预测未来温度对马铃薯块茎化的生理和分子反应

Abigail M. Guillemette, Guillian Hernández Casanova, John P. Hamilton, Eva Pokorná, Petre I. Dobrev, Václav Motyka, Aaron M. Rashotte, Courtney P. Leisner
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摘要

马铃薯(Solanum tuberosum L.)是全球最重要的粮食作物之一,特别容易受到热胁迫的影响。然而,我们在了解块茎对热胁迫反应的相关发育机制方面仍存在巨大的知识差距。本研究利用全植物生理学、转录组学和激素分析来深入了解热胁迫对马铃薯块茎发育影响的相关机制。当植物在预测的未来温度条件下生长时,叶片和块茎组织中的脱落酸(ABA)水平显著下降,而叶片碳同化率和气孔导度未受显著影响。虽然在温度升高条件下生长的植株平均每株能长出更多块茎,但最终收获时成熟块茎的数量却明显减少(66%)。我们推测,温度升高时块茎产量减少不是因为块茎萌发减少,而是因为块茎填充受损。转录组分析发现,与对 ABA、热和辅助素生物合成过程的反应有关的基因的转录表达发生了显著变化。在高温下生长的块茎中,已知的块茎化抑制基因 SELF PRUNING 5G (StSP5G)和 CONSTANS-LIKE1 (StCOL1)的表达量有所不同。其他已知的块茎化基因还有块茎 IDENTITY OF TUBER 1 (StIT1) 和 CAB 表达 TIMING OF EXPRESSION 1 (StTOC1),它们在高温和常温下的表达模式不同,但没有差异表达。这项工作强调了与块茎化相关的潜在基因靶标和关键发育阶段,以培育更耐热的马铃薯。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physiological and Molecular Responses of Projected Future Temperatures on Potato Tuberization
Potato (Solanum tuberosum L.) is one of the most important food crops globally and is especially vulnerable to heat stress. Significant knowledge gaps remain however, in our understanding of the developmental mechanisms associated with tuber responses to heat stress. This study uses whole-plant physiology, transcriptomics, and hormone profiling to gain insights into the mechanisms associated with heat stress impacts on potato tuber development. When plants were grown in projected future temperature conditions, levels of abscisic acid (ABA) were significantly decreased in leaf and tuber tissues while rates of leaf carbon assimilation and stomatal conductance were not significantly affected. While plants grown in elevated temperature conditions initiated more tubers on average per plant, there was a significant decrease (66%) in mature tubers at final harvest. We hypothesize that reduced tuber yields at elevated temperatures are not due to reductions in tuber initiation, but due to impaired tuber filling. Transcriptomic analysis found significant changes in transcript expression for genes related to response to ABA, heat and auxin biosynthetic process. The known tuberization repressor genes SELF PRUNING 5G (StSP5G) and CONSTANS-LIKE1 (StCOL1) were found to be differentially expressed in tubers grown in elevated temperatures. IDENTITY OF TUBER 1 (StIT1) and TIMING OF CAB EXPRESSION 1 (StTOC1) are other known tuberization genes that displayed distinct expression patterns in elevated versus ambient temperatures but were not differentially expressed. This work highlights potential gene targets and key developmental stages associated with tuberization to development more heat tolerant potatoes.
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