Jianping Wu , Xin Xiong , Dafeng Hui , Huiling Zhang , Jianling Li , Zhongbing Chang , Shuo Zhang , Yongxian Su , Xueyan Li , Deqiang Zhang , Qi Deng
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Results showed that the SAR treatment significantly inhibited microbial activities, specifically decreasing both bacterial and fungal abundances, leading to declines in C-degrading potential enzyme activities. Conversely, potential enzyme activities related to phosphorus (P) and nitrogen (N) mineralization as well as the enzyme stoichiometry for P/N ratio significantly increased under the SAR treatment. The SAR treatment showed no significant differences in microbial abundance across the three soil aggregate sizes. However, it had a more pronounced effect on potential enzyme activities in their optimal aggregate sizes, such as hydrolytic enzymes like <em>β</em>-glucosidase in macroaggregates and oxidases like phenol oxidase and peroxidase in microaggregates. Overall, C-degrading potential enzyme activities were more strongly decreased in the microaggregates than in macroaggregates, and the distribution in aggregates was significantly altered, transforming from large to small sizes under the SAR treatment, which together may boost SOC stabilization and accumulation. Additionally, our findings indicate that prolonged acid rain also caused soil nutrient limitation and imbalance, particularly for P, in subtropical forests. 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引用次数: 0
摘要
长期暴露在酸雨环境中极大地限制了土壤微生物的活动,从而影响了土壤碳(C)的储存,但人们对在一定程度上决定土壤碳稳定的土壤团聚体中微生物的反应却知之甚少。在这里,我们研究了亚热带森林中不同大小土壤团聚体(微团聚体(250 μm)、小宏观团聚体(250-2000 μm)和微团聚体(2000 μm))内的主要微生物群组成和相关潜在酶活性。通过用不同 pH 值(即 3.0、3.5、4.0 和 4.5 作为对照)的水灌溉地块,设置了四种 SAR 处理。结果表明,SAR 处理明显抑制了微生物的活动,特别是降低了细菌和真菌的数量,导致降解 C 的潜在酶活性下降。相反,在 SAR 处理下,与磷(P)和氮(N)矿化有关的潜在酶活性以及 P/N 比率的酶化学计量显著增加。在三种大小的土壤团聚体中,SAR 处理对微生物丰度的影响无明显差异。然而,它对其最佳聚集体大小的潜在酶活性有更明显的影响,如大聚集体中的β-葡萄糖苷酶等水解酶和微聚集体中的酚氧化酶和过氧化物酶等氧化酶。总体而言,微团聚体中的 C 降解潜能酶活性比大团聚体中的更强,而且在 SAR 处理下,团聚体的分布发生了显著变化,由大变小,这可能共同促进了 SOC 的稳定和积累。此外,我们的研究结果表明,长期酸雨也会造成亚热带森林土壤养分的限制和失衡,尤其是钾的限制和失衡。这项研究强调了土壤团粒大小在调节微生物对酸雨反应中的重要性,应将其纳入生态系统模型,以预测未来气候条件下的土壤生物地球化学循环。
Soil aggregate size distribution mediates microbial responses to prolonged acid deposition in a subtropical forest in south China
Extended exposure to acid rain has vastly limited soil microbial activity with the consequences for soil carbon (C) storage, but less is known about the microbial responses within soil aggregates that to some extent determine soil C stabilization. Here, we investigated the main microbial group compositions and the relevant potential enzyme activities within different soil aggregates sizes (microaggregates (<250 μm), small macroaggregates (250–2000 μm), and microaggregates (>2000 μm)) in a subtropical forest with decade-long simulated acid rain (SAR) treatments. Four SAR treatments were set by irrigating plots with water of different pH values (i.e., 3.0, 3.5, 4.0, and 4.5 as a control). Results showed that the SAR treatment significantly inhibited microbial activities, specifically decreasing both bacterial and fungal abundances, leading to declines in C-degrading potential enzyme activities. Conversely, potential enzyme activities related to phosphorus (P) and nitrogen (N) mineralization as well as the enzyme stoichiometry for P/N ratio significantly increased under the SAR treatment. The SAR treatment showed no significant differences in microbial abundance across the three soil aggregate sizes. However, it had a more pronounced effect on potential enzyme activities in their optimal aggregate sizes, such as hydrolytic enzymes like β-glucosidase in macroaggregates and oxidases like phenol oxidase and peroxidase in microaggregates. Overall, C-degrading potential enzyme activities were more strongly decreased in the microaggregates than in macroaggregates, and the distribution in aggregates was significantly altered, transforming from large to small sizes under the SAR treatment, which together may boost SOC stabilization and accumulation. Additionally, our findings indicate that prolonged acid rain also caused soil nutrient limitation and imbalance, particularly for P, in subtropical forests. This study highlights the importance of soil aggregate size in regulating microbial responses to acid rain, which should be integrated into ecosystem models to predict soil biogeochemical cycles under future climate conditions.
期刊介绍:
Soil Biology & Biochemistry publishes original research articles of international significance focusing on biological processes in soil and their applications to soil and environmental quality. Major topics include the ecology and biochemical processes of soil organisms, their effects on the environment, and interactions with plants. The journal also welcomes state-of-the-art reviews and discussions on contemporary research in soil biology and biochemistry.
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