IMMU-09. REVERSING SYSTEMIC T CELL DYSFUNCTION TO LICENSE IMMUNOTHERAPY IN INTRACRANIAL TUMORS

Intracranial tumors present unique challenges for immunotherapy. These can include both local and systemic modes of immune suppression, the mechanistic underpinnings of which are incompletely understood. Our work reveals that intracranial tumors elicit systemic increases in circulating catecholamine levels, and that this chronic sympathetic hyperactivity results in T cell dysfunction that impedes immunotherapeutic efficacy. We show that treatment with b-adrenergic blockade can partially overcome the negative impacts of chronic sympathetic hyperactivity by increasing NF-kB activity in immune cells, restoring T cell polyfunctionality, favorably modifying the tumor microenvironment, and extending survival in murine models of glioblastoma treated with immune-based therapies. Furthermore, we demonstrate that extended survival is also observed in glioblastoma patients receiving b-adrenergic blockade, as well as in patients with melanoma and lung cancer brain metastases who received b-blockade alongside concomitant immune checkpoint inhibition. Importantly, while local sympathetic hyperactivity in the tumor microenvironment and b-blockade also impact the anti-tumor immune response in the context of extracranial disease, these effects are markedly more pronounced in intracranial disease. Taken together, these data reveal that sympathetic hyperactivity facilitates systemic immune dysfunction in the setting of intracranial tumors and highlight a novel role for the application of b-adrenergic blockade to license immunotherapy in intracranial malignancies.

Duke Scholars

Author Quinn Ostrom Neurosurgery, Neuro-Oncology