Meirong Cui, Dan Zhang, Xian Zheng, Huan Zhai, Mo Xie, Qin Fan, Lianhui Wang, Chunhai Fan, Jie Chao
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We employ circular DNA origami to integrate predesigned modular multitarget protein binding sites and pH-responsive protein degradation promoters that specifically recognize cell-surface lysosome-shuttling receptors in tumor tissues. By precisely manipulating the stoichiometry and modularity of promoters and ligands targeting diverse proteins, the IMTAC nanodevice enables accurate localization and delivery into tumor tissues, where the acidic tumor microenvironment triggers degradation switch activation, multivalent binding, and efficient degradation of various prespecified proteins. The tissue-specificity and multiple ligands in IMTACs significantly improve the drug utilization rate while reducing off-target effects. 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引用次数: 0
摘要
溶酶体靶向嵌合体(LYTACs)已成为一种强大的模式,可消除传统上无法消除的细胞外肿瘤相关致病蛋白,但其生物利用度低和非特异性分布极大地限制了其在肿瘤精准治疗中的功效。开发一种能选择性靶向肿瘤组织并实现模块化设计的 LYTAC 系统至关重要,但也极具挑战性。我们在此报告了一种可编程纳米平台,该平台利用智能模块化 DNA LYTAC(IMTAC)纳米装置对多致病蛋白进行肿瘤特异性降解。我们利用环形 DNA 折纸将预先设计的模块化多目标蛋白结合位点和 pH 响应型蛋白降解启动子整合在一起,这些启动子能特异性识别肿瘤组织中的细胞表面溶酶体关闭受体。IMTAC 纳米装置通过精确控制针对不同蛋白质的启动子和配体的化学计量和模块化,实现了精确定位并输送到肿瘤组织,酸性肿瘤微环境会触发降解开关激活、多价结合并高效降解各种预先指定的蛋白质。IMTACs 的组织特异性和多种配体大大提高了药物利用率,同时减少了脱靶效应。重要的是,该系统展示了在肿瘤组织中协同降解表皮生长因子受体和 PDL1 的能力,可用于肝细胞癌(HCC)的联合靶向和免疫治疗,即使在低浓度下也能导致明显的肿瘤坏死并抑制体内肿瘤生长。这项研究提出了一种独特的策略,即构建一个通用、智能、模块化和简单编码的纳米平台,用于设计精准药物降解剂和开发专利抗肿瘤药物。
Intelligent Modular DNA Lysosome-Targeting Chimera Nanodevice for Precision Tumor Therapy
Lysosome targeting chimeras (LYTACs) have emerged as a powerful modality that can eliminate traditionally undruggable extracellular tumor-related pathogenic proteins, but their low bioavailability and nonspecific distribution significantly restrict their efficacy in precision tumor therapy. Developing a LYTAC system that can selectively target tumor tissues and enable a modular design is crucial but challenging. We here report a programmable nanoplatform for tumor-specific degradation of multipathogenic proteins using an intelligent modular DNA LYTAC (IMTAC) nanodevice. We employ circular DNA origami to integrate predesigned modular multitarget protein binding sites and pH-responsive protein degradation promoters that specifically recognize cell-surface lysosome-shuttling receptors in tumor tissues. By precisely manipulating the stoichiometry and modularity of promoters and ligands targeting diverse proteins, the IMTAC nanodevice enables accurate localization and delivery into tumor tissues, where the acidic tumor microenvironment triggers degradation switch activation, multivalent binding, and efficient degradation of various prespecified proteins. The tissue-specificity and multiple ligands in IMTACs significantly improve the drug utilization rate while reducing off-target effects. Importantly, this system demonstrates the capability of collabo-rative degradation of EGFR and PDL1 in tumor tissue for combined targeting and immunity therapy of hepatocellular carcinoma (HCC), resulting in obvious tumor necrosis and inhibition of tumor growth in vivo even at low concentrations. This study presents a unique strategy for building a general, intelligent, modular, and simple encoded nanoplatform for designing precision medicine degraders and developing proprietary antitumor drugs.
期刊介绍:
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