Cell-based immunotherapy continues to be a promising avenue for cancers that standard therapy has failed. Although the specificity, avidity, and efficacy of infused cells have improved, immunocytotherapy still faces substantial hurdles. To this end, we developed a structure-based rational design approach and constructed a novel Dual Targeting Chimeric Receptor (DTCR) PD1-DAP10/NKG2D comprising the truncated ectodomain of PD1 fused to a key co-stimulatory receptor DAP10, and subsequently harnessed the activating receptor NKG2D, which evaluated the capacity of solid tumor cell killing. Retroviral transduction of DTCR dramatically increased NK92 cell surface expression of PD1 and NKG2D, which boosted robust cytotoxicity against human gastric cell SGC-7901. Chimeric receptor DTCR stimulation elicited a significant increase of TNF-α and TRAIL, which can trigger apoptosis of SGC-7901 cells. More importantly, DTCR-NK92 cells had considerable antitumor activity in the solid tumor cell SGC-7901-bearing mice model. Collectively, we demonstrated that expression of DTCR markedly augmented the cytotoxic potential of NK92 cells against solid tumor cells, and this potentially promising treatment modality will facilitate clinical translation of potent NK-tailored chimeric receptor strategy for a generalized cellular therapy that may be conducive to treat a wide range of solid tumors.
