Zhu Fu-Yuan, Chen Mo-Xian, Ye Neng-Hui, Shi Lu, Ma Kai-Long, Yang Jing-Fang, Cao Yun-Ying, Zhang Youjun, Yoshida Takuya, Fernie Alisdair R, Fan Guang-Yi, Wen Bo, Zhou Ruo, Liu Tie-Yuan, Fan Tao, Gao Bei, Zhang Di, Hao Ge-Fei, Xiao Shi, Liu Ying-Gao, Zhang Jianhua
State Key Laboratory of Crop Biology, College of Life Science, Shandong Agricultural University, Taian, Shandong, China.
School of Life Sciences and State Key Laboratory of Agrobiotechnology, The Chinese University of Hong Kong, Shatin, Hong Kong.
Plant J. 2017 Aug;91(3):518-533. doi: 10.1111/tpj.13571. Epub 2017 Jun 7.
In eukaryotes, mechanisms such as alternative splicing (AS) and alternative translation initiation (ATI) contribute to organismal protein diversity. Specifically, splicing factors play crucial roles in responses to environment and development cues; however, the underlying mechanisms are not well investigated in plants. Here, we report the parallel employment of short-read RNA sequencing, single molecule long-read sequencing and proteomic identification to unravel AS isoforms and previously unannotated proteins in response to abscisic acid (ABA) treatment. Combining the data from the two sequencing methods, approximately 83.4% of intron-containing genes were alternatively spliced. Two AS types, which are referred to as alternative first exon (AFE) and alternative last exon (ALE), were more abundant than intron retention (IR); however, by contrast to AS events detected under normal conditions, differentially expressed AS isoforms were more likely to be translated. ABA extensively affects the AS pattern, indicated by the increasing number of non-conventional splicing sites. This work also identified thousands of unannotated peptides and proteins by ATI based on mass spectrometry and a virtual peptide library deduced from both strands of coding regions within the Arabidopsis genome. The results enhance our understanding of AS and alternative translation mechanisms under normal conditions, and in response to ABA treatment.
在真核生物中,诸如可变剪接(AS)和可变翻译起始(ATI)等机制有助于生物体蛋白质的多样性。具体而言,剪接因子在对环境和发育信号的响应中发挥关键作用;然而,其潜在机制在植物中尚未得到充分研究。在此,我们报告了平行运用短读长RNA测序、单分子长读长测序和蛋白质组鉴定,以揭示脱落酸(ABA)处理后可变剪接异构体和先前未注释的蛋白质。结合两种测序方法的数据,约83.4%含内含子的基因发生了可变剪接。两种可变剪接类型,即可变第一外显子(AFE)和可变最后外显子(ALE),比内含子保留(IR)更为丰富;然而,与正常条件下检测到的可变剪接事件不同,差异表达的可变剪接异构体更有可能被翻译。ABA广泛影响可变剪接模式,这表现为非常规剪接位点数量的增加。这项工作还基于质谱和从拟南芥基因组编码区两条链推导的虚拟肽库,通过ATI鉴定出了数千种未注释的肽和蛋白质。这些结果增进了我们对正常条件下以及ABA处理后的可变剪接和可变翻译机制的理解。
