Gong Xusheng, Xu Zhiyan, Lu Wei, Tian Yuqing, Liu Yaheng, Wang Zhengxiang, Dai Can, Zhao Jinghui, Li Zhongqiang
Hubei Collaborative Innovation Center for Green Transformation of Bio-Resources, Hubei Key Laboratory of Regional Development and Environmental Response, Faculty of Resources and Environment, College of Life Sciences, Hubei University, Wuhan, China.
Front Plant Sci. 2018 Sep 21;9:1398. doi: 10.3389/fpls.2018.01398. eCollection 2018.
Ecological stoichiometry is a powerful indicator for understanding the adaptation of plants to environment. However, understanding of stoichiometric characteristics of leaf carbon (C%), nitrogen (N%), and phosphorus (P%) for aquatic macrophytes remains limited. In this study, 707 samples from 146 sites were collected to study the variations in leaf C%, N%, and P%, and tried to explore how different environmental conditions affect leaf C, N, and P stoichiometry. Results showed that the mean values of leaf C%, N%, P%, and N:P ratios were 39.95%, 2.12%, 0.14%, and 16.60% of macrophytes across the arid zone of northwestern China, respectively. And the mean values of leaf P% were lower than those from the Tibetan Plateau and eastern China, which maybe due to an adaptation strategy of the plants to the unique conditions in the arid zone in the long-term evolutionary process. The higher N:P ratios suggested that P was established as the limiting factor of the macrophytes communities in the arid zone of northwestern China. There were significant differences in leaf C%, N%, P%, and their ratios among different life forms. Our results also showed strong relationships between leaf N% and N:P ratios and longitude, leaf N%, P%, and N:P ratios and latitude, and leaf N% and P% and altitude, respectively. In addition, the results showed that pH can significantly influence leaf C%. Our results supported the temperature-plant physiology hypothesis owing to a negative relationship between leaf N% and P% of macrophytes and mean annual temperature in the arid zone of northwestern China. The different patterns of leaf stoichiometry between the arid zone of northwestern China and eastern China indicated that there were different physiological and ecological adaptability of macrophytes to environmental gradients in different climatic zones.
生态化学计量学是理解植物对环境适应性的有力指标。然而,对水生大型植物叶片碳(C%)、氮(N%)和磷(P%)的化学计量特征的了解仍然有限。在本研究中,从146个地点收集了707个样本,以研究叶片C%、N%和P%的变化,并试图探讨不同环境条件如何影响叶片碳、氮和磷的化学计量。结果表明,中国西北干旱区大型植物叶片C%、N%、P%和N:P比的平均值分别为39.95%、2.12%、0.14%和16.60%。叶片P%的平均值低于青藏高原和中国东部地区,这可能是植物在长期进化过程中对干旱区独特条件的一种适应策略。较高的N:P比表明磷是中国西北干旱区大型植物群落的限制因素。不同生活型之间叶片C%、N%、P%及其比值存在显著差异。我们的结果还表明,叶片N%和N:P比与经度、叶片N%、P%和N:P比与纬度、叶片N%和P%与海拔之间分别存在很强的关系。此外,结果表明pH值可显著影响叶片C%。由于中国西北干旱区大型植物叶片N%和P%与年平均温度呈负相关,我们的结果支持了温度-植物生理学假说。中国西北干旱区和中国东部地区叶片化学计量的不同模式表明,大型植物在不同气候区对环境梯度具有不同的生理和生态适应性。
