A multifunctional nutrient transfer nanoCRISPR scaffold induces metabolic remodeling to fuel cancer immunotherapy

Abstract

Tumor cells are major consumers of glutamine and glucose in the tumor microenvironment (TME), causing nutrient deficiency of immune cells, leading to immune escape and resistance to immunotherapy. However, pharmacological modulation would cause metabolic inhibition in both immune cells and tumor cells. Herein, a multifunctional nutrient transfer nanoCRISPR scaffold (FUEL) is fabricated to realize “nutrient transfer” from tumor cells to immune cells and remodel the metabolism in the TME, thus fueling cancer immunotherapy. FUEL is endowed with characteristics of enhanced blood circulation, specific tumor cell targeting, effective lysosomal escape, cascaded reactive-oxygen-species (ROS)-responsiveness, and ASCT2/GLUT1 dual gene knockout. Consequently, FUEL can restrict nutrient uptake of tumor cells thoroughly, increase glucose and glutamine in the TME remarkably to satisfy metabolic demands of immune cells, and reduce immunosuppressive metabolites concurrently. Metabolomics data shows that energy metabolism and biosynthesis are reduced in tumor cells but enhanced in immune cells. FUEL remarkably impedes the growth, metastasis, and recurrence of solid tumors in mice, further shows stronger anti-tumor immune responses and enhanced tumor inhibition in combination with anti-PD-L1 antibody. Overall, this nutrient transfer strategy enables a “one arrow aiming at three eagles” effect that induces a cascade amplification of antitumor immune responses for the maximized tumor therapy efficacy.