Nanoparticle targets tumor-infiltrating immune cells, flips switch telling them to fight
New research builds on Nobel-winning immune checkpoint blockade work
Immunotherapy’s promise in the fight against cancer drew international attention after two scientists won a Nobel Prize this year for unleashing the ability of the immune system to eliminate tumor cells.
But their approach, which keeps cancer cells from shutting off the immune system’s powerful T-cells before they can fight tumors, is just one way to use the body’s natural defenses against deadly disease. A team of Vanderbilt University bioengineers today announced a major breakthrough in another: penetrating tumor-infiltrating immune cells and flipping on a switch that tells them to start fighting. The team designed a nanoscale particle to do that and found early success using it on human melanoma tissue.
“Tumors are pretty conniving and have evolved many ways to evade detection from our immune system,” said John T. Wilson, assistant professor of chemical and biomolecular engineering and biomedical engineering. “Our goal is to rearm the immune system with the tools it needs to destroy cancer cells.
“Checkpoint blockade has been a major breakthrough, but despite the huge impact it continues to have, we also know that there are a lot of patients who don’t respond to these therapies. We’ve developed a nanoparticle to find tumors and deliver a specific type of molecule that’s produced naturally by our bodies to fight off cancer.”
That molecule is called cGAMP, and it’s the primary way to switch on what’s known as the stimulator of interferon genes (STING) pathway: a natural mechanism the body uses to mount an immune response that can fight viruses or bacteria or clear out malignant cells. Wilson said his team’s nanoparticle delivers cGAMP in a way that jump-starts the immune response inside the tumor, resulting in the generation of T-cells that can destroy the tumor from the inside and also improve responses to checkpoint blockade.
While the Vanderbilt team’s research focused on melanoma, their work also indicates that this could impact treatment of many cancers, Wilson said, including breast, kidney, head and neck, neuroblastoma, colorectal and lung cancer.
His findings appear today in a paper titled “Endosomolytic Polymersomes Increase the Activity of Cyclic Dinucleotide STING Agonists to Enhance Cancer Immunotherapy” in the journal Nature Nanotechnology.
Daniel Shae, a Ph.D. student on Wilson’s team and first author of the manuscript, said the process began with developing the right nanoparticle, built using “smart” polymers that respond to changes in pH that he engineered to enhance the potency of cGAMP. After 20 or so iterations, the team found one that could deliver cGAMP and activate STING efficiently in mouse immune cells, then mouse tumors and eventually human tissue samples.
“That’s really exciting because it demonstrates that, one day, this technology may have success in patients,” Shae said.
Their collaborators included Vanderbilt School of Medicine professors Justin Balko, Doug Johnson and Manny Ascano.
This research was supported by National Science Foundation grant CBET-1554623, Alex’s Lemonade Stand Foundation grant SID924, National Institutes of Health grants K23 CA204726/CA/NCI, R00CA181491 and 5R35GM119569-03, a Vanderbilt-Ingram Cancer Center Support Grant, a Vanderbilt Ingram Cancer Center Ambassador Discovery Grant, a VICC-Vanderbilt Center for Immunobiology Pilot Grant, Melanoma Research Alliance grant 503565 and Stand Up To Cancer Innovative Research Grant SU2C-4.