ABSTRACT: Epigenetic plasticity is critical for tumor transformation, progression, and response to immunotherapy. Although pseudouridine is the first discovered and most abundant epitranscriptomic modification, its cellular functions remain poorly understood. In this study, we identified pseudouridine synthase (PUS) as a key driver of tumor immune evasion. Specifically, we found that PUS was aberrantly overexpressed in tumors and correlated with tumor malignant progression as well as poor patient prognosis, particularly in patients with TP53 mutations. Notably, genetic ablation of PUS effectively suppressed tumor progression, increased T cell infiltration, and boosted T cell function in a de novo MYC/Trp53-/- mouse liver cancer, as well as in chemically induced liver cancer models. Mechanistically, PUS loss induced the expression of retrotransposon sequences, resulting in elevated levels of double-stranded RNA and subsequent activation of innate antiviral immune signaling. We further demonstrated the role of PUS1 in tumor immune evasion was dependent on its enzymatic activity. Importantly, inhibition of PUS1 could sensitize tumors to anti-PD-1 therapy in a MYC/Trp53-/- mouse liver cancer model. Similarly, we revealed that 5-fluorouracil could inhibit pseudouridine synthesis and significantly enhance the efficacy of PD-1 inhibition. Clinically, low PUS level showed a higher response rate and better clinical outcome to immune checkpoint blockade therapies. Overall, our findings demonstrate PUS1 as a critical regulator of immune evasion and targeting pseudouridine synthesis may a novel strategy to enhance immunotherapy efficacy by activating dsRNA-sensing pathways.