Nodularin-R通过抑制PPP1CA协同增强阿比特龙对抗阉割耐药前列腺癌的能力

IF 5.3 2区 医学 Q1 Biochemistry, Genetics and Molecular Biology
Yiqiao Huang, Yi Cen, Hualing Wu, Guohao Zeng, Zhengming Su, Zhiming Zhang, Shourui Feng, Xianhan Jiang, Anyang Wei
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引用次数: 0

摘要

在临床上,大多数前列腺癌(PCa)患者在接受雄激素剥夺疗法(ADT)(包括ADT的首选药物阿比特龙)治疗后,不可避免地会发展为铸型耐药前列腺癌(CRPC),预后较差。因此,有必要深入探讨阿比特龙的耐药机制。研究人员利用全基因组CRISPR/Cas9基因敲除技术筛选CRPC细胞系22Rv1的阿比特龙耐药基因。结合生物信息学,筛选出一个在CRPC患者中高表达且预后不良的关键基因。然后,通过沉默和过表达探讨了靶基因对阿比特龙耐药 22Rv1 细胞功能的影响。此外,还发现了一种具有潜在靶向作用的天然产物,并通过分子对接和蛋白表达进行了验证。分子动力学模拟揭示了天然产物影响靶蛋白表达的潜在机制。最后,通过细胞和体内实验验证了该天然产物和阿比特龙的联合抗肿瘤作用。研究成功鉴定了五个常见的耐药基因(KCNJ3、COL2A1、PPP1CA、MDH2和EXOSC5),其中PPP1CA的高表达预示着最差的无病生存期。此外,PPP1CA 在阿比特龙耐药的 22Rv1 细胞中高表达。沉默PPP1CA可提高细胞对阿比特龙的敏感性,同时促进细胞凋亡并抑制克隆形成。过表达 PPP1CA 则产生相反的效果。分子对接揭示了天然产物nodularin-R与PPP1CA的结合模式,其抑制作用与剂量有关。从机理上讲,nodularin-R能减弱PPP1CA和USP11(去泛素化酶)之间的相互作用,从而促进PPP1CA的降解。此外,2.72 μM nodularin-R 和 54.5 μM 阿比特龙的组合能协同抑制耐药 22Rv1 细胞的功能。体内实验还发现,联合疗法能显著抑制肿瘤生长,减少 PPP1CA 的诱导表达。PPP1CA是阿比特龙耐药的关键驱动因素,而nodularin-R通过抑制PPP1CA增强了阿比特龙抗CRPC的效果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Nodularin-R Synergistically Enhances Abiraterone Against Castrate- Resistant Prostate Cancer via PPP1CA Inhibition.

Nodularin-R Synergistically Enhances Abiraterone Against Castrate- Resistant Prostate Cancer via PPP1CA Inhibition.

Clinically, most prostate cancer (PCa) patients inevitably progress to castration-resistant prostate cancer (CRPC) with poor prognosis after androgen deprivation therapy (ADT), including abiraterone, the drug of choice for ADT. Therefore, it is necessary to explore the resistance mechanism of abiraterone in depth. Genome-wide CRISPR/Cas9 knockout technology was used to screen CRPC cell line 22Rv1 for abiraterone-resistant genes. Combined with bioinformatics, a key gene with high expression and poor prognosis in CRPC patients was screened. Then, the effects of target gene on abiraterone-resistant 22Rv1 cell function were explored by silencing and overexpression. Further, a natural product with potential targeting effect was identified and validated by molecular docking and protein expression. Molecular dynamics simulations revealed potential mechanism for the natural product affecting target protein expression. Finally, the combined anti-CRPC effects of the natural product and abiraterone were validated by cellular and in vivo experiments. Five common resistance genes (KCNJ3, COL2A1, PPP1CA, MDH2 and EXOSC5) were identified successfully, among which high PPP1CA expression had the worst prognosis for disease-free survival. Moreover, PPP1CA was highly expressed in abiraterone-resistant 22Rv1 cells. Silencing PPP1CA increased cell sensitivity to abiraterone while promoting apoptosis and inhibiting clone formation. Overexpressing PPP1CA exerted the opposite effects. Molecular docking revealed the binding mode of the natural product nodularin-R to PPP1CA with a dose-dependent manner for inhibition. Mechanistically, nodularin-R attenuates the interaction between PPP1CA and USP11 (deubiquitinating enzyme), potentially promoting PPP1CA degradation. Additionally, combination of 2.72 μM nodularin-R and 54.5 μM abiraterone synergistically inhibited the resistant 22Rv1 cell function. In vivo experiments also revealed that combination therapy significantly inhibited tumour growth and reduced inducible expression of PPP1CA. PPP1CA is a key driver for abiraterone resistance, and nodularin-R enhances the anti-CRPC effects of abiraterone by inhibiting PPP1CA.

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来源期刊
CiteScore
10.00
自引率
1.90%
发文量
496
审稿时长
28 weeks
期刊介绍: Bridging physiology and cellular medicine, and molecular biology and molecular therapeutics, Journal of Cellular and Molecular Medicine publishes basic research that furthers our understanding of the cellular and molecular mechanisms of disease and translational studies that convert this knowledge into therapeutic approaches.
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