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Main Authors: Liu, Jianxiong, Yan, Yue, Zhang, Yimeng, Pan, Xingquan, Xia, Heming, Zhou, Jiayi, Wan, Fangjie, Huang, Xinyu, Zhang, Weiwei, Zhang, Qiang, Chen, Binlong, Wang, Yiguang
Format: Artículo científico
Language:en
Published: Journal of the American Chemical Society 2024
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/39639594/
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author Liu, Jianxiong
Yan, Yue
Zhang, Yimeng
Pan, Xingquan
Xia, Heming
Zhou, Jiayi
Wan, Fangjie
Huang, Xinyu
Zhang, Weiwei
Zhang, Qiang
Chen, Binlong
Wang, Yiguang
author_facet Liu, Jianxiong
Yan, Yue
Zhang, Yimeng
Pan, Xingquan
Xia, Heming
Zhou, Jiayi
Wan, Fangjie
Huang, Xinyu
Zhang, Weiwei
Zhang, Qiang
Chen, Binlong
Wang, Yiguang
Liu, Jianxiong
Yan, Yue
Zhang, Yimeng
Pan, Xingquan
Xia, Heming
Zhou, Jiayi
Wan, Fangjie
Huang, Xinyu
Zhang, Weiwei
Zhang, Qiang
Chen, Binlong
Wang, Yiguang
collection PubMed - marine biology
contents Lysosome-Mitochondria Cascade Targeting Nanoparticle Drives Robust Pyroptosis for Cancer Immunotherapy. Liu, Jianxiong Yan, Yue Zhang, Yimeng Pan, Xingquan Xia, Heming Zhou, Jiayi Wan, Fangjie Huang, Xinyu Zhang, Weiwei Zhang, Qiang Chen, Binlong Wang, Yiguang Lysosomes Nanoparticles Mitochondria Pyroptosis Humans Animals Mice Immunotherapy Photosensitizing Agents Neoplasms Cell Line, Tumor Antineoplastic Agents Reactive Oxygen Species The subcellular distribution of cargoes plays a crucial role in determining cell fate and therapeutic efficacy. However, achieving the precise delivery of therapeutics to specific intracellular targets remains a significant challenge. Here, we present a trimodular and acid/enzyme-gated nanoplatform (TAEN) that undergoes disassembly within acidic endosomes and then is cleaved by lysosomal cathepsin B to facilitate efficient and targeted transport of released cargoes into mitochondria compartments. By utilizing this nanovehicle, we successfully achieve selective sorting of photosensitizer molecules into mitochondria with a colocalization coefficient of up to 0.98, leading to the generation of reactive oxygen species stress specifically within the mitochondria for potent pyroptosis-based cancer therapy. The induction of mitochondrial stress triggers the intrinsic apoptotic pathway as well as caspase-3/gasdermin-E (GSDME) cascade, resulting in an enhanced cancer cell killing efficacy by nearly 2 orders of magnitude as compared to lysosomal stress. Furthermore, due to its superior capability to stimulate both innate and adaptive immune responses, our mitochondria-sorted nanophotosensitizer exhibits robust antitumor immune efficacy in multiple tumor-bearing mice models. This study not only provides insights into engineering nanomedicines for subcellular targeted delivery but also offers a valuable toolkit for advanced research in the field of nanobiology at subcellular resolution.
format Artículo científico
id pubmed_39639594
institution PubMed
language en
publishDate 2024
publisher Journal of the American Chemical Society
record_format pubmed
spellingShingle Lysosome-Mitochondria Cascade Targeting Nanoparticle Drives Robust Pyroptosis for Cancer Immunotherapy.
Liu, Jianxiong
Yan, Yue
Zhang, Yimeng
Pan, Xingquan
Xia, Heming
Zhou, Jiayi
Wan, Fangjie
Huang, Xinyu
Zhang, Weiwei
Zhang, Qiang
Chen, Binlong
Wang, Yiguang
Lysosomes
Nanoparticles
Mitochondria
Pyroptosis
Humans
Animals
Mice
Immunotherapy
Photosensitizing Agents
Neoplasms
Cell Line, Tumor
Antineoplastic Agents
Reactive Oxygen Species
Lysosome-Mitochondria Cascade Targeting Nanoparticle Drives Robust Pyroptosis for Cancer Immunotherapy. Liu, Jianxiong Yan, Yue Zhang, Yimeng Pan, Xingquan Xia, Heming Zhou, Jiayi Wan, Fangjie Huang, Xinyu Zhang, Weiwei Zhang, Qiang Chen, Binlong Wang, Yiguang Lysosomes Nanoparticles Mitochondria Pyroptosis Humans Animals Mice Immunotherapy Photosensitizing Agents Neoplasms Cell Line, Tumor Antineoplastic Agents Reactive Oxygen Species The subcellular distribution of cargoes plays a crucial role in determining cell fate and therapeutic efficacy. However, achieving the precise delivery of therapeutics to specific intracellular targets remains a significant challenge. Here, we present a trimodular and acid/enzyme-gated nanoplatform (TAEN) that undergoes disassembly within acidic endosomes and then is cleaved by lysosomal cathepsin B to facilitate efficient and targeted transport of released cargoes into mitochondria compartments. By utilizing this nanovehicle, we successfully achieve selective sorting of photosensitizer molecules into mitochondria with a colocalization coefficient of up to 0.98, leading to the generation of reactive oxygen species stress specifically within the mitochondria for potent pyroptosis-based cancer therapy. The induction of mitochondrial stress triggers the intrinsic apoptotic pathway as well as caspase-3/gasdermin-E (GSDME) cascade, resulting in an enhanced cancer cell killing efficacy by nearly 2 orders of magnitude as compared to lysosomal stress. Furthermore, due to its superior capability to stimulate both innate and adaptive immune responses, our mitochondria-sorted nanophotosensitizer exhibits robust antitumor immune efficacy in multiple tumor-bearing mice models. This study not only provides insights into engineering nanomedicines for subcellular targeted delivery but also offers a valuable toolkit for advanced research in the field of nanobiology at subcellular resolution.
title Lysosome-Mitochondria Cascade Targeting Nanoparticle Drives Robust Pyroptosis for Cancer Immunotherapy.
topic Lysosomes
Nanoparticles
Mitochondria
Pyroptosis
Humans
Animals
Mice
Immunotherapy
Photosensitizing Agents
Neoplasms
Cell Line, Tumor
Antineoplastic Agents
Reactive Oxygen Species
url https://pubmed.ncbi.nlm.nih.gov/39639594/