Cernusak Lucas A, Mejia-Chang Monica, Winter Klaus, Griffiths Howard
Smithsonian Tropical Research Institute, Balboa, Ancon, Republic of Panama.
Plant Cell Environ. 2008 Nov;31(11):1644-62. doi: 10.1111/j.1365-3040.2008.01868.x. Epub 2008 Sep 2.
Leaf gas exchange and leaf water (18)O enrichment (Delta(18)O(L)) were measured in three Clusia species under field conditions during dry and wet seasons and in Miconia argentea during the dry season in the Republic of Panama. During the dry season, all three Clusia species used crassulacean acid metabolism (CAM); during the wet season Clusia pratensis operated in the C(3) mode, while Clusia uvitana and Clusia rosea used CAM. Large departures from isotopic steady state were observed in daytime Delta(18)O(L) of the Clusia species, especially during the dry season. In contrast, daytime Delta(18)O(L) was near isotopic steady state in the C(3) tree M. argentea. Across the full data set, non-steady-state predictions explained 49% of variation in observed Delta(18)O(L), whereas steady-state predictions explained only 14%. During the wet season, when Delta(18)O(L) could be compared with Clusia individuals operating in both C(3) and CAM modes, steady-state and non-steady-state models gave contrasting predictions with respect to interspecific variation in daytime Delta(18)O(L). The observed Delta(18)O(L) pattern matched that predicted for the non-steady state. The results provided a clear example of how non-steady-state control of leaf water (18)O dynamics can shift the slope of the relationship between transpiration rate and daytime Delta(18)O(L) from negative to positive.
在巴拿马共和国的旱季和雨季,对三种克鲁西亚属植物以及旱季时的银叶米团花进行了野外条件下的叶片气体交换和叶片水(18)O富集(δ(18)O(L))测量。旱季时,所有三种克鲁西亚属植物都采用景天酸代谢(CAM);雨季时,草原克鲁西亚以C(3)模式运行,而乌维塔克鲁西亚和玫瑰克鲁西亚则采用CAM。在克鲁西亚属植物的白天δ(18)O(L)中观察到了与同位素稳态的较大偏差,尤其是在旱季。相比之下,C(3)树木银叶米团花的白天δ(18)O(L)接近同位素稳态。在整个数据集上,非稳态预测解释了观测到的δ(18)O(L)变化的49%,而稳态预测仅解释了14%。在雨季,当可以将δ(18)O(L)与以C(3)和CAM两种模式运行的克鲁西亚个体进行比较时,稳态和非稳态模型在白天δ(18)O(L)的种间变化方面给出了相反的预测。观测到的δ(18)O(L)模式与非稳态预测的模式相匹配。结果提供了一个明确的例子,说明叶片水(18)O动态的非稳态控制如何能使蒸腾速率与白天δ(18)O(L)之间关系的斜率从负变为正。
