Boonman Alex, Anten Niels P R, Dueck Tom A, Jordi Wilco J R M, van der Werf Adrie, Voesenek Laurentius A C J, Pons Thijs L
Plant Ecophysiology Group, Institute of Environmental Biology, Utrecht University, Sorbonnelaan 16, 3584 CA Utrecht, The Netherlands.
Am Nat. 2006 Nov;168(5):597-607. doi: 10.1086/508633. Epub 2006 Sep 25.
Canopy photosynthesis models have predicted an optimal leaf area index (LAI; leaf area per unit surface area) and leaf nitrogen distribution at which whole-plant carbon gain per unit N is maximized. In this study we experimentally tested these models, using transgenic P(SAG12)-IPT tobacco (SAG; Nicotiana tabacum L.) plants with delayed leaf senescence and therefore a greater LAI and more uniform N distribution than the wild type (WT). In a competition experiment, the increased density of surrounding WT plants caused a greater reduction in dry mass of mature SAG target plants than in that of WT target plants, indicating negative effects of delayed leaf senescence on performance at high canopy density. Vegetative SAG plants achieved a lower calculated daily carbon gain than competing WT plants because the former retained leaves with a negative carbon gain in the shaded, lower part of the canopy. Sensitivity analyses showed that the carbon gain of SAG plants would increase if these lower leaves were shed and the N reallocated from these leaves were used to form additional leaf area at the canopy top. This strategy, which is adopted by the WT, is most advantageous because it results in the shading of competing neighbors.
冠层光合作用模型预测了一个最佳叶面积指数(LAI;单位表面积的叶面积)和叶氮分布,在该指数和分布下单位氮素的整株碳同化量达到最大化。在本研究中,我们使用了具有延迟叶片衰老特性的转基因P(SAG12)-IPT烟草(SAG;烟草)植株对这些模型进行了实验测试,因此与野生型(WT)相比,其叶面积指数更大,氮分布更均匀。在一项竞争实验中,周围野生型植株密度的增加导致成熟的SAG目标植株干质量的减少幅度大于野生型目标植株,这表明延迟叶片衰老对高冠层密度下的表现具有负面影响。营养生长阶段的SAG植株计算得出的每日碳同化量低于与之竞争的野生型植株,因为前者在冠层下部遮荫区域保留了具有负碳同化量的叶片。敏感性分析表明,如果去除这些下部叶片,并将从这些叶片重新分配的氮用于在冠层顶部形成额外的叶面积,SAG植株的碳同化量将会增加。野生型采用的这种策略是最有利的,因为它会导致对竞争邻体的遮荫。
