Sheshshayee M S, Bindumadhava H, Ramesh R, Prasad T G, Lakshminarayana M R, Udayakumar M
Department of Crop Physiology, University of Agricultural Sciences, GKVK Campus, Bangalore 560065, India.
J Exp Bot. 2005 Dec;56(422):3033-9. doi: 10.1093/jxb/eri300. Epub 2005 Nov 1.
Experimental evidence is presented to show that the 18O enrichment in the leaf biomass and the mean (time-averaged) transpiration rate are positively correlated in groundnut and rice genotypes. The relationship between oxygen isotope enrichment and stomatal conductance (g(s)) was determined by altering g(s) through ABA and subsequently using contrasting genotypes of cowpea and groundnut. The Peclet model for the 18O enrichment of leaf water relative to the source water is able to predict the mean observed values well, while it cannot reproduce the full range of measured isotopic values. Further, it fails to explain the observed positive correlation between transpiration rate and 18O enrichment in leaf biomass. Transpiration rate is influenced by the prevailing environmental conditions besides the intrinsic genetic variability. As all the genotypes of both species experienced similar environmental conditions, the differences in transpiration rate could mostly be dependent on intrinsic g(s). Therefore, it appears that the delta18O of leaf biomass can be used as an effective surrogate for mean transpiration rate. Further, at a given vapour pressure difference, delta18O can serve as a measure of stomatal conductance as well.
实验证据表明,花生和水稻基因型中叶片生物量的18O富集与平均(时间平均)蒸腾速率呈正相关。通过脱落酸改变气孔导度(g(s)),随后使用豇豆和花生的不同基因型,确定了氧同位素富集与气孔导度(g(s))之间的关系。相对于源水的叶片水分18O富集的佩克莱特模型能够很好地预测平均观测值,但它无法再现测量的同位素值的整个范围。此外,它无法解释蒸腾速率与叶片生物量中18O富集之间观察到的正相关关系。蒸腾速率除了受内在遗传变异性影响外,还受当时环境条件的影响。由于两个物种的所有基因型都经历了相似的环境条件,蒸腾速率的差异可能主要取决于内在的气孔导度。因此,看来叶片生物量的δ18O可以用作平均蒸腾速率的有效替代指标。此外,在给定的蒸汽压差下,δ18O也可以用作气孔导度的度量指标。