The inability to regulate the firing properties of neurons can lead to aberrant and excessive activity, oftentimes causing seizures. GABAA receptors are crucial for transmission of inhibitory signals which act as a brake on excessive activity to control and coordinate neuronal function. Deficits in the β3 subunit of the GABAA receptor have been implicated in epilepsy in humans, and mice lacking β3 suffer from seizures. However, the underlying mechanism for how loss of β3 leads to susceptibility to seizures is still unknown. My preliminary data suggests that knockout of β3 in hippocampal CA1 pyramidal cells affects transmission from a specific subset of inhibitory cells, but the precise identity of those cells remains to be determined. In addition, changes to the overall network activity of hippocampal cells resulting from deficits to these specific connections, and how these changes lead to epilepsy remains to be resolved. I aim to use genetic, electrophysiological, imaging, and computational modeling methods to test the hypothesis that loss of the β3 subunit in the CA1 region of the hippocampus results in specific circuit and network level disruptions underlying susceptibility to seizures. These studies will lay a foundation for the identification of potential avenues for therapeutic intervention while simultaneously elucidating basic mechanisms underlying seizure generation and epilepsy.