基于RGD和pH响应性抗菌肽的用于实体瘤的双功能化脂质体递送系统。

Dual-functionalized liposomal delivery system for solid tumors based on RGD and a pH-responsive antimicrobial peptide.

作者信息

Zhang Qianyu, Lu Libao, Zhang Li, Shi Kairong, Cun Xingli, Yang Yuting, Liu Yayuan, Gao Huile, He Qin

机构信息

Key Laboratory of Drug Targeting and Drug Delivery Systems, West China School of Pharmacy, Sichuan University, No. 17, Block 3, Southern RenminRoad, Chengdu 610041, China.

出版信息

Sci Rep. 2016 Feb 4;6:19800. doi: 10.1038/srep19800.

DOI:10.1038/srep19800

PMID:26842655

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4740748/

Abstract

[D]-H6L9, as a pH-responsive anti-microbial peptide (AMP), has been evidenced by us to be an excellent choice in tumor microenvironment-responsive delivery as it could render liposomes responsive to the acidified tumor microenvironment. However, [D]-H6L9-modified liposomes could not actively target to tumor area. Therefore, integrin αvβ3-targeted peptide RGD was co-modified with [D]-H6L9 onto liposomes [(R + D)-Lip] for improved tumor delivery efficiency. Under pH 6.3, (R + D)-Lip could be taken up by C26 cells and C26 tumor spheroids (integrin αvβ3-positive) with significantly improved efficiency compared with other groups, which was contributed by both RGD and [D]-H6L9, while RGD did not increase the cellular uptake performance on MCF-7 cells (integrin αvβ3-negative). Results showed that RGD could decrease cellular uptake of (R + D)-Lip while [D]-H6L9 could increase it, implying the role of both RGD and [D]-H6L9 in cellular internalization of (R + D)-Lip. On the other hand, (R + D)-Lip could escape the entrapment of lysosomes. PTX-loaded (R + D)-Lip could further increase the cellular toxicity against C26 cells compared with liposomes modified only with RGD and [D]-H6L9 respectively, and achieve remarkable tumor inhibition effect on C26 tumor models.

摘要

[D]-H6L9作为一种pH响应性抗菌肽（AMP），我们已证明它是肿瘤微环境响应性递送的绝佳选择，因为它能使脂质体对酸化的肿瘤微环境产生响应。然而，[D]-H6L9修饰的脂质体不能主动靶向肿瘤区域。因此，将整合素αvβ3靶向肽RGD与[D]-H6L9共同修饰在脂质体上[(R + D)-Lip]，以提高肿瘤递送效率。在pH 6.3条件下，(R + D)-Lip能够被C26细胞和C26肿瘤球（整合素αvβ3阳性）摄取，与其他组相比效率显著提高，这是由RGD和[D]-H6L9共同作用的结果，而RGD并未提高MCF-7细胞（整合素αvβ3阴性）的细胞摄取性能。结果表明，RGD可降低(R + D)-Lip的细胞摄取，而[D]-H6L9可增加其摄取，这意味着RGD和[D]-H6L9在(R + D)-Lip的细胞内化过程中均发挥作用。另一方面，(R + D)-Lip能够逃脱溶酶体的捕获。与分别仅用RGD和[D]-H6L9修饰的脂质体相比，负载紫杉醇的(R + D)-Lip对C26细胞的细胞毒性进一步增加，并在C26肿瘤模型上实现了显著的肿瘤抑制效果。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/2983/4740748/765fae38dbfc/srep19800-f1.jpg

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基于RGD和pH响应性抗菌肽的用于实体瘤的双功能化脂质体递送系统。

Dual-functionalized liposomal delivery system for solid tumors based on RGD and a pH-responsive antimicrobial peptide.

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