Summary Mammalian genomes is folded within the nucleus in a highly organized fashion. The cohesin complex participates in the organization of 3D genome through generating and maintaining DNA loops. The tumor suppressor STAG2, which encodes a core subunit of the cohesin complex, is frequently mutated in various cancers. However, the impact of STAG2 inactivation on 3D genome organization in cancer cells, especially the long-range enhancer-promoter contacts and subsequent gene expression control, remains poorly understood. In our preliminary studies, we have carried out RNA-seq, ChIP-seq as well as Hi-C analyses in melanoma cells stably expressing inducible shRNA of STAG2. We have shown that depletion of STAG2 in melanoma cells leads to expansion of topologically associated domains (TADs) at sites where binding of STAG2 is switched to its paralog STAG1. We also identified Interferon Regulatory Factor 9 (IRF9) as a putative direct target of STAG2 in melanoma cells and demonstrated that loss of STAG2 activates IRF9 to enhance type I interferon signaling and increases the expression of PD-L1. Based on these preliminary findings, we hypothesize that loss of STAG2 results in dysregulation of type I interferon signaling in melanoma via perturbation of 3D genome organization. In aim 1, we will characterize the molecular mechanism underlying the regulation of type I interferon response by STAG2 in melanoma via modulating 3D genome organization. We will also examine the chromatin interactions at the IRF9 locus and other targets in STAG2 wildtype and STAG2 mutant human melanoma samples. In aim 2, we will systematically characterize STAG2-specific chromatin loops and investigate the effects of STAG2 inactivation on the enhancer-promoter interactome in melanoma cells by carrying out STAG2- and H3K27ac- HiChIP analyses. In aim 3, we will examine the roles of STAG2 in regulating tumor-induced immune evasion and in determining the sensitivity to anti-PD-1 immune checkpoint blockade in melanoma. Findings from the proposed study will very likely reveal functions of STAG2 within the cohesin complex that contribute to the malignant phenotypes in STAG2 mutant cancer arising from 3D genome perturbation.