Key Laboratory of Drug Targeting and Drug Delivery System, Ministry of Education, West China School of Pharmacy , Sichuan University , No. 17, Block 3, Southern Renmin Road , Chengdu 610041 , People's Republic of China.
Biomacromolecules. 2019 Oct 14;20(10):3755-3766. doi: 10.1021/acs.biomac.9b00800. Epub 2019 Sep 10.
As a major clinical tumor chemotherapeutic burden, multidrug resistance (MDR) is often a result of up-regulation of P-glycoprotein (P-gp), which strongly enhances anticancer drug efflux. The excess mitochondrial reactive oxygen species (ROS) could not only inhibit the function of P-gp through insufficient adenosine triphosphate supply but also cause apoptosis in MDR cells. Here, we designed a mitochondria targeting nanoparticulate system (GNPs-P-Dox-GA) for overcoming MDR through enhanced ROS generation, where increased cellular uptake as well as mitochondria accumulation were both realized by glycyrrhetinic acid (GA). First, doxorubicin was conjugated with GA (GA-Dox) and then grafted onto a -(2-hydroxypropyl) methacrylamide (HPMA) copolymer backbone via hydrazone bond (P-Dox-GA). The obtained P-Dox-GA was subsequently attached to the surface of gelatin nanoparticles (GNPs). As gelatin is a substrate of tumor extracellular metal matrix protease-2 (MMP2), GNPs-P-Dox-GA nanoparticles could be degraded and release small size P-Dox-GA to facilitate tumor tissue penetration. After P-Dox-GA internalized by tumor cells under GA mediation, Dox-GA detached from HPMA copolymer through hydrolysis of hydrazone bond and then efficiently delivered to mitochondria. Compared to non-GA modified carriers, GNPs-P-Dox-GA exhibited increased cellular uptake nearly 4-fold and mitochondria distribution 8.8-fold, and increased ROS production level nearly 3-fold, significantly decreased efflux rate (55% compared with Dox group) in drug resistant HepG2/ADR cells, and then led to improved antitumor efficiency in HepG2/ADR cells (IC only 19.5% of unmodified ones) as well as exciting antitumor efficiency on HepG2/ADR heterotopic tumor nude mice (1.75-fold higher tumor growth inhibition rate than free drug).
作为一种主要的临床肿瘤化学治疗负担,多药耐药(MDR)通常是 P-糖蛋白(P-gp)上调的结果,这强烈增强了抗癌药物的外排。过多的线粒体活性氧(ROS)不仅可以通过供应不足的三磷酸腺苷来抑制 P-gp 的功能,还可以导致 MDR 细胞凋亡。在这里,我们设计了一种靶向线粒体的纳米颗粒系统(GNPs-P-Dox-GA),通过增强 ROS 的产生来克服 MDR,其中通过甘草次酸(GA)实现了细胞摄取的增加和线粒体的积累。首先,阿霉素与 GA (GA-Dox)共轭,然后通过腙键(P-Dox-GA)接枝到 - (2-羟丙基)甲基丙烯酰胺(HPMA)共聚物主链上。所得的 P-Dox-GA 随后附着在明胶纳米颗粒(GNPs)的表面上。由于明胶是肿瘤细胞外金属基质蛋白酶-2(MMP2)的基质,GNPs-P-Dox-GA 纳米颗粒可以被降解并释放小尺寸的 P-Dox-GA,以促进肿瘤组织渗透。在 GA 介导下,肿瘤细胞内吞 P-Dox-GA 后,Dox-GA 通过腙键的水解从 HPMA 共聚物上脱离,然后有效地递送到线粒体。与非 GA 修饰的载体相比,GNPs-P-Dox-GA 表现出近 4 倍的细胞摄取和 8.8 倍的线粒体分布,以及近 3 倍的 ROS 产生水平,显著降低了耐药 HepG2/ADR 细胞中的流出率(与 Dox 组相比为 55%),从而提高了 HepG2/ADR 细胞的抗肿瘤效率(IC 仅为未修饰的 19.5%),以及在 HepG2/ADR 异质肿瘤裸鼠中令人兴奋的抗肿瘤效率(比游离药物高 1.75 倍的肿瘤生长抑制率)。
