吉瑞替尼可逆转ABCB1介导的多药耐药性:临床前体外和动物实验

Meng Zhang, Mei-Ling She, Jun Chen, Xiao-Qi Zeng, Qing-Quan Xiong, Ying-Huan Cen, Jia-An Ye, Guo-Bin Qiu, Shu-Yi Yang, Guang-Hui Ren
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摘要

多重耐药性(MDR)给癌症治疗带来了巨大挑战。靶向ATP结合盒B亚家族成员1(ABCB1)是克服MDR的可行策略。本研究考察了临床前体外和动物研究中使用吉特替尼的情况,吉特替尼是一种能逆转ABCB1介导的MDR的FLT3抑制剂。在无毒水平下,吉特替尼能显著提高过表达 ABCB1 的癌细胞对化疗药物的敏感性。此外,吉特替尼还能抑制耐药细胞集落和三维球体的发育。对其逆转机制的研究表明,吉特替尼可以直接与 ABCB1 的药物结合位点结合,抑制药物外流活性。因此,底物药物在 MDR 细胞中的细胞毒性增加。此外,吉尔替尼在增加 ATPase 活性的同时,使 ABCB1 的表达和亚细胞分布保持不变,并抑制了 AKT 或 ERK 的激活。对接分析表明,吉尔替尼可与 ABCB1 转运体的药物结合位点相互作用。体内研究表明,吉尔替尼可提高紫杉醇在裸鼠体内的抗肿瘤疗效,且无明显毒副作用。总之,我们的临床前研究表明,吉特替尼与底物药物联合使用,有可能在临床环境中成功克服ABCB1介导的MDR。
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Gilteritinib reverses ABCB1-mediated multidrug resistance: Preclinical in vitro and animal investigations.

Multi-drug resistance (MDR) poses a significant challenge to cancer treatment. Targeting ATP-binding cassette subfamily B member 1 (ABCB1) is a viable strategy for overcoming MDR. This study examined the preclinical in vitro and animal studies that used gilteritinib, a FLT3 inhibitor that reverses ABCB1-mediated MDR. At nontoxic levels, gilteritinib significantly increased the susceptibility of cancer cells overexpressing ABCB1 to chemotherapeutic drugs. Furthermore, it impaired the development of drug-resistant cell colonies and 3D spheroids. Studies on the reversal mechanism have shown that gilteritinib can directly bind to the drug-binding site of ABCB1, inhibiting drug efflux activity. Consequently, the substrate's drug cytotoxicity increases in MDR cells. Furthermore, gilteritinib increased ATPase activity while leaving ABCB1 expression and subcellular distribution unchanged and inhibited AKT or ERK activation. Docking analysis indicated that Gilteritinib could interact with the drug-binding site of the ABCB1 transporter. In vivo studies have shown that gilteritinib improves the antitumor efficacy of paclitaxel in nude mice without obvious toxic effects. In conclusion, our preclinical investigations show that gilteritinib has the potential to successfully overcome ABCB1-mediated MDR in a clinical environment when combined with substrate medicines.

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