Efficient and tumor-specific knockdown of MTDH gene attenuates paclitaxel resistance of breast cancer cells both in vivo and in vitro

Drug resistance of paclitaxel (TAX), the first-line chemotherapy drug for breast cancer, was reported to develop in 90% of patients with breast cancer, especially metastatic breast cancer. Investigating the mechanism of TAX resistance of breast cancer cells and developing the strategy improving its...

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Published in:Breast cancer research : BCR 2018-09, Vol.20 (1), p.113-113, Article 113
Main Authors: Yang, Liu, Tian, Yanhua, Leong, Wei Sun, Song, Heng, Yang, Wei, Wang, Meiqi, Wang, Xinle, Kong, Jing, Shan, Baoen, Song, Zhengchuan
Format: Article
Language:English
Subjects:
Breast cancer
Cancer
Cancer therapies
Care and treatment
Cell cycle
Chemotherapy
Co-delivery
Drug resistance
Efficiency
FDA approval
Gene expression
Genetic aspects
Metadherin (MTDH) gene
Metastases
Nanoparticle (NP)
Nanoparticles
NF-κB protein
Paclitaxel
Paclitaxel (TAX)
Patients
siRNA
Solid tumors
Studies
Tumor cell lines
Tumors
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Summary:Drug resistance of paclitaxel (TAX), the first-line chemotherapy drug for breast cancer, was reported to develop in 90% of patients with breast cancer, especially metastatic breast cancer. Investigating the mechanism of TAX resistance of breast cancer cells and developing the strategy improving its therapeutic efficiency are crucial to breast cancer cure. We here report an elegant nanoparticle (NP)-based technique that realizes efficient breast cancer treatment of TAX. Using lentiviral vector-mediated gene knockdown, we first demonstrated that TAX therapeutic efficiency was closely correlated with metadherin (MTDH) gene expression in breast cancer cell lines. This finding was also supported by efficacy of TAX treatment in breast cancer patients from our clinical studies. Specifically, TAX treatment became more effective when MTDH expression was decreased in MCF-7 cancer cells by the blocking nuclear factor-kappa B (NF-κB) pathway. Based on these findings, we subsequently synthesized a polymeric NP that could co-deliver MTDH-small interfering RNA (MTDH-siRNA) and TAX into the breast cancer tumors in tumor-bearing mice. The NPs were composed of a cationic copolymer, which wrapped TAX in the inside and adsorbed the negatively charged siRNA on their surface with high drug-loading efficiency and good stability. NP-based co-delivery approach can effectively knock down the MTDH gene both in vitro and in vivo, which dramatically inhibits breast tumor growth, achieving effective TAX chemotherapy treatment without overt side effects. This study provides a potential therapeutic strategy for the treatment of a wide range of solid tumors highly expressing MTDH.
ISSN:1465-542X
1465-5411
1465-542X
DOI:10.1186/s13058-018-1042-7