Glutathione/Glucose-Depleting Nanoparticles with NO Generation for Ferroptosis/Starvation/NO-Induced Cancer Therapy

Abstract

Depleting intracellular glutathione (GSH) has emerged as a potent strategy to combat cancer. However, the existing GSH-depleting agents are too toxic or ineffective and standalone GSH depletion fails to yield a satisfactory curative effect. Herein, we present an intelligent nanoparticle that possesses GSH depletion, glucose consumption accompanied with H2O2 production, and NO generation properties for multimodal cancer therapy. The nanoparticle is constructed by synthesis of tetrasulfide bond-doped mesoporous silica nanoparticles followed by conjugating glucose oxidase (GOx) on the surface and loading l-arginine (l-Arg) into the mesopores. In this nanoparticle, the doped tetrasulfide bonds can quickly deplete GSH, which increases the cellular reactive oxygen species concentration to induce ferroptosis and meanwhile triggers particle biodegradation to expose the loaded l-Arg. Moreover, the elevated H2O2 level activates l-Arg to release NO for NO therapy. GOx consumes glucose to initiate starvation therapy and simultaneously produces a large amount of H2O2. Importantly, the produced H2O2 can not only potentiate ferroptosis but also promote NO release to enhance NO therapy. Besides, NO could in turn improve the efficacy of starvation therapy by damaging the mitochondria to block energy supply. In vitro and in vivo studies demonstrate that the nanoparticles show a great synergistic effect of ferroptosis/starvation/NO therapy, which can significantly kill cancer cells and remarkably inhibit tumor growth without obvious side effects. Therefore, we think that the designed nanoparticles may provide a promising paradigm for synergistic cancer therapy and hold a prospect in clinical trials.