Understanding the molecular mechanisms involved in the effects of oxidative stress in humans and animals is important to minimize the damage it causes, leading to various intestinal diseases. Our aim is to study the genes and pathways involved in oxidative stress in the gut using mouse small intestinal epithelial cells (MODE-K) as a model. The MODE-K cell line was divided into two different groups: one group was treated with hydrogen peroxide (H²O²) and the other group was not. To analyze the effects of H²O² exposure, cell viability, apoptosis rate and reactive oxygen species (ROS) levels were determined. Next, transcriptome sequencing was performed, differentially expressed genes (DEGs) were identified and function annotation was performed, followed by a series of bioinformatics analyses. Real-time PCR was used to confirm the transcriptome data. Our results showed that H²O²-induced oxidative stress significantly increased ROS synthesis and promoted cell apoptosis in mouse small intestinal epithelial cells. During oxidative stress, 1207 DEGs (859 up-regulated, 348 down-regulated) were identified. According to GO analysis, DEGs are annotated into 51 different GO classifications including 22 biological processes, 15 cellular components and 14 molecular functions. In addition, using KEGG, PPI and correlation analysis, the two most significant subnetworks were identified. Ten correlated nodal DEGs of the first subnetwork correspond to MAPK, NF-kappa B and PI3K-AKT signaling pathways, and six correlated DEGs of the second subnetwork are associated with mitochondria. KDM6B was found to link these two subnetworks. The results suggest that oxidative stress affects epithelial growth, metabolism and apoptosis in a mouse model of intestinal cells through signaling pathways such as MAPK and PI3K/AKT/NF-kappa B, and mitochondria-related genes that are interconnected through the PTGS2-KDM6B-MT-ATP6 pathway.