全球 RNA 测序显示，基因型依赖的等位基因特异性表达导致水稻 F1 杂种的差异表达。

Global RNA sequencing reveals that genotype-dependent allele-specific expression contributes to differential expression in rice F1 hybrids.

机构信息

State Key Laboratory of Hybrid Rice and College of Life Sciences, Wuhan University, Luojia Hill, Wuhan, Hubei Province 430072, China.

出版信息

BMC Plant Biol. 2013 Dec 21;13:221. doi: 10.1186/1471-2229-13-221.

DOI:10.1186/1471-2229-13-221

PMID:24358981

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3878109/

Abstract

BACKGROUND

Extensive studies on heterosis in plants using transcriptome analysis have identified differentially expressed genes (DEGs) in F1 hybrids. However, it is not clear why yield in heterozygotes is superior to that of the homozygous parents or how DEGs are produced. Global allele-specific expression analysis in hybrid rice has the potential to answer these questions.

RESULTS

We report a genome-wide allele-specific expression analysis using RNA-sequencing technology of 3,637-3,824 genes from three rice F1 hybrids. Of the expressed genes, 3.7% exhibited an unexpected type of monoallelic expression and 23.8% showed preferential allelic expression that was genotype-dependent in reciprocal crosses. Those genes exhibiting allele-specific expression comprised 42.4% of the genes differentially expressed between F1 hybrids and their parents. Allele-specific expression accounted for 79.8% of the genes displaying more than a 10-fold expression level difference between an F1 and its parents, and almost all (97.3%) of the genes expressed in F1, but non-expressed in one parent. Significant allelic complementary effects were detected in the F1 hybrids of rice.

CONCLUSIONS

Analysis of the allelic expression profiles of genes at the critical stage for highest biomass production from the leaves of three different rice F1 hybrids identified genotype-dependent allele-specific expression genes. A cis-regulatory mechanism was identified that contributes to allele-specific expression, leading to differential gene expression and allelic complementary effects in F1 hybrids.

摘要

背景

利用转录组分析对植物杂种优势进行了广泛研究，鉴定了 F1 杂种中差异表达的基因（DEGs）。然而，杂种中产量为何优于纯合亲本，以及 DEGs 是如何产生的，这些问题尚不清楚。杂种水稻的全基因组等位基因特异性表达分析有可能回答这些问题。

结果

我们使用 RNA-seq 技术对来自三个水稻 F1 杂种的 3637-3824 个基因进行了全基因组等位基因特异性表达分析。在表达的基因中，有 3.7%表现出出乎意料的单等位基因表达类型，23.8%表现出依赖于正反交基因型的优先等位基因表达。表现出等位基因特异性表达的基因占 F1 杂种与其亲本之间差异表达基因的 42.4%。等位基因特异性表达解释了 F1 与其亲本之间表达水平差异超过 10 倍的基因的 79.8%，几乎所有（97.3%）在 F1 中表达但在一个亲本中不表达的基因。在水稻不同 F1 杂种中检测到显著的等位互补效应。

结论

对来自三个不同水稻 F1 杂种叶片中最高生物量产生的关键阶段的基因的等位基因表达谱进行分析，鉴定了依赖于基因型的等位基因特异性表达基因。鉴定了一个顺式调控机制，该机制有助于等位基因特异性表达，导致 F1 杂种中基因表达和等位互补效应的差异。

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全球 RNA 测序显示，基因型依赖的等位基因特异性表达导致水稻 F1 杂种的差异表达。

Global RNA sequencing reveals that genotype-dependent allele-specific expression contributes to differential expression in rice F1 hybrids.

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSIONS

背景

结果

结论

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