森林木质残体微生物群落构建机制研究进展

doi:10.11707/j.1001-7488.LYKX20220472

摘要/Abstract

摘要： 木质残体分解是森林碳循环过程中的重要环节，而微生物是影响其分解的关键因素，近年来，木质残体微生物群落构建机制已逐渐成为森林生态系统碳循环研究中的重要议题。然而当前对木质残体微生物构建的研究内容较为零散，基于此，本文进行了综述。1）微生物通过在木质残体不断定殖和竞争维持了其群落的动态平衡。木质残体微生物来源主要包括残体自身、大气以及土壤。定殖过程在分解的各个阶段均会发生，主要包括微生物进入基质后发生的竞争和资源捕获。2）土壤、木质残体特性、气候是影响木质残体微生物群落形成的3个要素，三者均会作用于微生物源和定殖过程。3）土壤环境会影响其微生物群落，也会改变与其接触的残体水分和养分等特性。木质残体特性的差异会影响资源的可得性进而影响微生物群落。随着分解进行，微生物群落形成会从初期以随机过程主导转变为确定过程为主导。气候会通过温度与湿度2种气候因子作用于土壤与木质残体，表现形式主要为大气候、小气候及全球气候变化。该领域在未来研究中需要注意的问题有：1）关注早期定殖者及不同分解阶段土壤微生物优势类群对木质残体微生物群落形成过程的影响。2）加强木质残体资源变化情况与对应微生物群落中优势物种功能特性的研究。3）将木质残体分解与全球气候变化和养分循环联系起来。4）选择靶向宏基因组联用等技术辅助进行研究。综上，本文总结了森林木质残体微生物群落形成机制研究的基本思路、框架与前景，为森林生物多样性保护、生物地球化学循环功能的维持以及森林固碳提供了一定的科学参考。

关键词: 森林生态系统, 微生物, 木质残体, 土壤, 分解, 气候变化

Abstract: The decomposition of woody debris is an important part of the forest carbon cycle, and microorganisms are the key factor influencing its decomposition rate. In recent years, the mechanisms of microbial community building in woody debris have gradually become an important topic in the study of carbon cycling in forest ecosystems. However, current microbial research on woody debris is fragmented. Hence, this paper reviews the formation mechanism of woody debris microbial communities. 1) Microorganisms maintain a dynamic balance of communities by continuously colonising woody debris. The microbial sources of woody debris mainly stem from the debris itself, the atmosphere and the soil. The colonization process occurs at all stages of decomposition and consists mainly of competition and resource capture that occurs when microorganisms colonizing the substrate. 2) Soil, properties of woody debris and climate are three important factors influencing the formation of microbial communities of woody debris, all of which act on the microbial sources and the colonisation process. 3) The soil environment affects the soil microbial community and changes the properties of the debris with which it comes into contact. Differences in woody debris properties affect the availability of resources and thus the microbial community. As decomposition proceeds, microbial community assembly changes from an initial dominance of stochastic processes to a dominance of deterministic processes. Climate affect the soil and woody debris through both temperature and humidity climate factors, mainly in the form of macroclimate, microclimate and global climate change. Finally, the paper summarised the issues that need to be addressed in future research in this area and identifies the need to: 1) focus on the impact of early colonizers and soil microorganisms at different stages of decomposition on the microbial community of woody debris; 2) strengthen the study of changes in woody debris resources and the function of the dominant species in the corresponding microbial community; 3) link woody debris decomposition to global climate change and nutrient cycling; 4) select more precise techniques for the decomposition of woody debris. In summary, this paper summarised the basic ideas, framework and prospects for the study of microbial community formation mechanisms in forest woody residues, providing certain scientific references for forest biodiversity conservation, maintenance of biogeochemical cycle functions and forest carbon sequestration.

Key words: forest ecosystem, microflora, woody debris, soil, decomposition, climate change

中图分类号:

S718.5

赵杼祺, 胡振宏, 何鲜, 黄志群. 森林木质残体微生物群落构建机制研究进展[J]. 林业科学, 2024, 60(2): 106-117.

Zhao Zhuqi, Hu Zhenhong, He Xian, Huang Zhiqun. Research Progresses on the Dynamics of Microbial Community Establishment in Woody Debris[J]. Scientia Silvae Sinicae, 2024, 60(2): 106-117.

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