MRPL33 及其剪接调节因子 hnRNPK 对于线粒体功能是必需的，并与肿瘤进展有关。

MRPL33 and its splicing regulator hnRNPK are required for mitochondria function and implicated in tumor progression.

机构信息

Key Laboratory of Food Safety Research, Institute for Nutritional Sciences, Shanghai Institutes for Biological Sciences, Chinese Academy of Sciences, University of Chinese Academy of Sciences, Shanghai, China.

Department of Surgery, Zhongshan Hospital, Fudan University School of Medicine, Shanghai, China.

出版信息

Oncogene. 2018 Jan 4;37(1):86-94. doi: 10.1038/onc.2017.314. Epub 2017 Sep 4.

DOI:10.1038/onc.2017.314

PMID:28869607

Abstract

MRPL33 gene encodes a large mitoribosomal subunit protein, which may be involved in mitochondrial translation. Although two splice variants of MRPL33 have been described, its splicing regulation remains elusive. Here we observed that inclusion of alternative exon 3 was greatly promoted in a panel of human cancer cells. Depletion of the exon 3-containing long isoform of MRPL33 (MRPL33-L) led to impaired proliferation and increased apoptosis in cancer cell lines and in a xenograft model. MRPL33-L knockdown could also induce mitochondrial dysfunction including increased accumulation of reactive oxygen species, decreased ATP production and 16 S rRNA levels. We further showed that alternative splicing of MRPL33-L pre-mRNA is regulated by hnRNPK and that knocking down hnRNPK could phenocopy MRPL33-L depletion. More importantly, overexpression of MRPL33-L could increase tumorigenic potential of hnRNPK-depleted cancer cells, likely indicating that hnRNPK mediates tumorigenesis through splicing regulation of MRPL33 pre-mRNA. Finally, we found that inclusion of MRPL33 exon 3 was promoted in human colorectal cancer tissues and this was correlated with hnRNPK levels. In summary, our findings underscore the biological significance of MRPL33-L and hnRNPK in the tumor formation and identifies hnRNPK as a critical splicing regulator of MRPL33 pre-mRNA in cancer cells.

摘要

MRPL33 基因编码一种大型线粒体核糖体亚单位蛋白，可能参与线粒体翻译。虽然已经描述了 MRPL33 的两种剪接变体，但它的剪接调控仍不清楚。在这里，我们观察到在一组人类癌细胞中，替代外显子 3 的包含被大大促进。MRPL33 长异构体（MRPL33-L）的外显子 3 缺失导致癌细胞系和异种移植模型中的增殖受损和凋亡增加。MRPL33-L 敲低还可诱导线粒体功能障碍，包括活性氧物质积累增加、ATP 产生减少和 16S rRNA 水平降低。我们进一步表明，MRPL33-L 前体 mRNA 的选择性剪接受 hnRNPK 调控，hnRNPK 敲低可模拟 MRPL33-L 缺失。更重要的是，MRPL33-L 的过表达可以增加 hnRNPK 耗尽的癌细胞的致瘤潜力，这可能表明 hnRNPK 通过 MRPL33 前体 mRNA 的剪接调控介导肿瘤发生。最后，我们发现人类结直肠癌组织中促进了 MRPL33 外显子 3 的包含，这与 hnRNPK 水平相关。总之，我们的研究结果强调了 MRPL33-L 和 hnRNPK 在肿瘤形成中的生物学意义，并确定 hnRNPK 是癌细胞中 MRPL33 前体 mRNA 的关键剪接调控因子。

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MRPL33 及其剪接调节因子 hnRNPK 对于线粒体功能是必需的，并与肿瘤进展有关。

MRPL33 and its splicing regulator hnRNPK are required for mitochondria function and implicated in tumor progression.

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