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一项针对人类非小细胞肺癌细胞中肿瘤抑制因子p53活性调节因子的全基因组siRNA筛选,将RNA剪接机制的组成部分鉴定为抗癌治疗的靶点。

A genome-wide siRNA screen for regulators of tumor suppressor p53 activity in human non-small cell lung cancer cells identifies components of the RNA splicing machinery as targets for anticancer treatment.

作者信息

Siebring-van Olst Ellen, Blijlevens Maxime, de Menezes Renee X, van der Meulen-Muileman Ida H, Smit Egbert F, van Beusechem Victor W

机构信息

Department of Pulmonary Diseases, VU University Medical Center, Amsterdam, The Netherlands.

Department of Medical Oncology, VU University Medical Center, Amsterdam, The Netherlands.

出版信息

Mol Oncol. 2017 May;11(5):534-551. doi: 10.1002/1878-0261.12052. Epub 2017 Apr 11.

DOI:10.1002/1878-0261.12052
PMID:28296343
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5527466/
Abstract

Reinstating wild-type tumor suppressor p53 activity could be a valuable option for the treatment of cancer. To contribute to development of new treatment options for non-small cell lung cancer (NSCLC), we performed genome-wide siRNA screens for determinants of p53 activity in NSCLC cells. We identified many genes not previously known to be involved in regulating p53 activity. Silencing p53 pathway inhibitor genes was associated with loss of cell viability. The largest functional gene cluster influencing p53 activity was mRNA splicing. Prominent p53 activation was observed upon silencing of specific spliceosome components, rather than by general inhibition of the spliceosome. Ten genes were validated as inhibitors of p53 activity in multiple NSCLC cell lines: genes encoding the Ras pathway activator SOS1, the zinc finger protein TSHZ3, the mitochondrial membrane protein COX16, and the spliceosome components SNRPD3, SF3A3, SF3B1, SF3B6, XAB2, CWC22, and HNRNPL. Silencing these genes generally increased p53 levels, with distinct effects on CDKN1A expression, induction of cell cycle arrest and cell death. Silencing spliceosome components was associated with alternative splicing of MDM4 mRNA, which could contribute to activation of p53. In addition, silencing splice factors was particularly effective in killing NSCLC cells, albeit in a p53-independent manner. Interestingly, silencing SNRPD3 and SF3A3 exerted much stronger cytotoxicity to NSCLC cells than to lung fibroblasts, suggesting that these genes could represent useful therapeutic targets.

摘要

恢复野生型肿瘤抑制因子p53的活性可能是治疗癌症的一个有价值的选择。为了推动非小细胞肺癌(NSCLC)新治疗方案的开发,我们对NSCLC细胞中p53活性的决定因素进行了全基因组siRNA筛选。我们鉴定出了许多以前未知参与调节p53活性的基因。沉默p53通路抑制基因与细胞活力丧失有关。影响p53活性的最大功能基因簇是mRNA剪接。在沉默特定剪接体成分时观察到显著的p53激活,而不是通过对剪接体的普遍抑制。十个基因在多个NSCLC细胞系中被验证为p53活性的抑制剂:编码Ras通路激活剂SOS1、锌指蛋白TSHZ3、线粒体膜蛋白COX16以及剪接体成分SNRPD3、SF3A3、SF3B1、SF3B6、XAB2、CWC22和HNRNPL的基因。沉默这些基因通常会增加p53水平,对CDKN1A表达、细胞周期停滞的诱导和细胞死亡有不同影响。沉默剪接体成分与MDM4 mRNA的可变剪接有关,这可能有助于p53的激活。此外,沉默剪接因子对杀死NSCLC细胞特别有效,尽管是以p53非依赖的方式。有趣的是,沉默SNRPD3和SF3A3对NSCLC细胞的细胞毒性比对肺成纤维细胞强得多,这表明这些基因可能是有用的治疗靶点。

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本文引用的文献

1
Graded requirement for the spliceosome in cell cycle progression.细胞周期进程中剪接体的分级要求。
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2
Combined MYC and P53 defects emerge at medulloblastoma relapse and define rapidly progressive, therapeutically targetable disease.髓母细胞瘤复发时出现 MYC 和 P53 联合缺陷,并定义为快速进展、具有治疗靶点的疾病。
Cancer Cell. 2015 Jan 12;27(1):72-84. doi: 10.1016/j.ccell.2014.11.002. Epub 2014 Dec 18.
3
Rational design of small molecule inhibitors targeting the Ras GEF, SOS1.
STIL与FOXM1的相互作用在肝细胞癌发展过程中调节SF3A3转录。
Cell Div. 2025 Jan 17;20(1):1. doi: 10.1186/s13008-025-00142-4.
4
The therapeutic potential of circular RNAs.环状RNA的治疗潜力。
Nat Rev Genet. 2025 Apr;26(4):230-244. doi: 10.1038/s41576-024-00806-x. Epub 2025 Jan 9.
5
Prognostic value of a lactate metabolism gene signature in lung adenocarcinoma and its associations with immune checkpoint blockade therapy response.乳酸代谢基因特征在肺腺癌中的预后价值及其与免疫检查点阻断治疗反应的关系。
Medicine (Baltimore). 2024 Oct 4;103(40):e39371. doi: 10.1097/MD.0000000000039371.
6
Regulation of HNRNP family by post-translational modifications in cancer.癌症中翻译后修饰对异质性核糖核蛋白(HNRNP)家族的调控
Cell Death Discov. 2024 Oct 4;10(1):427. doi: 10.1038/s41420-024-02198-7.
7
Oncofetal SNRPE promotes HCC tumorigenesis by regulating the FGFR4 expression through alternative splicing.癌胚 SNRPE 通过选择性剪接调节 FGFR4 表达促进 HCC 肿瘤发生。
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8
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5
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6
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Oncogene. 2015 May 28;34(22):2943-8. doi: 10.1038/onc.2014.230. Epub 2014 Aug 4.
7
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9
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10
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