比较转录组学揭示了玉米改良过程中的可变剪接变化和选择特征。

Comparative transcriptomics uncovers alternative splicing changes and signatures of selection from maize improvement.

作者信息

Huang Jun, Gao Youjun, Jia Haitao, Liu Lei, Zhang Dan, Zhang Zuxin

机构信息

National Key Laboratory of Crop Genetic Improvement, Huazhong Agricultural University, Wuhan, 430070, China.

Hubei Collaborative Innovation Center for Grain Crops, Jingzhou, 434025, China.

出版信息

BMC Genomics. 2015 May 8;16(1):363. doi: 10.1186/s12864-015-1582-5.

DOI:10.1186/s12864-015-1582-5

PMID:25952680

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4433066/

Abstract

BACKGROUND

Alternative splicing (AS) is an important regulatory mechanism that greatly contributes to eukaryotic transcriptome diversity. A substantial amount of evidence has demonstrated that AS complexity is relevant to eukaryotic evolution, development, adaptation, and complexity. In this study, six teosinte and ten maize transcriptomes were sequenced to analyze AS changes and signatures of selection in maize domestication and improvement.

RESULTS

In maize and teosinte, 13,593 highly conserved genes, including 12,030 multiexonic genes, were detected. By identifying AS isoforms from mutliexonic genes, we found that AS types were not significantly different between maize and teosinte. In addition, the two main AS types (intron retention and alternative acceptor) contributed to more than 60% of the AS events in the two species, but the average unique AS events per each alternatively spliced gene in maize (4.12) was higher than that in teosinte (2.26). Moreover, 94 genes generating 98 retained introns with transposable element (TE) sequences were detected in maize, which is far more than 9 retained introns with TEs detected in teosinte. This indicates that TE insertion might be an important mechanism for intron retention in maize. Additionally, the AS levels of 3864 genes were significantly different between maize and teosinte. Of these, 151 AS level-altered genes that are involved in transcriptional regulation and in stress responses are located in regions that have been targets of selection during maize improvement. These genes were inferred to be putatively improved genes.

CONCLUSIONS

We suggest that both maize and teosinte share similar AS mechanisms, but more genes have increased AS complexity during domestication from teosinte to maize. Importantly, a subset of AS level-increased genes that encode transcription factors and stress-responsive proteins may have been selected during maize improvement.

摘要

背景

可变剪接（AS）是一种重要的调控机制，对真核生物转录组的多样性有很大贡献。大量证据表明，AS的复杂性与真核生物的进化、发育、适应性和复杂性相关。在本研究中，对六个大刍草和十个玉米转录组进行了测序，以分析玉米驯化和改良过程中的AS变化及选择特征。

结果

在玉米和大刍草中，检测到13593个高度保守的基因，其中包括12030个多外显子基因。通过从多外显子基因中鉴定AS异构体，我们发现玉米和大刍草之间的AS类型没有显著差异。此外，两种主要的AS类型（内含子保留和可变受体）在这两个物种的AS事件中占比超过60%，但玉米中每个可变剪接基因的平均独特AS事件数（4.12）高于大刍草（2.26）。此外，在玉米中检测到94个基因产生了98个带有转座元件（TE）序列的保留内含子，这远远多于在大刍草中检测到的9个带有TE的保留内含子。这表明TE插入可能是玉米中内含子保留的重要机制。此外，玉米和大刍草之间3864个基因的AS水平存在显著差异。其中，151个AS水平改变的基因参与转录调控和应激反应，它们位于玉米改良过程中的选择靶点区域。这些基因被推断为可能经过改良的基因。

结论

我们认为玉米和大刍草具有相似的AS机制，但从大刍草驯化到玉米的过程中，更多基因的AS复杂性增加。重要的是，在玉米改良过程中，可能选择了一部分AS水平增加且编码转录因子和应激反应蛋白的基因。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9373/4433066/7ebc342ec51e/12864_2015_1582_Fig1_HTML.jpg

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比较转录组学揭示了玉米改良过程中的可变剪接变化和选择特征。

Comparative transcriptomics uncovers alternative splicing changes and signatures of selection from maize improvement.

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出版信息

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