Wang Xuan, Wang Le, Li Weimin, Li Yifan, An Yu, Wu Haitao, Guo Yue
State Key Laboratory of Black Soils Conservation and Utilization, Northeast Institute of Geography and Agroecology, Chinese Academy of Sciences, Changchun, China.
University of Chinese Academy of Sciences, Beijing, China.
Front Plant Sci. 2024 Sep 2;15:1441567. doi: 10.3389/fpls.2024.1441567. eCollection 2024.
The ecological environment of wetlands in semi-arid regions has deteriorated, and vegetation succession has accelerated due to climate warming-induced aridification and human interference. The nutrient acquisition strategies and biomass allocation patterns reflect plant growth strategies in response to environmental changes. However, the impact of nutrient acquisition strategies on biomass allocation in successional vegetation remains unclear. We investigated 87 plant communities from 13 wetland sites in the semi-arid upper Yellow River basin. These communities were divided into three successional sequences: the herbaceous community (HC), the herbaceous-shrub mixed community (HSC), and the shrub community (SC). The nutrient composition of stems and leaves, as well as the biomass distribution above and belowground, were investigated. Results revealed that aboveground biomass increased with succession while belowground biomass decreased. Specifically, SC exhibited the highest stem biomass of 1,194.53 g m, while HC had the highest belowground biomass of 2,054.37 g m. Additionally, significant positive correlations were observed between leaf and stem biomasses in both HC and SC. The nitrogen (N) and phosphorus (P) contents within aboveground parts displayed an evident upward trend along the succession sequence. The highest N and P contents were found in SC, followed by HSC, and the lowest in HC. Stem N was negatively correlated with stem, leaf, and belowground biomass but positively correlated with root-shoot ratio. Leaf P displayed positive correlations with aboveground biomass while showing negative correlations with belowground biomass and root-shoot ratio. The ratios of C:N, C:P, and N:P in stem and leaf exhibited positive correlations with belowground biomass. The random forest model further demonstrated that stem N and leaf P exerted significant effects on aboveground biomass, while leaf P, stem N and P, and leaf C:P ratio had significant effects on belowground components. Additionally, the root-shoot ratio was significantly influenced by leaf P, leaf C:P ratio, and stem N, P, and C:P ratio. Therefore, the aboveground and belowground biomasses exhibited asynchronism across successional sequences, while plant nutrient acquisition strategies, involving nutrient levels and stoichiometric ratios, determined the biomass allocation pattern. This study offers valuable insights for assessing vegetation adaptability and formulating restoration plans in the semi-arid upper Yellow River basin.
半干旱地区湿地的生态环境已经恶化,由于气候变暖导致的干旱化和人类干扰,植被演替加速。养分获取策略和生物量分配模式反映了植物应对环境变化的生长策略。然而,养分获取策略对演替植被生物量分配的影响仍不明确。我们调查了黄河上游半干旱地区13个湿地站点的87个植物群落。这些群落被分为三个演替序列:草本群落(HC)、草本 - 灌木混合群落(HSC)和灌木群落(SC)。我们研究了茎和叶的养分组成以及地上和地下生物量分布。结果表明,地上生物量随演替增加,而地下生物量减少。具体而言,SC的茎生物量最高,为1194.53 g/m,而HC的地下生物量最高,为2054.37 g/m。此外,在HC和SC中,叶生物量和茎生物量之间均存在显著正相关。地上部分的氮(N)和磷(P)含量沿演替序列呈明显上升趋势。SC中的N和P含量最高,其次是HSC,HC中最低。茎N与茎、叶和地下生物量呈负相关,但与根冠比呈正相关。叶P与地上生物量呈正相关,而与地下生物量和根冠比呈负相关。茎和叶中的C:N、C:P和N:P比值与地下生物量呈正相关。随机森林模型进一步表明,茎N和叶P对地上生物量有显著影响,而叶P、茎N和P以及叶C:P比值对地下部分有显著影响。此外,根冠比受叶P、叶C:P比值以及茎N、P和C:P比值的显著影响。因此,地上和地下生物量在演替序列中表现出不同步性,而涉及养分水平和化学计量比的植物养分获取策略决定了生物量分配模式。本研究为评估黄河上游半干旱地区植被适应性和制定恢复计划提供了有价值的见解。
