Embrapa Recursos Genéticos e Biotecnologia, Parque Estação Biológica, CP, Final W5 Norte, Brasília, DF-Brazil.
Universidade de Brasília, Campus Darcy Ribeiro, Brasília, DF-Brazil.
PLoS One. 2018 May 30;13(5):e0198191. doi: 10.1371/journal.pone.0198191. eCollection 2018.
Wild peanut relatives (Arachis spp.) are genetically diverse and were selected throughout evolution to a range of environments constituting, therefore, an important source of allelic diversity for abiotic stress tolerance. In particular, A. duranensis and A. stenosperma, the parents of the reference Arachis A-genome genetic map, show contrasting transpiration behavior under limited water conditions. This study aimed to build a comprehensive gene expression profile of these two wild species under dehydration stress caused by the withdrawal of hydroponic nutrient solution. For this purpose, roots of both genotypes were collected at seven time-points during the early stages of dehydration and used to construct cDNA paired-end libraries. Physiological analyses indicated initial differences in gas exchange parameters between the drought-tolerant genotype of A. duranensis and the drought-sensitive genotype of A. stenosperma. High-quality Illumina reads were mapped against the A. duranensis reference genome and resulted in the identification of 1,235 and 799 Differentially Expressed Genes (DEGs) that responded to the stress treatment in roots of A. duranensis and A. stenosperma, respectively. Further analysis, including functional annotation and identification of biological pathways represented by these DEGs confirmed the distinct gene expression behavior of the two contrasting Arachis species genotypes under dehydration stress. Some species-exclusive and common DEGs were then selected for qRT-PCR analysis, which corroborated the in silico expression profiling. These included genes coding for regulators and effectors involved in drought tolerance responses, such as activation of osmosensing molecular cascades, control of hormone and osmolyte content, and protection of macromolecules. This dataset of transcripts induced during the dehydration process in two wild Arachis genotypes constitute new tools for the understanding of the distinct gene regulation processes in these closely related species but with contrasting drought responsiveness. In addition, our findings provide insights into the nature of drought tolerance in wild germoplasm, which might be explored as novel sources of diversity and useful wild alleles to develop climate-resilient crop varieties.
野生花生近缘种(Arachis spp.)具有丰富的遗传多样性,在进化过程中适应了各种环境,因此是抗非生物胁迫的等位基因多样性的重要来源。特别是 A. duranensis 和 A. stenosperma,它们是参考 Arachis A 基因组遗传图谱的亲本,在有限水分条件下表现出相反的蒸腾行为。本研究旨在构建这两个野生种在脱除水培营养液引起的脱水胁迫下的综合基因表达谱。为此,在脱水早期的七个时间点收集了这两种基因型的根,并用于构建 cDNA 配对末端文库。生理分析表明,耐旱基因型 A. duranensis 和耐旱基因型 A. stenosperma 的气体交换参数在初始阶段存在差异。高质量的 Illumina 读数与 A. duranensis 参考基因组进行比对,分别在 A. duranensis 和 A. stenosperma 的根部鉴定到 1235 和 799 个差异表达基因(DEGs)对胁迫处理有响应。进一步的分析,包括功能注释和由这些 DEGs 代表的生物途径的鉴定,证实了这两个具有对照基因型的 Arachis 物种在脱水胁迫下的独特基因表达行为。然后选择一些物种特有的和共同的 DEGs 进行 qRT-PCR 分析,这与计算机表达谱分析结果相符。其中包括编码与干旱胁迫响应相关的调节剂和效应子的基因,如渗透感应分子级联的激活、激素和渗透溶质含量的控制以及大分子的保护。这两个野生 Arachis 基因型在脱水过程中诱导的转录本数据集为理解这两个密切相关但耐旱性不同的物种的独特基因调控过程提供了新的工具。此外,我们的研究结果为野生种质的耐旱性本质提供了新的认识,这可能作为多样性的新来源和有用的野生等位基因来开发适应气候变化的作物品种。
