Leigh syndrome (LS) is a progressive neurological disorder that manifests within the first year of life and is characterized by the loss of mental and movement abilities and is accompanied by epilepsy. LS has been associated with loss-of-function (LOF) mutations in genes that encode for proteins present in complex 1 of the electron transport chain. LOF mutations in one such gene, NADH dehydrogenase (ubiquinone) iron sulfur protein 4 (NDUFS4), are strongly associated with LS. Mice carrying an NDUFS4 deletion exhibit symptoms similar to those in humans, creating a relevant mouse model. I investigated the effects of an NDUFS4 knockout (KO) on the neuronal excitability of inhibitory and excitatory neurons across brain regions in LS mouse models. Two LS mouse models were generated by knocking out NDUFS4 in inhibitory or excitatory neurons utilizing LoxP/Cre technology. Mice carrying floxed alleles of NDUFS4 were crossed with Vglut2Cre or Gad2Cre driver mice, creating animals with excitatory and inhibitory neuron-specific NDUFS4 KO, respectively. NDUFS4 KO mutations in specific neuron types cause different phenotypes in these animal models, which together model various aspects of LS. I took the progeny with excitatory or inhibitory neuron-specific NDUFS4 KO (6 VglutCre, 16 GadCre, ages P90-120 & P60-70, respectively) and their control littermates (4 VglutCre, 11 GadCre, same age ranges), perfused them with phosphate buffered saline (PBS), and fixed with 4% paraformaldehyde (PFA). I took brains from these mice, sliced, and stained them with c-fos immunocytochemistry, then imaged them to quantify neuronal activity. Results show increased c-fos expression in GadCre mutant mice after spontaneous & thermally induced seizures, especially in the dentate gyrus and frontal cortex. In addition, there was decreased c-fos expression in the cerebellum and Pre-Bötzinger complex in VglutCre mutant mice. Findings from this study contribute to our understanding of the mechanisms for the development of seizures in LS.