Min Haowei, Chen Chengxuan, Wei Shaowei, Shang Xiaoling, Sun Meiyun, Xia Ran, Liu Xiangguo, Hao Dongyun, Chen Huabang, Xie Qi
State Key Laboratory of Plant Genomics and National Center for Plant Gene Research, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences Beijing, China.
Argo-Biotechnology Research Institute, Jilin Academy of Agricultural Sciences Changchun, China.
Front Plant Sci. 2016 Jul 26;7:1080. doi: 10.3389/fpls.2016.01080. eCollection 2016.
Zea mays is an important crop that is sensitive to drought stress, but survival rates and growth status remain strong in some drought-tolerant lines under stress conditions. Under drought conditions, many biological processes, such as photosynthesis, carbohydrate metabolism and energy metabolism, are suppressed, while little is known about how the transcripts of genes respond to drought stress in the genome-wide rang in the seedling stage. In our study, the transcriptome profiles of two maize recombination inbred lines (drought-tolerant RIL70 and drought-sensitive RIL93) were analyzed at different drought stages to elucidate the dynamic mechanisms underlying drought tolerance in maize seedlings during drought conditions. Different numbers of differentially expressed genes presented in the different stages of drought stress in the two RILs, for the numbers of RIL93 vs. RIL70 were: 9 vs. 358, 477 vs. 103, and 5207 vs. 152 respectively in DT1, DT2, and DT5. Gene Ontology enrichment analysis revealed that in the initial drought-stressed stage, the primary differentially expressed genes involved in cell wall biosynthesis and transmembrane transport biological processes were overrepresented in RIL70 compared to RIL93. On the contrary, differentially expressed genes profiles presented at 2 and 5 day-treatments, the primary differentially expressed genes involved in response to stress, protein folding, oxidation-reduction, photosynthesis and carbohydrate metabolism, were overrepresented in RIL93 compared to RIL70. In addition, the transcription of genes encoding key members of the cell cycle and cell division processes were blocked, but ABA- and programmed cell death-related processes responded positively in RIL93. In contrast, the expression of cell cycle genes, ABA- and programmed cell death-related genes was relatively stable in RIL70. The results we obtained supported the working hypothesis that signaling events associated with turgor homeostasis, as established by cell wall biosynthesis regulation- and aquaporin-related genes, responded early in RIL70, which led to more efficient detoxification signaling (response to stress, protein folding, oxidation-reduction) during drought stress. This energy saving response at the early stages of drought should facilitate more cell activity under stress conditions and result in drought tolerance in RIL70.
玉米是一种对干旱胁迫敏感的重要作物,但在胁迫条件下,一些耐旱品系的存活率和生长状况依然良好。在干旱条件下,许多生物学过程,如光合作用、碳水化合物代谢和能量代谢都会受到抑制,然而在全基因组范围内,关于基因转录本在玉米苗期如何响应干旱胁迫却知之甚少。在我们的研究中,分析了两个玉米重组自交系(耐旱RIL70和干旱敏感RIL93)在不同干旱阶段的转录组图谱,以阐明干旱条件下玉米幼苗耐旱性的动态机制。在两个RILs的不同干旱胁迫阶段呈现出不同数量的差异表达基因,RIL93与RIL70的数量在DT1、DT2和DT5中分别为:9对358、477对103和5207对152。基因本体富集分析表明,在初始干旱胁迫阶段,与细胞壁生物合成和跨膜运输生物学过程相关的主要差异表达基因在RIL70中比RIL93中更为富集。相反,在处理2天和5天时呈现的差异表达基因图谱中,与胁迫响应、蛋白质折叠、氧化还原、光合作用和碳水化合物代谢相关的主要差异表达基因在RIL93中比RIL70中更为富集。此外,编码细胞周期和细胞分裂过程关键成员的基因转录被阻断,但ABA和程序性细胞死亡相关过程在RIL93中呈阳性反应。相比之下,细胞周期基因、ABA和程序性细胞死亡相关基因的表达在RIL70中相对稳定。我们获得的结果支持了这样一个工作假设,即与膨压稳态相关的信号事件,如由细胞壁生物合成调控和水通道蛋白相关基因所建立的,在RIL70中早期响应,这导致在干旱胁迫期间更有效的解毒信号(对胁迫的响应、蛋白质折叠、氧化还原)。干旱早期的这种节能反应应有助于在胁迫条件下更多的细胞活动,并导致RIL70具有耐旱性。
