Burgess Alexandra J, Retkute Renata, Pound Michael P, Foulkes John, Preston Simon P, Jensen Oliver E, Pridmore Tony P, Murchie Erik H
Division of Plant and Crop Sciences, School of Biosciences, University of Nottingham, Sutton Bonington LE12 5RD, United Kingdom (A.J.B., R.R., M.P.P., J.F., E.H.M.);School of Mathematical Sciences, University of Nottingham, Nottingham NG7 2RD, United Kingdom (R.R., S.P.P.);School of Mathematics, University of Manchester, Manchester M13 9PL, United Kingdom (O.E.J.); and School of Computer Science, Jubilee Campus, University of Nottingham, Nottingham NG8 1BB, United Kingdom (T.P.P.).
Division of Plant and Crop Sciences, School of Biosciences, University of Nottingham, Sutton Bonington LE12 5RD, United Kingdom (A.J.B., R.R., M.P.P., J.F., E.H.M.);School of Mathematical Sciences, University of Nottingham, Nottingham NG7 2RD, United Kingdom (R.R., S.P.P.);School of Mathematics, University of Manchester, Manchester M13 9PL, United Kingdom (O.E.J.); and School of Computer Science, Jubilee Campus, University of Nottingham, Nottingham NG8 1BB, United Kingdom (T.P.P.)
Plant Physiol. 2015 Oct;169(2):1192-204. doi: 10.1104/pp.15.00722. Epub 2015 Aug 17.
Photoinhibition reduces photosynthetic productivity; however, it is difficult to quantify accurately in complex canopies partly because of a lack of high-resolution structural data on plant canopy architecture, which determines complex fluctuations of light in space and time. Here, we evaluate the effects of photoinhibition on long-term carbon gain (over 1 d) in three different wheat (Triticum aestivum) lines, which are architecturally diverse. We use a unique method for accurate digital three-dimensional reconstruction of canopies growing in the field. The reconstruction method captures unique architectural differences between lines, such as leaf angle, curvature, and leaf density, thus providing a sensitive method of evaluating the productivity of actual canopy structures that previously were difficult or impossible to obtain. We show that complex data on light distribution can be automatically obtained without conventional manual measurements. We use a mathematical model of photosynthesis parameterized by field data consisting of chlorophyll fluorescence, light response curves of carbon dioxide assimilation, and manual confirmation of canopy architecture and light attenuation. Model simulations show that photoinhibition alone can result in substantial reduction in carbon gain, but this is highly dependent on exact canopy architecture and the diurnal dynamics of photoinhibition. The use of such highly realistic canopy reconstructions also allows us to conclude that even a moderate change in leaf angle in upper layers of the wheat canopy led to a large increase in the number of leaves in a severely light-limited state.
光抑制会降低光合生产力;然而,在复杂冠层中准确量化光抑制是困难的,部分原因是缺乏关于植物冠层结构的高分辨率结构数据,而冠层结构决定了光在空间和时间上的复杂波动。在这里,我们评估了光抑制对三种结构不同的小麦(普通小麦)品系长期碳增益(超过1天)的影响。我们使用一种独特的方法对田间生长的冠层进行精确的数字三维重建。该重建方法捕捉了品系之间独特的结构差异,如叶角、曲率和叶密度,从而提供了一种评估实际冠层结构生产力的灵敏方法,而这种结构以前很难或无法获得。我们表明,无需传统的手动测量就能自动获取关于光分布的复杂数据。我们使用一个光合作用数学模型,该模型由叶绿素荧光、二氧化碳同化的光响应曲线以及冠层结构和光衰减的手动确认组成的田间数据进行参数化。模型模拟表明,仅光抑制就会导致碳增益大幅降低,但这高度依赖于确切的冠层结构和光抑制的昼夜动态。使用这种高度逼真的冠层重建还使我们能够得出结论,即使小麦冠层上层叶角的适度变化也会导致处于严重光照受限状态的叶片数量大幅增加。
