全质体转录组揭示了蝴蝶兰亚种台湾蝴蝶兰丰富的RNA编辑位点和差异编辑状态。

Whole plastid transcriptomes reveal abundant RNA editing sites and differential editing status in Phalaenopsis aphrodite subsp. formosana.

作者信息

Chen Ting-Chieh, Liu Yu-Chang, Wang Xuewen, Wu Chi-Hsuan, Huang Chih-Hao, Chang Ching-Chun

机构信息

Institute of Biotechnology, National Cheng Kung University, Tainan, 701, Taiwan.

Department of Biotechnology and Bioindustry Sciences, National Cheng Kung University, Tainan, 701, Taiwan.

出版信息

Bot Stud. 2017 Sep 16;58(1):38. doi: 10.1186/s40529-017-0193-7.

DOI:10.1186/s40529-017-0193-7

PMID:28916985

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5602750/

Abstract

BACKGROUND

RNA editing is a process of post-transcriptional level of gene regulation by nucleotide modification. Previously, the chloroplast DNA of Taiwan endemic moth orchid, P. aphrodite subsp. formosana was determined, and 44 RNA editing sites were identified from 24 plastid protein-coding transcripts of leaf tissue via RT-PCR and then conventional Sanger sequencing. However, the RNA editing status of whole-plastid transcripts in leaf and other distinct tissue types in moth orchids has not been addressed. To sensitively and extensively examine the plastid RNA editing status of moth orchid, RNA-Seq was used to investigate the editing status of whole-plastid transcripts from leaf and floral tissues by mapping the sequence reads to the corresponding cpDNA template. With the threshold of at least 5% C-to-U or U-to-C conversion events observed in sequence reads considered as RNA editing sites.

RESULTS

In total, 137 edits with 126 C-to-U and 11 U-to-C conversions, including 93 newly discovered edits, were identified in plastid transcripts, representing an average of 0.09% of the nucleotides examined in moth orchid. Overall, 110 and 106 edits were present in leaf and floral tissues, respectively, with 79 edits in common. As well, 79 edits were involved in protein-coding transcripts, and the 58 nucleotide conversions caused the non-synonymous substitution. At least 32 edits showed significant (≧20%) differential editing between leaf and floral tissues. Finally, RNA editing in trnM is required for the formation of a standard clover-leaf structure.

CONCLUSIONS

We identified 137 edits in plastid transcripts of moth orchid, the highest number reported so far in monocots. The consequence of RNA editing in protein-coding transcripts mainly cause the amino acid change and tend to increase the hydrophobicity as well as conservation among plant phylogeny. RNA editing occurred in non-protein-coding transcripts such as tRNA, introns and untranslated regulatory regions could affect the formation and stability of secondary structure, which might play an important role in the regulation of gene expression. Furthermore, some unidentified tissue-specific factors might be required for regulating RNA editing in moth orchid.

摘要

背景

RNA编辑是一种通过核苷酸修饰进行转录后水平基因调控的过程。此前，已测定了台湾特有蝴蝶兰（P. aphrodite subsp. formosana）的叶绿体DNA，并通过逆转录聚合酶链式反应（RT-PCR）以及传统的桑格测序法，从叶片组织的24个质体蛋白编码转录本中鉴定出44个RNA编辑位点。然而，蝴蝶兰叶片及其他不同组织类型中全质体转录本的RNA编辑状态尚未得到研究。为了灵敏且广泛地检测蝴蝶兰的质体RNA编辑状态，我们使用RNA测序（RNA-Seq）技术，通过将序列读数映射到相应的叶绿体DNA模板上，来研究叶片和花组织中全质体转录本的编辑状态。将序列读数中至少5%的C到U或U到C转换事件的阈值视为RNA编辑位点。

结果

总共在质体转录本中鉴定出137个编辑，其中包括126个C到U和11个U到C的转换，包括93个新发现的编辑，占蝴蝶兰中检测核苷酸的平均0.09%。总体而言，叶片和花组织中分别存在110个和106个编辑，其中79个编辑是共有的。此外，79个编辑涉及蛋白质编码转录本，58个核苷酸转换导致非同义替换。至少32个编辑在叶片和花组织之间显示出显著（≧20%）的差异编辑。最后，trnM中的RNA编辑是形成标准三叶草结构所必需的。

结论

我们在蝴蝶兰的质体转录本中鉴定出137个编辑，这是迄今为止单子叶植物中报道的最高数量。蛋白质编码转录本中的RNA编辑结果主要导致氨基酸变化，并倾向于增加植物系统发育中的疏水性以及保守性。在非蛋白质编码转录本（如tRNA、内含子和非翻译调控区）中发生的RNA编辑可能会影响二级结构的形成和稳定性，这可能在基因表达调控中起重要作用。此外，可能需要一些未鉴定的组织特异性因子来调节蝴蝶兰中的RNA编辑。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6172/5602750/f3fd58b9ed4b/40529_2017_193_Fig1_HTML.jpg

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全质体转录组揭示了蝴蝶兰亚种台湾蝴蝶兰丰富的RNA编辑位点和差异编辑状态。

Whole plastid transcriptomes reveal abundant RNA editing sites and differential editing status in Phalaenopsis aphrodite subsp. formosana.

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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