Scientists have discovered a new method that delivers a “one-two punch” to aid T cells attack solid tumors.
In mice models, targeting regulators that regulate gene functions linked to inflammation resulted in higher anti-cancer activity. CAR T cell therapy was pioneered at Penn Medicine by Carl H. June, MD, the Richard W. Vague Professor in Immunotherapy at Penn and director of the Center for Cellular Immunotherapies (CCI) at Abramson Cancer Center, whose work led to the first approved CAR T cell therapy for B-cell acute lymphoblastic leukemia in 2017. Since then, personalized cellular therapies have revolutionized blood cancer treatment, but remained stubbornly ineffective against solid tumors, such as lung cancer and breast cancer.
“Our study shows that immune inflammatory regulator targeting is worth additional investigation to enhance T cell potency.”
One of the challenges for CAR T cell therapy in solid tumors is a phenomenon known as T cell exhaustion, where the persistent antigen exposure from the solid mass of tumor cells wears out the T cells to the point that they aren’t able to mount an antitumor response. Engineering already exhausted T cells from patients for CAR T cell therapy results in a less effective product because the T cells don’t multiply enough or remember their task as well.
Solid Tumor Treatment
Previous observational studies hinted at the inflammatory regulator Regnase-1 as a potential target to indirectly overcome the effects of T cell exhaustion because it can cause hyperinflammation when disrupted in T cells – reviving them to produce an antitumor response. The research team, including lead author David Mai, a Bioengineering graduate student in the School of Engineering and Applied Science, and co-corresponding author Neil Sheppard, DPhil, head of the CCI T Cell Engineering Lab, hypothesized that targeting the related, but independent Roquin-1 regulator at the same time could boost responses further.“Each of these two regulatory genes has been implicated in restricting T cell inflammatory responses, but we found that disrupting them together produced much greater anticancer effects than disrupting them individually,” Mai said. “By building on previous research, we are starting to get closer to strategies that seem to be promising in the solid tumor context.”
The team used CRISPR-Cas9 gene editing to knock out Regnase-1 and Roquin-1 individually and together in healthy donor T cells with two different immune receptors that are currently being investigated in Phase I clinical trials: the mesothelin-targeting M5 CAR (mesoCAR) and the NY-ESO-1-targeting 8F TCR (NYESO TCR). Neither engineered T cell product targets CD19, the antigen targeted by most approved CAR T cell therapies, as this antigen is not present in solid tumors.
After CRISPR editing, the T cells were expanded and infused in solid tumor mice models, where researchers observed the double knockout led to at least 10 times as many engineered T cells compared to disabling Regnase-1 alone, as well as increased antitumor immune activity and longevity of the engineered T cells. In some mice, it also led to overproduction of lymphocytes, causing toxicity.
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Source-Eurekalert