Scientists at the UCLA Health Jonsson Comprehensive Cancer Center have developed a new cytokine-armored CAR-T cell therapy that helps the immune system better attack aggressive brain tumors in mice while reducing dangerous side effects that have long limited immune-based treatments for glioblastoma, one of the deadliest and most treatment-resistant brain cancers.
The therapy works by reprogramming CAR-T cells to release immune-stimulating proteins, called IL-12 and DR-18, that activate the body’s own immune system, strengthening the overall anti-cancer response. In mouse models, the approach improved tumor control, including against cancers made up of mixed cell populations that often escape therapies. Researchers also found that pairing the treatment with a second CAR-T strategy targeting VEGF, a protein that drives abnormal blood vessel growth and contributes to swelling in glioblastoma, helped reduce side effects while preserving strong anti-tumor activity.
The findings, published in Cancer Research, a journal of the American Association for Cancer Research, suggest a potential new strategy for treating recurrent high-grade gliomas and other solid tumors that historically have been difficult to target with CAR-T cell therapy.
Why it matters
Glioblastoma remains extremely difficult to treat because tumors suppress immune responses, contain diverse cancer cells and create abnormal blood vessels that limit the effectiveness of immunotherapy. While CAR-T cell therapy has transformed treatment for certain blood cancers, success in solid tumors has been limited.
“A key challenge in treating brain tumors, particularly glioblastoma, is that the tumor cells are often antigen heterogeneous, meaning they do not all express the same proteins that can be recognized by a given targeted therapy,” said Yvonne Chen, PhD, co-director of the Tumor Immunology and Immunotherapy Program at the UCLA Health Jonsson Comprehensive Cancer Center and senior author of the study. “We hypothesized that effective immunotherapy against brain tumors would have to engage naturally occurring immune cells, which can recognize a wide variety of target antigens, in the fight against cancer.”
What the study did
Because brain tumors are considered immunologically “cold,” meaning they do not naturally trigger a strong immune response, the researchers designed so-called “armored CAR-T cells” to activate immunity against the tumor. These CAR-T cells were built to recognize a tumor antigen called IL-13Rα2, a protein commonly found on glioblastoma cells, while also secreting immune-stimulating proteins that recruit and activate the body’s immune cells.
The team then tested multiple combinations of these “armor” molecules in immunocompetent mouse models of glioblastoma, using head-to-head comparisons to evaluate how each design affected tumor growth and immune activity. The CAR-T cells were studied in several orthotopic glioma models, including tumors engineered to vary in antigen expression to better reflect the heterogeneity seen in human disease.
What they found
After testing multiple combinations, researchers identified one especially potent pairing: IL-12 and decoy-resistant IL-18, known as DR-18.
“IL-12 and DR-18 work synergistically to activate the immune system, resulting in a dramatic influx of immune cells into the tumor-bearing brain,” said Chen, who is also a professor of microbiology, immunology, and molecular genetics at UCLA and a member of the UCLA Broad Stem Cell Research Center. “The diverse immune-cell population recruited into the brain contributes to attacking the tumor, including ones that cannot be directly recognized by the CAR-T cells themselves.”
The therapy demonstrated the ability to eliminate tumors containing cancer cells that lacked the target recognized by the CAR-T cells, a major hurdle in glioblastoma treatment because tumors can evolve and escape single-target therapies.
Addressing toxicity
Because IL-12 can trigger dangerous inflammation, the researchers also explored ways to reduce side effects while maintaining anti-tumor activity.
They found that adding a second engineered CAR-T approach targeting VEGF helped reduce treatment-related toxicity while maintaining strong tumor control in mice.
“When developing novel therapies, we always have to balance considerations for safety and efficacy,” Chen said. “Potent cytokines such as IL-12 and DR-18 have toxicity potential, which is why we performed in-depth studies to understand the nature and severity of the toxicity and devised ways to counteract safety concerns while maintaining anti-tumor activity.”
What this means for patients
The findings suggest a potential new strategy for treating recurrent high-grade gliomas. The researchers are now completing the necessary preclinical studies and raising funds to launch a Phase 1 clinical trial in patients with the disease.
“We are very encouraged by the ability of our cytokine-armored CAR-T cells to kill not only tumor cells that express IL-13Rα2, but also tumor cells that are not directly recognizable to the CAR-T cells,” Chen said. “We are excited to have developed a clinical protocol that would allow us to bring this therapy to the clinic while also providing a detailed toxicity management plan to ensure patient safety.”
About the research team
The study’s first author is Justin Clubb, a doctoral student in the department of Chemical & Biomolecular Engineering at UCLA. Other UCLA authors include Ryan Shih, Torahito Gao, Amanda Shafer, Shreya Vajragiri, Katrina Lam, Sohan Talluri, Amber Bouren and Robert Prins.
Funding
The study was funded in part by grants from the National Institutes of Health, the National Science Foundation and the Cancer Research Institute.
Journal
Cancer Research