Researchers find combination can enhance ipilimumab immunotherapy
Anti-CTLA-4 treatment triggers immune-suppressing EZH2 on T cells; clinical trial open
MD Anderson News Release June 15, 2018
Using a targeted therapy to block a protein that suppresses T cell activity could improve cancer treatment with immune checkpoint inhibitors, researchers at The University of Texas MD Anderson Cancer Center report today in the Journal of Clinical Investigation.
The team showed that EZH2 is elevated in immune T cells in patients after treatment with ipilimumab, a drug that unleashes an immune response by blocking the activity of CTLA-4 on T cells, white blood cells that serve as the targeted warriors of the adaptive immune system.
“Immune checkpoint therapy has led to significant clinical responses in some patients but in order to provide benefit to even more patients, we will need rationally designed combination therapies,” said senior author Padmanee Sharma, M.D., Ph.D., professor of Genitourinary Medical Oncology and Immunology.
“Our studies show that anti-CTLA-4 therapy can lead to increased EZH2 expression in T cells, which can act to diminish T cell responses,” Sharma said.
Preclinical research in mouse models showed that combination therapy using a drug that inhibits EZH2 and ipilimumab improved T cell responses, tumor rejection and extended survival. MD Anderson researchers have translated these findings into the clinic, with a phase I clinical trial of the combination open this spring.
First clue in ipilimumab-treated patients
The team’s research began with an observation in Sharma’s lab with experiments conducted by first author Sangeeta Goswami, M.D., Ph.D., who was studying patient samples from a clinical trial of ipilimumab. Sharma’s team, working through MD Anderson’s Immunotherapy platform, examined samples from bladder cancer, prostate cancer and melanoma patients taken before and after treatment to analyze changes in immune activity.
Goswami found EZH2 levels in patients’ T cells elevated after treatment with ipilimumab and that increase was correlated in prostate cancer patients with cancer progression as measured by prostate specific antigen levels.
EZH2 is known to work epigenetically, repressing genes by regulating a histone protein to stabilize expression of a transcription factor in regulatory T cells that act to suppress immune response.
To better understand the consequences of EZH2 elevation, Goswami, Sharma and colleagues conducted a series of lab experiments.
They were the first to show that EZH2 inhibition enhances the function of effector T cells (CD8+ and CD4+ T cells). Goswami ran a series of tests on four different inhibitors and showed for the first time that CPI-1205 had the greatest effect suppressing T cell differentiation into regulatory T cells.
Follow-up experiments showed that EZH2 inhibition forced regulatory T cells to lose their suppressive capacity, changing their phenotype to effector-like T cells. Additionally, mice genetically altered to lack EZH2 on their regulatory T cells had significant tumor regression compared to control mice after inoculation with a bladder cancer cell line. They also had elevated levels of CD8-positive T cells in and around their tumors
Connection with anti-CTLA-4
T cells are activated by CD28, a co-stimulatory molecule that fires up the cells once their T cell receptor has connected with an antigen target. CD28 also turns on CTLA-4, an immune checkpoint. The team hypothesized that blocking CTLA-4 with ipilimumab results in exaggerated CD28 signaling that increases EZH2 in T cells.
By examining T cells collected before and after treatment with ipilimumab for bladder, melanoma and prostate cancer patients, the team found increased EZH2 expression in effector T cells and regulatory T cells after treatment. Among prostate cancer patients, elevated EZH2 in those T cells was correlated with PSA-measured tumor progression.
Combination thwarts tumor growth
Treatment with the ipilimumab and CPI-1205 combination caused major reductions in tumor growth, significantly increased survival, reduced the percentage of regulatory T cells and increased tumor-penetrating effector cells compared to treatment with either drug alone in two types of mice, one that develops bladder cancer and one with melanoma.
Treating mice that have EZH2 knocked out with ipilimumab resulted in complete tumor rejection by the immune system.
No immune-related toxicities were observed in mice treated with the combination.
The phase I clinical trial at MD Anderson is a safety and dosing trial that treats patients with advanced tumors with either combination of CPI-1205 and ipilimumab or CPI-1205 and pembrolizumab, which blocks PD1, a different immune checkpoint.
Co-authors with Sharma and Goswami are Jan Zhang, Swetha Anandhan, Liangwen Xiong, Ph.D., Ana Aparicio, M.D., and Sumit Subudhi, M.D., Ph.D., of Genitourinary Medical Oncology; Irina Apostolou, Ph.D., Jill Skepner, and Patrick Trojer, Ph.D., of Constellation Pharmaceuticals; Xuejun Zhang, M.D., and Hao Zhao, Ph.D., of MD Anderson’s Immunotherapy Platform; and Jim Allison, Ph.D., of Immunology. Anandhan is a graduate student in the MD Anderson/UTHealth Graduate School of Biomedical Sciences.
Sharma serves on the scientific advisory board of Constellation Pharmaceuticals, which makes CPI-1205. She has consulted for Bristol-Myers Squibb, which makes ipilimumab, known commercially as Yervoy.
Funding for this research was provided by the Parker Institute for Cancer Immunotherapy and a grant from the National Cancer Institute of the National Institutes of Health (RO1CA163793).