[Species-dependence of the pattern of plant photosynthetic rate response to light intensity transition from saturating to limiting one].

植物生理与分子生物学学报 Pub Date : 2007-12-01
Yue Chen, Da-Quan Xu
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Abstract

By observing the photosynthetic responses of leaves to changes in light intensity and CO(2) concentration it was found that among the more than 50 plant species examined 32 species and 25 species showed respectively the V pattern and L pattern of the photosynthetic response to light intensity transition from saturating to limiting one (Figs.1 and 2 and Table 1). The pattern of photosynthetic response to light intensity transition is species-dependent but not leaf developmental stage-dependent (Fig.3). The species-dependence was not related to classification in taxonomy because the photosynthetic response might display the two different patterns (V and L) in plants of the same family, for example, rice and wheat (Gramineae), soybean and peanut (Leguminosae). It seemed to be related to the pathway of photosynthetic carbon assimilation because all of the C(4) plants examined (maize, green bristlegrass and thorny amaranth) displayed the L pattern. It might be related to light environment where the plants originated. The V pattern of photosynthetic response to light intensity transition was often observed in some plants grown in shade habitats, for example, sweet viburnum and Japan fatsia, while the L pattern was frequently observed in those plants grown in sunny habitats, for example, ginkgo and cotton. Furthermore, the ratio of electron transport rate to carboxylation rate in vivo measured at limiting light was far higher in the V pattern plants (mostly higher than 10) than in the L pattern plants (mostly lower than 5), but the ratio measured at saturating light had no significant difference between the two kinds of plants (Table 2). These results can be explained in part by that the V pattern plant species have larger light-harvesting complex (LHCII) and at saturating light the reversible dissociation of some LHCIIs from PSII reaction center complex occurs. The pattern of photosynthetic response to light intensity transition and the ratio of electron transport rate to carboxylation rate in vivo measured at limiting light can probably be used as a criterion to distinguish sun plants from shade plants. In the observation of photosynthetic response to light intensity transition the use of saturating light is very important because using non-saturating light can form an artifact, which leads to incorrect conclusion (Fig.4).

[植物光合速率对光强从饱和向限制转变的响应模式的物种依赖性]。
通过观察树叶的光合响应光强度变化和CO浓度(2)发现在超过50个植物物种分别检查了32种和25个物种显示V模式和L模式的光合响应光强度从饱和限制一个过渡(Figs.1和2和表1)。光合响应光强度转换的模式生物但不是叶子发育stage-dependent(图3)。由于在同一科植物中,如稻麦(Gramineae)、大豆(Leguminosae),其光合响应可能表现为V型和L型两种不同的模式,因此这种物种依赖性与分类学上的分类无关。这似乎与光合碳同化途径有关,因为所有的C(4)植物(玉米、绿鬃草和多刺苋菜)都表现出L模式。这可能与植物生长的光环境有关。生长在遮荫生境的部分植物对光强变化的光合响应呈V型,如甜豆荚和日本菜;生长在阳光生境的部分植物对光强变化的光合响应呈L型,如银杏和棉花。此外,在限光条件下,V型植株体内电子传递速率与羧基化速率之比远高于L型植株(多高于10)。但在饱和光下,两种植物之间的比值没有显著差异(表2)。这一结果的部分原因是V型植物具有较大的光收集复合物(LHCII),并且在饱和光下,一些LHCII与PSII反应中心复合物发生可逆解离。在限光条件下,体内光合作用对光强转换的响应模式和电子传递速率与羧基化速率的比值可以作为区分日光植物与遮荫植物的标准。在观察光合作用对光强跃迁的响应时,使用饱和光是非常重要的,因为使用非饱和光会形成伪影,从而导致错误的结论(图4)。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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