College of Agronomy and Biotechnology, China Agricultural University, Beijing 100193, China; School of Agricultural Sciences, Jiangxi Agricultural University, Nanchang 330045, China.
College of Agronomy and Biotechnology, China Agricultural University, Beijing 100193, China.
J Plant Physiol. 2020 Aug;251:153194. doi: 10.1016/j.jplph.2020.153194. Epub 2020 May 25.
The interception of irradiation by smog pollution and cloud cover associated with extreme rainfall events has become an increasingly important limiting factor in crop production in China. Little is known about the adaptation of carbon (C) allocation to periodic low irradiance in field conditions. The trehalose signaling pathway plays a critical role in adapting C allocation to the environment in crops but its importance in adaptation to low light in field conditions is not known. To determine the effects of low irradiance on C economy and maize yield, two commonly grown hybrids (LY-16 and ZD-958) were subject to three levels of shading (15 %, 50 %, and 97 %) for one week from V13 stage in two successive seasons. Shading led to yield loss mainly due to decreased kernel number, which was greater in LY-16 than ZD-958. Effects of shading on leaf area and photosynthesis were similar in both varieties. Starch levels in leaves were maintained, whereas total soluble carbohydrates were reduced up to fivefold by shading in both varieties. Shading increased the proportion of photoassimilate retained in leaves relative to reproductive organs. Carbohydrates in ears and stem were decreased by shading similarly in both varieties. Amongst the parameters measured, the main difference between LY-16 and ZD-958 associated with yield penalty was the expression of class II trehalose phosphate synthase (TPS) and trehalose-6-phosphate phosphatase (TPP) genes which were increased due to shading in leaves and ears, particularly in ears of LY-16. It is concluded that altered C fixation and allocation by low irradiance limited ear growth at pre-anthesis. Activation of TPSII and TPP genes indicates that the trehalose pathway likely plays a role in ear development under low light and could be a target for yield improvement under such conditions as with other stresses.
烟雾污染和与极端降雨事件相关的云量对中国作物生产的辐射拦截已成为一个日益重要的限制因素。人们对在田间条件下周期性低光照下碳(C)分配的适应机制知之甚少。海藻糖信号通路在作物适应环境的 C 分配中起着至关重要的作用,但它在适应田间低光照条件下的重要性尚不清楚。为了确定低光照对 C 经济和玉米产量的影响,在两个连续季节的 V13 期后一周内,将两种常用杂交种(LY-16 和 ZD-958)分别进行 15%、50%和 97%的三种遮荫处理。遮荫导致产量损失主要是由于穗粒数减少,LY-16 中的穗粒数减少大于 ZD-958。遮荫对两种品种叶片面积和光合作用的影响相似。叶片中淀粉水平保持不变,而总可溶性碳水化合物在两种品种中遮荫时减少了五倍。遮荫增加了叶片相对于生殖器官保留的光合产物的比例。两种品种中,穗部和茎部碳水化合物均因遮荫而减少。在所测量的参数中,与产量损失相关的 LY-16 和 ZD-958 的主要区别是类 II 海藻糖磷酸合酶(TPS)和海藻糖-6-磷酸磷酸酶(TPP)基因的表达,这些基因在叶片和耳朵中因遮荫而增加,特别是在 LY-16 的耳朵中。研究结果表明,低光照下 C 固定和分配的改变限制了开花前的穗部生长。TPSII 和 TPP 基因的激活表明,在低光照下,海藻糖途径可能在耳朵发育中起作用,并可能成为在低光照条件下提高产量的目标,就像在其他胁迫下一样。
