Graduate School of Nanobioscience, Yokohama City University, 22-2 Seto, Kanazawa-ku, Yokohama, Kanagawa 236-0027, Japan.
Kihara Institute for Biological Research, Yokohama City University, 641-12 Maioka-cho, Totsuka-ku, Yokohama, Kanagawa 244-0813, Japan.
Gigascience. 2018 Apr 1;7(4). doi: 10.1093/gigascience/giy020.
Allopolyploid plants often show wider environmental tolerances than their ancestors; this is expected to be due to the merger of multiple distinct genomes with a fixed heterozygosity. The complex homoeologous gene expression could have been evolutionarily advantageous for the adaptation of allopolyploid plants. Despite multiple previous studies reporting homoeolog-specific gene expression in allopolyploid species, there are no clear examples of homoeolog-specific function in acclimation to a long-term stress condition.
We found that the allopolyploid grass Brachypodium hybridum and its ancestor Brachypodium stacei show long-term heat stress tolerance, unlike its other ancestor, Brachypodium distachyon. To understand the physiological traits of B. hybridum, we compared the transcriptome of the 3 Brachypodium species grown under normal and heat stress conditions. We found that the expression patterns of approximately 26% and approximately 38% of the homoeolog groups in B. hybridum changed toward nonadditive expression and nonancestral expression, respectively, under normal condition. Moreover, we found that B. distachyon showed similar expression patterns between normal and heat stress conditions, whereas B. hybridum and B. stacei significantly altered their transcriptome in response to heat after 3 days of stress exposure, and homoeologs that were inherited from B. stacei may have contributed to the transcriptional stress response to heat in B. hybridum. After 15 days of heat exposure, B. hybridum and B. stacei maintained transcriptional states similar to those under normal conditions. These results suggest that an earlier response to heat that was specific to homoeologs originating from B. stacei contributed to cellular homeostasis under long-term heat stress in B. hybridum.
Our results provide insights into different regulatory events of the homoeo-transcriptome that are associated with stress acclimation in allopolyploid plants.
异源多倍体植物通常比其祖先表现出更广泛的环境耐受性;这预计是由于多个不同基因组与固定杂合性的融合。复杂的同源基因表达可能在异源多倍体植物的适应中具有进化优势。尽管之前有多项研究报告了异源多倍体物种中同源基因的特异性表达,但在适应长期胁迫条件方面,同源基因特异性功能的明确例子并不多。
我们发现,异源多倍体草 Brachypodium hybridum 及其祖先 Brachypodium stacei 表现出长期耐热性,而不像其另一个祖先 Brachypodium distachyon。为了了解 B. hybridum 的生理特征,我们比较了在正常和热胁迫条件下生长的 3 种 Brachypodium 物种的转录组。我们发现,在正常条件下,B. hybridum 中大约 26%和大约 38%的同源基因组的表达模式分别向非加性表达和非祖先表达转变。此外,我们发现 B. distachyon 在正常和热胁迫条件下表现出相似的表达模式,而 B. hybridum 和 B. stacei 在受到 3 天的胁迫后,显著改变了它们对热的转录组反应,并且可能来自 B. stacei 的同源基因对 B. hybridum 对热的转录应激反应做出了贡献。在 15 天的热暴露后,B. hybridum 和 B. stacei 保持与正常条件下相似的转录状态。这些结果表明,来自 B. stacei 的同源基因的特定早期对热的反应有助于 B. hybridum 在长期热胁迫下的细胞内稳态。
我们的结果提供了有关与异源多倍体植物胁迫适应相关的同源转录组不同调控事件的见解。
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