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Thursday, March 25, 2021
Engineered immune cells deliver anticancer signal, prevent cancer from spreading
In a study of mice, treatment with the engineered cells shrank tumors and prevented the cancer from spreading to other parts of the body.
Scientists have genetically engineered immune cells, called myeloid cells, to precisely deliver an anticancer signal to organs where cancer may spread. In a study of mice, treatment with the engineered cells shrank tumors and prevented the cancer from spreading to other parts of the body. The study, led by scientists at the National Cancer Institute’s (NCI) Center for Cancer Research, part of the National Institutes of Health, was published March 24, 2021, in Cell.
“This is a novel approach to immunotherapy that appears to have promise as a potential treatment for metastatic cancer,” said the study’s leader, Rosandra Kaplan, M.D., of NCI’s Center for Cancer Research.
Metastatic cancer — cancer that has spread from its original location to other parts of the body — is notoriously difficult to treat. Dr. Kaplan’s team has been exploring another approach: Preventing cancer from spreading in the first place.
Before cancer spreads, it sends out signals that get distant sites ready for the cancer’s arrival — like calling ahead to have the pillows fluffed in your hotel room prior to arrival. These “primed and ready” sites, discovered by Dr. Kaplan in 2005, are called premetastatic niches.
In the new study, the NCI team explored the behavior of immune cells in the premetastatic niche. Because Dr. Kaplan is a pediatric oncologist, the team mainly studied mice implanted with rhabdomyosarcoma, a type of cancer that develops in the muscles of children and often spreads to their lungs.
To study the premetastatic niche, the researchers looked at the lungs of the mice after tumors formed in the leg muscle but before the cancer was found in the lungs. The immune system’s natural ability to attack cancer was present but actively stifled in the lungs, the NCI scientists discovered. There were few cancer-killing immune cells, but many cells that suppress the immune system.
Myeloid cells, in particular, were abundant in the premetastatic niche and continued to gather there as the cancer progressed. Myeloid cells are part of the body’s first response to infection, injury, and cancer. When they detect a threat, they normally make interleukin 12 (IL-12), a signal that alerts and activates other immune cells. But myeloid cells in the lung premetastatic niche instead sent out signals that told cancer-fighting immune cells to stand down, the researchers found.
Together, these features of the lung premetastatic niche allow cancer cells to thrive when they spread there, Dr. Kaplan explained.
The NCI team wondered if they could take advantage of myeloid cells to spur the immune system into action in the premetastatic niche by changing the message they deliver. So, they used genetic engineering to add an extra gene for IL-12 to myeloid cells from lab mice.
“We chose myeloid cells to deliver IL-12 based on their unique ability to home to tumors and metastatic sites,” Dr. Kaplan said. “With IL-12, we’re turning the volume up on a message that’s been quieted.”
In mice with rhabdomyosarcoma, these genetically engineered myeloid cells, nicknamed GEMys, produced IL-12 in the primary tumor and in metastatic sites. As hoped, the GEMys recruited and activated cancer-killing immune cells in the premetastatic niche and lowered the signals that suppress the immune system, the researchers found.
“We were excited to see that the GEMys ‘changed the conversation’ in the premetastatic niche. They were now telling other immune cells to get ready to fight the cancer,” Dr. Kaplan said.
As a result, mice treated with GEMys had less metastatic cancer in the lungs, smaller tumors in the muscle, and they lived substantially longer than mice treated with nonengineered myeloid cells. The researchers found similar results when they studied mice with pancreatic tumors that spread to the liver.
The NCI team also found that, in combination with chemotherapy, surgery, or T-cell transfer therapy, the effects of the GEMy treatment improved. For example, giving mice a single dose of chemotherapy two days before the GEMy infusion cured mice with rhabdomyosarcoma, meaning the treatment completely eliminated all traces of cancer for more than 100 days.
“I have never seen that kind of durable cure in my research before. Typically, cancer growth will slow down after treatment, but then it will come back with a vengeance,” Dr. Kaplan said.
The team also found evidence that the chemotherapy and GEMys combination might prevent cancer from coming back. When the researchers reintroduced cancer cells into mice that had been cured by the combination treatment, tumors didn’t form. This suggests that the combination treatment leaves a long-lasting “immune memory” of the cancer, the researchers explained.
As a final step in their study, the researchers created GEMys from human cells grown in the lab. In lab dishes, the genetically engineered human cells produced IL-12 and activated cancer-killing immune cells.
The team plans to test the safety of human GEMys in a clinical trial of adults with cancer and, if it proves to be safe, in children and adolescents with cancer. There are many unanswered questions they hope to explore, including whether the homing pattern of GEMys is similar in humans and mice, and whether IL-12 from the GEMys will cause side effects in patients.
But the researchers are reassured by several factors. “We are delivering a small amount of IL-12 that’s similar to the body’s natural response to an infection, creating a ripple effect of immune activation against the cancer. In addition, GEMys don’t multiply rapidly inside the body, so they’re not flooding the system with IL-12,” explained Sabina Kaczanowska, Ph.D., first author of the study. These are important considerations because high levels of IL-12 throughout the body can be toxic.
“Although there are challenges of planning a first-in-human trial of a cell therapy, I’m grateful to have access to the resources of the NIH Clinical Center and to be able to lean on the experience of my NCI colleagues who have had decades of experience developing cell therapies for cancer,” Dr. Kaplan added.
About the Center for Cancer Research (CCR): CCR comprises nearly 250 teams conducting basic, translational, and clinical research in the NCI intramural program—an environment supporting innovative science aimed at improving human health. CCR’s clinical program is housed at the NIH Clinical Center — the world’s largest hospital dedicated to clinical research. For more information about CCR and its programs, visit ccr.cancer.gov.
About the National Cancer Institute (NCI): NCI leads the National Cancer Program and NIH’s efforts to dramatically reduce the prevalence of cancer and improve the lives of cancer patients and their families, through research into prevention and cancer biology, the development of new interventions, and the training and mentoring of new researchers. For more information about cancer, please visit the NCI website at cancer.gov or call NCI’s contact center, the Cancer Information Service, at 1-800-4-CANCER (1-800-422-6237).
About the National Institutes of Health (NIH): NIH, the nation's medical research agency, includes 27 Institutes and Centers and is a component of the U.S. Department of Health and Human Services. NIH is the primary federal agency conducting and supporting basic, clinical, and translational medical research, and is investigating the causes, treatments, and cures for both common and rare diseases. For more information about NIH and its programs, visit www.nih.gov.
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