Differences in Cladonia rangiferina nitrogen uptake capacity between ammonium and nitrate with uptake kinetics.

Q3 Environmental Science 应用生态学报 Pub Date : 2024-07-18 DOI:10.13287/j.1001-9332.202407.016
Run-Yu Chen, Wen-Hui Hu, Xue-Yan Liu
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Abstract

Atmospheric nitrogen (N) deposition could affect the structure and function of terrestrial plants. Non-N2-fixing lichens are used to monitor atmospheric N deposition because they rely on the deposited inorganic N (i.e., ammonium and nitrate) as N sources. However, the uptake capacities of lichen on ammonium and nitrate remain unclear, which hinders the application of lichen N content to accurate bioindication of atmospheric N deposition levels. We investigated ammonium and nitrate uptake capacities of Cladonia rangiferina, which was treated with ammonium alone, nitrate alone, and ammonium and nitrate mixture solutions with different mixing ratios under light and dark conditions. The results showed that N uptake rates increased with ammonium and nitrate concentrations in solutions and generally followed the Michaelis-Menten saturation kinetics. Ammonium uptake of C. rangiferina showed higher values of affinity, and was more efficient than the nitrate uptake. Both rates and amounts of nitrate uptake decreased with increasing ratios of ammonium to nitrate in solutions, while ammonium uptake showed no substantial variations, indicating an inhibition of ammonium on nitrate uptake capability. The darkness significantly decreased the maximum uptake rate and efficiency of nitrate, but had much weaker effects on lichen ammonium uptake. These findings highlight the preference of lichen on ammonium as a key N uptake strategy. It is thus necessary to consider the main types of atmospheric inorganic N deposition when using lichens to monitor atmospheric N pollution levels and evaluate N deposition based on lichen ecophysiology.

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Cladonia rangiferina 吸收铵和硝酸盐氮的能力差异与吸收动力学。
大气中的氮沉降会影响陆生植物的结构和功能。非固氮地衣被用于监测大气氮沉降,因为它们依赖沉积的无机氮(即铵和硝酸盐)作为氮源。然而,地衣对铵盐和硝酸盐的吸收能力仍不清楚,这就阻碍了应用地衣的氮含量对大气氮沉降水平进行准确的生物指示。我们研究了地衣对铵和硝酸盐的吸收能力,在光照和黑暗条件下,分别用单独的铵、单独的硝酸盐以及不同混合比的铵和硝酸盐混合溶液处理地衣。结果表明,氮吸收率随溶液中铵和硝酸盐浓度的增加而增加,一般遵循 Michaelis-Menten 饱和动力学。C. rangiferina 吸收铵的亲和力值较高,比吸收硝酸盐更有效。随着溶液中铵和硝酸盐比例的增加,硝酸盐的吸收率和吸收量都有所下降,而铵盐的吸收量则没有明显变化,这表明铵盐对硝酸盐的吸收能力有抑制作用。黑暗会明显降低地衣对硝酸盐的最大吸收率和效率,但对地衣铵吸收的影响要弱得多。这些发现凸显了地衣对氨的偏好,将其作为一种关键的氮吸收策略。因此,在利用地衣监测大气氮污染水平和根据地衣生态生理学评估氮沉积时,有必要考虑大气无机氮沉积的主要类型。
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来源期刊
应用生态学报
应用生态学报 Environmental Science-Ecology
CiteScore
2.50
自引率
0.00%
发文量
11393
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