水淹胁迫对狗牙根光合、生长及营养元素含量的影响

doi:10.11686/cyxb2015472

摘要/Abstract

摘要： 以狗牙根当年生扦插苗为试验材料,采用盆栽控制实验,设置对照组(CK)、表土水淹组(SF)和全淹组(TF),研究水淹对狗牙根光合、生长、生物量和营养元素含量的影响。结果显示,1)与CK相比,SF组的狗牙根净光合速率、气孔导度、蒸腾速率和气孔限制值均显著降低,胞间CO₂浓度显著增加,但水分利用效率与CK组差异不显著。2)SF组分枝数、叶片数、根生物量、叶生物量和根冠比均显著低于CK组,而株高、基径、茎生物量和总生物量与CK组差异不显著;TF组除根冠比与CK组无显著差异外,株高、基径、分枝数、叶片数、根生物量、茎生物量和总生物量均显著低于CK组。3)与CK组相比,SF和TF组根的N、P、K、Fe、Mn含量均呈上升趋势,Cu含量显著降低;叶片中,SF组P、K、Cu含量显著下降,Fe、Mn含量显著升高。研究表明,水淹显著影响了狗牙根光合、生长及营养元素含量。狗牙根通过适度降低叶片P、K、Cu含量及升高Fe、Mn含量促进狗牙根叶片净光合速率的降低。然而狗牙根可通过提高对N、P、K等营养元素的吸收,促进其生长,维持较高的净光合速率,以有效应对水淹环境;其次,全淹环境中,狗牙根叶片衰老、凋落,叶片中N、P等营养元素可直接进入水体,存在增加水体富营养化的潜在风险,因此,应加强对三峡库区消落带狗牙根植被的刈割收获管理,以尽可能减少由此引起的二次污染。

Abstract: A flooding simulation experiment was conducted to detect the effects of flooding on photosynthesis, growth and nutrient concentrations of Cynodon dactylon. Two flooding-depth levels, surface flooding (SF) and total flooding (TF) were imposed, and compared with control (CK). Net photosynthetic rate (P_n), stomatal conductance (G_s), transpiration rate (T_r) and stomatal limitation (L_s) of C. dactylon under SF were significantly lower than those for the CK treatment, while the intercellular CO₂ concentration (C_i) was significantly higher. However, water use efficiency (WUE) did not differ significantly between SF and the CK treatment. Under SF, root length, root surface, root volume, branch number, leaf number, root biomass, leaf biomass and root∶shoot ratio were all significantly reduced, whereas plant height, base diameter, stem biomass and total biomass did not differ significantly between SF and CK. Under TF, root length, root surface, root volume, plant height, branch number, leaf number, root biomass, base diameter, stem biomass and total biomass were also significantly lower than those of CK. Compared to CK, root nutrient concentrations (N, P, K, Fe, and Mn) of C. dactylon under SF and TF were increased, whereas Cu content was significantly decreased. Leaf concentrations of Fe and Mn under SF were significantly increased, but the contents of P, K and Cu under SF were significantly decreased, compared to CK. Thus flooding resulted in significant reductions in photosynthesis, growth, and uptake of nutrients of C. dactylon. The reduction of leaf concentrations of P, K, and Cu and the rise in leaf concentrations of Fe, and Mn could account for the reduction in P_n. However, C. dactylon was able to improve the absorption of N, P, and K, promote stem elongation and maintain a high net photosynthetic rate to cope with flooding. Additionally, when flooded, leaf N and P could potentially be directly released into the water on leaf fall, which could increase the risk of eutrophication in waterways.

韩文娇, 白林利, 李昌晓. 水淹胁迫对狗牙根光合、生长及营养元素含量的影响[J]. 草业学报, 2016, 25(5): 49-59.

HAN Wen-Jiao, BAI Lin-Li, LI Chang-Xiao. Effects of flooding on photosynthesis, growth and nutrient content of Cynodon dactylon[J]. Acta Prataculturae Sinica, 2016, 25(5): 49-59.

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