Soil particulate organic carbon regulates microbial carbon use efficiency in subtropical forests under nitrogen addition in different seasons

IF 4.8 2区 农林科学 Q1 SOIL SCIENCE
Xueqi Sun , Hao Sun , Qiufang Zhang , Biao Zhu , Hui Dai , Quanxin Zeng , Jingqi Chen , Wenwei Chen , Yuehmin Chen
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Abstract

The Industrial Revolution has driven up atmospheric nitrogen (N) deposition, therefore can alter the physiological metabolism of soil microorganisms and impact their carbon use efficiency (CUE). Microbial CUE is an indispensable regulator for soil C cycle, and even little changes can have a significant impact on the amount of C stored in soils. The intrinsic mechanism and the role of microbial CUE in response N deposition are still unknown. Here, to explore the effect of N addition on microbial CUE across different seasons, we set up a three-level (0, 40, and 80 kg N ha−1 yr−1) field N addition experiment and collected soil samples during both the growing and non-growing seasons. Soil organic C fractions and a series of other indicators were also measured. The results showed that microbial CUE is significantly lower during the growing season compared to the non-growing season, and N addition significantly increases microbial CUE in both the growing and non-growing seasons (+27 % and + 24 % respectively for low N addition and +41 % and +32 % respectively for high N addition). Similarly, nitrogen addition had a positive effect on particulate organic carbon (POC) during both seasons. Significant positive correlation between microbial CUE and POC was found. Further partial correlation analysis revealed that, after controlling for POC, the correlations between other factors and microbial CUE weakened or disappeared, while the significant positive relationship between POC and microbial CUE persisted even after controlling for other factors such as soil C or N availability and microbial activity. Jointly, this result provides empirical evidence for the close relationship between POC dynamics and microbial CUE. Considering the high C accessibility of POC, these results highlight that N addition-induced changes in soil C accessibility rather than C availability play an important role in microbial CUE in the subtropical forests. Compared with traditional models that use a fixed CUE value, the new models should incorporate the changes of microbial CUE and soil C fractions driven by N deposition to more accurately predict soil C sequestration.
不同季节氮添加条件下土壤颗粒有机碳调节亚热带森林微生物碳利用效率
工业革命加剧了大气中氮(N)的沉积,因此会改变土壤微生物的生理代谢,影响其碳利用效率(CUE)。微生物的碳利用效率是土壤碳循环不可或缺的调节因子,即使是微小的变化也会对土壤中的碳储存量产生重大影响。微生物 CUE 在响应氮沉积中的内在机制和作用尚不清楚。在此,为了探索不同季节氮添加对微生物 CUE 的影响,我们建立了一个三级(0、40 和 80 kg N ha-1 yr-1)田间氮添加实验,并在生长季和非生长季采集了土壤样本。同时还测量了土壤有机碳组分和其他一系列指标。结果表明,与非生长季相比,生长季的微生物 CUE 明显较低,而在生长季和非生长季,氮添加量都能显著提高微生物 CUE(低氮添加量分别为 +27 % 和 +24%,高氮添加量分别为 +41 % 和 +32%)。同样,在这两个季节,氮添加量对颗粒有机碳(POC)也有积极影响。微生物 CUE 与 POC 之间存在显著的正相关。进一步的偏相关分析表明,在控制了 POC 后,其他因子与微生物 CUE 之间的相关性减弱或消失,而 POC 与微生物 CUE 之间的显著正相关关系在控制了其他因子(如土壤碳或氮的可用性和微生物活性)后仍然存在。这一结果共同为 POC 动态与微生物 CUE 之间的密切关系提供了实证证据。考虑到 POC 具有较高的 C 可及性,这些结果突出表明,N 添加引起的土壤 C 可及性变化,而不是 C 可用性,在亚热带森林微生物 CUE 中发挥了重要作用。与使用固定 CUE 值的传统模型相比,新模型应结合氮沉降引起的微生物 CUE 和土壤 C 分量的变化,以更准确地预测土壤固碳。
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来源期刊
Applied Soil Ecology
Applied Soil Ecology 农林科学-土壤科学
CiteScore
9.70
自引率
4.20%
发文量
363
审稿时长
5.3 months
期刊介绍: Applied Soil Ecology addresses the role of soil organisms and their interactions in relation to: sustainability and productivity, nutrient cycling and other soil processes, the maintenance of soil functions, the impact of human activities on soil ecosystems and bio(techno)logical control of soil-inhabiting pests, diseases and weeds.
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