大豆发育、胁迫及植物激素处理过程中EF1α基因的系统发育分析与差异表达

Phylogenetic analysis and differential expression of EF1α genes in soybean during development, stress and phytohormone treatments.

作者信息

Saraiva Kátia Daniella da Cruz, Oliveira Antonio Edson Rocha, Dos Santos Clesivan Pereira, Lima Karine Thiers Leitão, de Sousa Janaina Martins, Fernandes de Melo Dirce, Costa José Hélio

机构信息

Departamento de Bioquímica e Biologia Molecular, Universidade Federal do Ceará, Campus do Pici, Cx., 6033, Fortaleza, Fortaleza, CE, 60451-970, Brazil.

出版信息

Mol Genet Genomics. 2016 Aug;291(4):1505-22. doi: 10.1007/s00438-016-1198-8. Epub 2016 Mar 16.

DOI:10.1007/s00438-016-1198-8

PMID:26984342

Abstract

The EF1α is a multifunctional protein with additional unrelated activities to its primary function in translation. This protein is encoded by a multigene family and few studies are still available in plants. Expression of six EF1α genes in Glycine max was performed using RT-qPCR and RNA-seq data to advance in the function of each gene during plant development, stress conditions and phytohormone treatments. A phylogenetic classification in Phaseoleae tribe was used to identify the G. max EF1α genes (EF1α 1a1, 1a2, 1b, 2a, 2b and 3). Three EF1α types (1-3) were found in Phaseoleae revealing duplications in G. max types 1 and 2. EF1α genes were expressed in all studied tissues, however, specific amount of each transcript was detected. In plant development, all EF1α transcripts were generally more expressed in younger tissues, however, in unifoliolate leaves and cotyledons a higher expression occurred in older tissues. Five EF1α genes (except 2a) were up-regulated under stress in a response tissue/stress/cultivar-dependent. EF1α 3 was the most stress-induced gene linked to cultivar stress tolerance mainly in aerial tissues. Auxin, salicylate and ethylene induced differentially the EF1α expression. Overall, this study provides a consistent EF1α classification in Phaseoleae tribe to better understand their functional evolution. The RT-qPCR and RNA-seq EF1α expression profiles were consistent, both exhibiting expression diversification of each gene (spatio-temporal, stress and phytohormone stimuli). Our results point out the EF1α genes, especially EF1α 3, as candidate for developing a useful tool for future G. max breeding.

摘要

延伸因子1α（EF1α）是一种多功能蛋白质，除了在翻译过程中的主要功能外，还具有其他不相关的活性。该蛋白质由一个多基因家族编码，而在植物方面的相关研究仍然较少。利用逆转录定量聚合酶链反应（RT-qPCR）和RNA测序（RNA-seq）数据对大豆中六个EF1α基因进行表达分析，以深入了解每个基因在植物发育、胁迫条件和植物激素处理过程中的功能。通过对菜豆族进行系统发育分类，以鉴定大豆的EF1α基因（EF1α 1a1、1a2、1b、2a、2b和3）。在菜豆族中发现了三种EF1α类型（1-3），表明大豆的1型和2型存在重复。EF1α基因在所有研究的组织中均有表达，但检测到每个转录本的具体含量有所不同。在植物发育过程中，所有EF1α转录本通常在较幼嫩的组织中表达量更高，但在心形叶和子叶中，较老的组织中表达量更高。五个EF1α基因（除2a外）在胁迫条件下响应组织/胁迫/品种依赖性地上调表达。EF1α 3是主要在地上组织中与品种胁迫耐受性相关的受胁迫诱导最多的基因。生长素、水杨酸和乙烯对EF1α的表达有不同的诱导作用。总体而言，本研究为菜豆族提供了一致的EF1α分类，以更好地了解其功能进化。RT-qPCR和RNA-seq的EF1α表达谱一致，均显示每个基因的表达具有多样性（时空、胁迫和植物激素刺激）。我们的结果指出，EF1α基因，尤其是EF1α 3，有望成为未来大豆育种有用工具的候选基因。

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大豆发育、胁迫及植物激素处理过程中EF1α基因的系统发育分析与差异表达

Phylogenetic analysis and differential expression of EF1α genes in soybean during development, stress and phytohormone treatments.

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