Daily Archives: August 14, 2020
Immunotherapy has revolutionized cancer treatment by stimulating the patient’s own immune system to attack cancer cells, yielding remarkably quick and complete remission in some cases. But such drugs work for less than a quarter of patients because tumors are notoriously adept at evading immune assault.
A new study in mice by researchers at Washington University School of Medicine in St. Louis has shown that the effects of a standard immunotherapy drug can be enhanced by blocking the protein TREM2, resulting in complete elimination of tumors. The findings, which are published in the journal Cell, point to a potential new way to unlock the power of immunotherapy for more cancer patients.
Immune cells infiltrate a human tumor in the four colorized images above. In a mouse study, researchers at Washington University School of Medicine in St. Louis have found that an antibody that targets the protein TREM2 empowers tumor-destroying immune cells and improves the effectiveness of cancer immunotherapy.
“Essentially, we have found a new tool to enhance tumor immunotherapy,” said senior author Marco Colonna, MD, the Robert Rock Belliveau, MD, Professor of Pathology. “An antibody against TREM2 alone reduces the growth of certain tumors, and when we combine it with an immunotherapy drug, we see total rejection of the tumor. The nice thing is that some anti-TREM2 antibodies are already in clinical trials for another disease. We have to do more work in animal models to verify these results, but if those work, we’d be able to move into clinical trials fairly easily because there are already a number of antibodies available.”
T cells, a kind of immune cell, have the ability to detect and destroy tumor cells. To survive, tumors create a suppressive immune environment in and around themselves that keeps T cells subdued. A type of immunotherapy known as checkpoint inhibition wakes T cells from their quiescence so they can begin attacking the tumor. But if the tumor environment is still immunosuppressive, checkpoint inhibition alone may not be enough to eliminate the tumor.
An expert on the immune system, Colonna has long studied a protein called TREM2 in the context of Alzheimer’s disease, where it is associated with underperforming immune cells in the brain. Colonna and first author Martina Molgora, PhD, a postdoctoral researcher, realized that the same kind of immune cells, known as macrophages, also were found in tumors, where they produce TREM2 and promote an environment that suppresses the activity of T cells.
“When we looked at where TREM2 is found in the body, we found that it is expressed at high levels inside the tumor and not outside of the tumor,” Colonna said. “So it’s actually an ideal target, because if you engage TREM2, you’ll have little effect on peripheral tissue.”
Colonna and Molgora — along with colleagues Robert D. Schreiber, PhD, the Andrew M. and Jane M. Bursky Distinguished Professor; and William Vermi, MD, an immunologist at the University of Brescia — set out to determine whether inhibiting TREM2 could reduce immunosuppression and boost the tumor-killing powers of T cells. As part of this study, the researchers injected cancerous cells into mice to induce the development of a sarcoma.
The mice were divided into four groups. In one group, the mice received an antibody that blocked TREM2; in another group, a checkpoint inhibitor; in the third group, both; and the fourth group, placebo. In the mice that received only placebo, the sarcomas grew steadily. In the mice that received the TREM2 antibody or the checkpoint inhibitor alone, the tumors grew more slowly and plateaued or, in a few cases, disappeared. But all of the mice that received both antibodies rejected the tumors completely. The researchers repeated the experiment using a colorectal cancer cell line with similarly impressive results.