Lung cancer is the leading cause of cancer deaths worldwide. Detection of lung cancer at early stages can be difficult since patients tend to be asymptomatic at this stage. Thus, many lung cancer patients present with metastatic diseases at first diagnosis when the efficacy of chemotherapy or radiotherapy is limited. It has been shown that tumor tissues are infiltrated by many immune cells, in particular CD8+ T cells, which play crucial roles in the fight against cancer. On the other hand, due to continuous stimulation of tumor antigens, many tumor-infiltrating lymphocytes (TILs) exhibit the exhausted phenotype, characterized by decreased secretion of effector cytokines, increased expression of immune checkpoints, and defective proliferative capabilities upon stimulation. These exhausted T cells (TEX) are unable to eliminate cancer cells effectively. Clinically, immune checkpoint blockade therapy (ICB) counteracts the inhibitory signaling triggered by immune checkpoints thereby reinvigorating exhausted T cells and enhancing their cytotoxicity. Notably, not every patient receiving immune checkpoint blockade has favorable clinical responses. Further studies showed exhausted T cells are a heterogeneous population composed of progenitor and terminally exhausted subsets. Progenitor exhausted T cells, while expressing high levels of immune checkpoints, have stem-cell properties with further differentiation capacity and respond better to checkpoint blockade therapy as opposed to terminally exhausted T cells. Nevertheless, even though checkpoint blockade therapy may temporarily restore the functions of exhausted T cells, the therapy can not reverse the intrinsic epigenetic landscape of the exhausted phenotype back to that of memory or effector phenotypes of T cells. Therefore, we hypothesized that epigenetic drugs could restore the functions of T cells by reprogramming epigenetic regulations. Our laboratory has previously conducted a screen for T cell poly-functionality using an epigenetic compound library, and found that inhibitors of bromodomain and extraterminal domain (BETi) can enhance the polyfunctionality of CD4+ and CD8+ T cells from the peripheral blood of healthy volunteers. Based on these observations, I aimed to investigate the immunomodulatory effects of BETi on dysfunctional T cells from malignant pleural effusions (MPE) in lung cancer patients, which represent a unique tumor microenvironment where cancer cells and various immune cells interact. First, I investigated the functional states of malignant pleural effusion T cells based on the expression levels of two exhaustion-related transcription factors — Eomes and T-bet. I found that, compared to the circulating T cells from healthy donors, the percentages of terminally exhausted T cells (EomeshiT-Betlo) in malignant pleural effusion were significantly higher. Furthermore, BETi treatment significantly enhanced the polyfunctionality of CD4+ and CD8+ T cells from MPE and decreased the expression of immune checkpoints. Besides, BETi treatment decreased the terminally exhausted T cell subset while increasing the progenitor exhausted T cell subset. Most importantly, we investigated the therapeutic potential of BETi in a syngeneic orthotopic model of mouse lung adenocarcinoma — Lewis lung carcinoma. We showed that JQ1 treatment significantly diminished the tumor growth and improved the overall survivals. In conclusion, through the in vitro and in vivo experiments, we demonstrated the immunomodulatory effects of BETi on exhausted T cells, which paves way to the development of novel immunotherapeutic strategies in treating lung cancer patients.