Resolving the Intricate Effects of Multiple Global Change Drivers on Root Litter Decomposition

IF 10.8 1区 环境科学与生态学 Q1 BIODIVERSITY CONSERVATION Global Change Biology Pub Date : 2024-10-28 DOI:10.1111/gcb.17547
Qingzhou Zhao, Grégoire T. Freschet, Tingting Tao, Gabriel Reuben Smith, Peng Wang, Lingyan Hu, Miaojun Ma, David Johnson, Thomas W. Crowther, Shuijin Hu
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Abstract

Plant roots represent about a quarter of global plant biomass and constitute a primary source of soil organic carbon (C). Yet, considerable uncertainty persists regarding root litter decomposition and their responses to global change factors (GCFs). Much of this uncertainty stems from a limited understanding of the multifactorial effects of GCFs and it remains unclear how these effects are mediated by litter quality, soil conditions and microbial functionality. Using complementary field decomposition and laboratory incubation approaches, we assessed the relative controls of GCF-mediated changes in root litter traits and soil and microbial properties on fine-root decomposition under warming, nitrogen (N) enrichment, and precipitation alteration. We found that warming and N enrichment accelerated fine-root decomposition by over 10%, and their combination showed an additive effect, while precipitation reduction suppressed decomposition overall by 12%, with the suppressive effect being most significant under warming-alone and N enrichment-alone conditions. Significantly, changes in litter quality played a dominant role and accelerated fine-root decomposition by 15% ~ 18% under warming and N enrichment, while changes in soil and microbial properties were predominant and reduced decomposition by 7% ~ 10% under precipitation reduction and the combined warming and N enrichment. Examining only the decomposition environment or litter properties in isolation can distort global change effects on root decomposition, underestimating precipitation reduction impacts by 38% and overstating warming and N effects by up to 73%. These findings highlight that the net impact of GCFs on root litter decomposition hinges on the interplay between GCF-modulated root decomposability and decomposition environment, as well as on the synergistic or antagonistic relationships among GCFs themselves. Our study emphasizes that integrating the legacy effects of multiple GCFs on root traits, soil conditions and microbial functionality would improve our prediction of C and nutrient cycling under interactive global change scenarios.

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解决多种全球变化驱动因素对根系腐烂分解的复杂影响。
植物根系约占全球植物生物量的四分之一,是土壤有机碳(C)的主要来源。然而,关于根系废弃物的分解及其对全球变化因子(GCFs)的响应,仍然存在相当大的不确定性。这种不确定性在很大程度上源于人们对 GCFs 的多因素影响的了解有限,而且目前仍不清楚这些影响是如何通过枯落物质量、土壤条件和微生物功能性来调节的。利用互补的野外分解和实验室培养方法,我们评估了在气候变暖、氮(N)富集和降水改变的条件下,由 GCF 介导的根系枯落物特征变化以及土壤和微生物特性对细根分解的相对控制。我们发现,气候变暖和氮素富集会加速细根分解 10%以上,两者结合会产生叠加效应,而降水减少会抑制总体分解 12%,其中单独气候变暖和单独氮素富集条件下的抑制效应最为显著。值得注意的是,在增温和富氮条件下,枯落物质量的变化起了主导作用,使细根分解加速了 15% ~ 18%;而在降水减少以及增温和富氮的综合条件下,土壤和微生物特性的变化起了主导作用,使分解减少了 7% ~ 10%。仅孤立地研究分解环境或枯落物特性会扭曲全球变化对根系分解的影响,将降水减少的影响低估了 38%,将气候变暖和氮的影响高估了 73%。这些发现突出表明,全球变化框架对枯落物根系分解的净影响取决于全球变化框架调节的根系可分解性与分解环境之间的相互作用,以及全球变化框架本身之间的协同或拮抗关系。我们的研究强调,综合多种 GCFs 对根系特征、土壤条件和微生物功能的遗留影响,将改善我们在交互式全球变化情景下对碳和养分循环的预测。
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来源期刊
Global Change Biology
Global Change Biology 环境科学-环境科学
CiteScore
21.50
自引率
5.20%
发文量
497
审稿时长
3.3 months
期刊介绍: Global Change Biology is an environmental change journal committed to shaping the future and addressing the world's most pressing challenges, including sustainability, climate change, environmental protection, food and water safety, and global health. Dedicated to fostering a profound understanding of the impacts of global change on biological systems and offering innovative solutions, the journal publishes a diverse range of content, including primary research articles, technical advances, research reviews, reports, opinions, perspectives, commentaries, and letters. Starting with the 2024 volume, Global Change Biology will transition to an online-only format, enhancing accessibility and contributing to the evolution of scholarly communication.
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