs, and P11S has also been associated with autism. In Specific Aim 1 we continue our strategy of characterizing effects of monogenic GABR mutations associated with IGEs on functional properties and/or biogenesis of GABAARs, focusing on the mutations in ß3 and γ2 subunits. It is important, also, to determine the effects ofthese mutations in vivo on thalamocortical network function and mouse behavior. In addition and to, characterize the adaptive neuronal plasticity that occurs in response to the loss of inhibition for each mutation. Since the GABRB3 (P11S) mutation has been associated with both epilepsy and autism, it is a particularly important mutation, and in Specific Aim 2 we will study aclass 3 ß3+/P11S KI mouse and a ß3+/- mouse for comparison. We will determine if: 1) the KI mice develop a generalized epilepsy and altered 'autism-like' behavior due to haploinsufficiency or due also to a dominant negative effect of the mutant subunit, 2) the mutation alters cortical and thalamic inhibition, 3) mut ß3 (P11S) subunits are reduced in mouse brain, and 4) the mutation causes altered transcriptional signatures of cellular plasticity in compensation for the loss of b3 subunits. The basis for most IGEs has not been found since about 98% are polygenic, and thus, likely due to the presence of multiple nsSNPs (nonsynonymous single nucleotide polymorphisms that change aa coding). Thus, new strategies are needed for identification of nsSNPs that contribute to IGEs with complex inheritance. Among GABR genes, monogenic mutations associated with IGEs have been found in the hEP genes, GABRA1, GABRB3 and GABRG2. Exome sequencing of candidate ion channel genes, including GABAR genes, from well characterized IGE cases and controls identified rare nsSNPs in non-hEP genes in cases but not in controls. Also, with the Exome Variant Server, we found rare nsSNPs in the hEP genes. In Specific Aim 3 we will characterize the effects of the rare nsSNPs found in non hEP genes only in cases or in hEP genes on functional properties and/or biogenesis of GABAARs.