Genetically modified IL-2 bone marrow-derived myeloid cells reprogram the glioma immunosuppressive tumor microenvironment

Gliomas are the most prevalent type of brain tumors and one of the leading causes of cancer-related death in the adolescent and young adult population (AYA). Two-thirds of glioma AYA patients are affected by low-grade gliomas (LGGs), but there are no specific treatments. Therefore, a percentage of LGG patients experience tumor relapse and malignant progression to high-grade glioma which leads to fatal outcomes. In part, malignant progression is potentiated by the immunosuppressive stromal component of the tumor microenvironment (TME) underscored by M2-macrophages and a paucity of cytotoxic T cells. As a result, first-line immunotherapies have failed to improve outcomes for patients with progressive high-grade gliomas. Here, we report the efficacy of an in vivo approach that demonstrates the potential for a novel cell-mediated innate immunotherapy designed to abrogate immunosuppressive mechanisms within the glioma TME and enhance the recruitment of activated effector T cells. A single dose of engineered bone marrow-derived myeloid cells that release Interleukin-2 (GEMys-IL2) was used systemically to treat mice with LGG tumors systemically. Our results demonstrate that GEMys-IL2 efficiently crossed the blood brain barrier (BBB), infiltrated the glioma microenvironment, and reprogrammed the infiltrating immune cell composition and transcriptome. In addition, GEMys-IL2 impaired tumor progression and extended survival in a LGG immunocompetent mouse model. In conclusion, we demonstrated that GEMys-IL2 have a therapeutic effect in vivo, thus supporting its potential application as a novel immunotherapy that warrants further investigation.