Breast cancer cells turn killer immune cells into allies
Credit: Chan et al., 2020
Researchers at Johns Hopkins University School of Medicine have discovered that breast cancer cells can alter the function of immune cells known as Natural killer (NK) cells so that instead of killing the cancer cells, they facilitate their spread to other parts of the body. The study, which will be published July 9 in the Journal of Cell Biology (JCB), suggests that preventing this reprogramming might stop breast cancer from metastasizing to other tissues, a major cause of death in breast cancer patients.
Breast cancer cells spread to other parts of the body by invading the surrounding, healthy breast tissue until they reach the circulation, which can carry them to other tissues where they can form new metastatic tumors. NK cells are white blood cells that can recognize and kill cancer cells as they spread through the body.
“Breast cancer cells must overcome NK cell surveillance in order to form distant metastases,” says Andrew Ewald, a professor of cell biology at Johns Hopkins University School of Medicine and co-director of the Cancer Invasion and Metastasis Program in the Sidney Kimmel Comprehensive Cancer Center. “However, we do not fully understand how breast cancer cells escape NK cell-mediated immunosurveillance during their transit through the circulation and the initial seeding of distant organs.”
Although metastasizing breast cancer cells are initially vulnerable to NK cells, they are quickly able to alter the behavior of their would-be killers, reprogramming them so that they actually promote the later stages of metastasis, Ewald and colleagues discovered. Using several new assays to model metastasis in the laboratory as well as experiments in mice, the researchers found that, after they encounter tumor cells, human and mouse NK cells lose the ability to restrict tumor invasion and instead help cancer cells form new tumors.
NK cells exposed to tumors undergo dramatic changes, turning thousands of genes on and off and expressing different receptor proteins on their surface. Ewald and colleagues found that antibodies targeting two key receptor proteins on the surface of NK cells, called TIGIT and KLRG1, prevented NK cells from helping breast cancer cells seed new tumors. The FDA-approved drugs decitabine and azacitidine had similar effects, likely because they prevent large-scale changes in gene activity by inhibiting enzymes known as DNA methyltransferases.
The researchers found that combining decitabine or azacitidine treatment with anti-TIGIT or anti-KLRG1 antibodies was particularly effective at preventing NK cells from enhancing the metastatic potential of breast cancer cells.
“The synergistic effects of DNA methyltransferase inhibitors with receptor-blocking antibodies suggests a viable clinical strategy to reactivate tumor-exposed NK cells to target and eliminate breast cancer metastases,” says Isaac Chan, a medical oncology fellow in Ewald’s laboratory and lead author of the study.
Ewald notes, “Combined with our observation that NK cells are abundant early responders to disseminated breast cancer cells, our data provide preclinical rationale for the concept of NK cell-directed immunotherapies in the adjuvant setting for breast cancer patients with high risk of metastatic recurrence.”
Chan et al., 2020. J. Cell Biol. https:/
About the Journal of Cell Biology The Journal of Cell Biology (JCB) features peer-reviewed research on all aspects of cellular structure and function. All editorial decisions are made by research-active scientists in conjunction with in-house scientific editors. JCB makes all of its content free online no later than six months after publication. Established in 1955, JCB is published by Rockefeller University Press. For more information, visit http://rupress.org/jcb>jcb.org.
Visit our http://rupress.org/pages/newsroom>Newsroom, and sign up for a weekly preview of articles to be published. Embargoed media alerts are for journalists only.
Follow JCB on Twitter at https://twitter.com/JCellBiol>@JCellBiol and https://twitter.com/rockupress>@RockUPress.
Related Journal Article