Summary/Abstract The immunologically inactive (cold) tumor is a major challenge for effective immunotherapies in many cancers, including breast cancer. Increasing evidence has demonstrated that human cells express various types of endogenous double-stranded RNAs (dsRNAs) regardless of pathogen invasion, and aberrant accumulation of cellular dsRNAs could trigger a detrimental innate immune response in cells. In cancer, these endogenous immunogenic dsRNAs are suggested as a source of immune induction to increase tumor response to immunotherapy. However, to exploit the cellular dsRNAs in immunotherapy for cancer, we need to understand the molecular mechanism for cellular dsRNA homeostasis in normal and malignant cells and find the specific ways to modulate immunogenic dsRNAs. We found that inhibition of DEAD-box RNA helicase 3X (DDX3X) resulted in the cytoplasmic accumulation of endogenous dsRNAs in the breast cancer cells. Loss of DDX3X increased the type I interferon production, STAT1 activation, IFN-stimulated genes (ISGs) expression, and the MHC class I expression with the enhanced antigen presentation on the breast cancer cells. DDX3X inhibition also suppressed the tumor growth and increased the tumor infiltration of active CD8+ T cells and DC in the syngeneic breast cancer mouse model. We hypothesize that inhibiting DDX3X leads to aberrant accumulation of endogenous dsRNAs, which triggers type I IFN responses and induces an innate immune response in the tumor. The proposed studies will be focused on understanding the molecular mechanism by which DDX3X regulates cellular dsRNA homeostasis, providing a link between cellular dsRNAs and immune signals in breast cancer cells, and establishing novel immunotherapeutic strategies for breast cancer. In Aim 1, we will determine the molecular mechanism by which DDX3X regulates cellular dsRNAs; In Aim 2, we will study DDX3X-dsRNAs-Type I IFN axis in cancer cells and human tumor; In Aim 3, we will explore the effect of inhibiting DDX3X to increase anti-tumor immunity and sensitize tumors to immunotherapy. Our study will reveal a novel regulatory mechanism of endogenous dsRNAs in cancer and may lead to novel therapeutics targeting DDX3X for new combinatory immunotherapy.