Department of Pharmacy, The Second Affiliated Hospital and Yuying Children's Hospital of Wenzhou Medical University, Wenzhou 325035, China.
School of Pharmaceutical Sciences, Wenzhou Medical University, Wenzhou 325027, China.
ACS Appl Mater Interfaces. 2020 Jul 8;12(27):30031-30043. doi: 10.1021/acsami.0c03564. Epub 2020 Jun 24.
Tumor cells usually display metabolic, genetic, and microenvironment-related alterations, which are beneficial to tumor proliferation, tumor development, and resistance occurrence. Many transporters and enzymes, including ATB, xCT, and matrix metalloproteinases (MMPs), are involved in the altered cell metabolism and tumor microenvironment and often abnormally upregulated in malignant tumors. Meanwhile, these dysregulated transporters and enzymes provide targets not only for a pharmacological blockage to suppress tumor progress but also for tumor-specific delivery. Although transporters and MMPs have been widely reported for antitumor drug delivery, the feasibility of utilizing two strategies has never been elucidated yet. Herein, we developed an MP2-activated and TB-targeted ipoome with oxorubicin and orafenib (DS@MA-LS) loaded for optimal tumor drug delivery for cancer therapy. DS@MA-LS was designed to prolong blood circulation and deshield the PEG shell from MMP2 cleavage to expose lysine and target overexpressed ATB for enhanced tumor distribution and cancer cellular uptake. Besides the anticancer effects of loaded drugs, the endocytosed liposomes could further increase ROS production and suppress the antioxidant system to amplify oxidative stress. As expected, DS@MA-LS displayed enhanced targeted drug delivery to tumor sites with the MMP2-controlled ligand exposure and ATB-mediated uptake. More importantly, DS@MA-LS successfully inhibited the tumor growth and cancer cell proliferation both and by enhancing apoptosis and ferroptosis, which thanks to the increased ROS generation and impaired GSH synthesis synergistically amplified oxidative stress. Our results suggested that the tumor microenvironment-responsive, multistaged nanoplatform, DS@MA-LS, has excellent potential for optimal drug delivery and enhanced cancer treatment.
肿瘤细胞通常表现出代谢、遗传和微环境相关的改变,这些改变有利于肿瘤增殖、肿瘤发展和耐药性的发生。许多转运体和酶,包括 ATB、xCT 和基质金属蛋白酶(MMPs),参与了改变的细胞代谢和肿瘤微环境,并且在恶性肿瘤中经常异常上调。同时,这些失调的转运体和酶不仅为抑制肿瘤进展的药理学阻断提供了靶点,也为肿瘤特异性递药提供了靶点。尽管转运体和 MMPs 已被广泛报道用于抗肿瘤药物递送,但这两种策略的可行性尚未得到阐明。在此,我们开发了一种由 MP2 激活和 TB 靶向的载有阿霉素和奥沙利铂的ipoome(DS@MA-LS),用于癌症治疗的最佳肿瘤药物递送。DS@MA-LS 的设计目的是延长血液循环时间,并使 PEG 壳从 MMP2 切割中解屏蔽,以暴露赖氨酸并靶向过表达的 ATB,从而增强肿瘤分布和癌细胞摄取。除了负载药物的抗癌作用外,内吞的脂质体还可以进一步增加 ROS 产生并抑制抗氧化系统,以放大氧化应激。不出所料,DS@MA-LS 通过增强 MMP2 控制的配体暴露和 ATB 介导的摄取,显示出增强的肿瘤部位靶向药物递送。更重要的是,DS@MA-LS 通过增强细胞凋亡和铁死亡成功抑制了肿瘤生长和癌细胞增殖,这得益于 ROS 生成的增加和 GSH 合成的受损协同放大氧化应激。我们的结果表明,肿瘤微环境响应的多阶段纳米平台 DS@MA-LS 具有优化药物递送和增强癌症治疗的巨大潜力。
