Hu Shuang, Wang Bao-Teng, Li Taihua, Bu Su, Jin Chun-Zhi, Jin Long, Ruan Hong-Hua, Shin Kee-Sun, Jin Feng-Jie
College of Ecology and Environment, Co-Innovation Center for Sustainable Forestry in Southern China, Nanjing Forestry University, Nanjing, China.
National Positioning Observation Station of Hung-tse Lake Wetland Ecosystem in Jiangsu Province, Hongze, China.
Front Microbiol. 2025 Jul 23;16:1628355. doi: 10.3389/fmicb.2025.1628355. eCollection 2025.
Litter decomposition drives nutrient cycling in terrestrial ecosystems, yet the dynamics of phyllosphere microbial communities during this process remain poorly understood. Poplar leaf litter decomposition is particularly critical due to its widespread plantation use. While prior studies highlight the roles of microbes in decomposition, stage-specific community succession patterns and their driving factors are underexplored. We hypothesize that microbial structure and function correlate with litter nutrient dynamics. This work advances mechanistic insights into poplar litter decomposition and informs sustainable plantation management.
Poplar leaf litter was sampled periodically during a 342-day decomposition period. DNA was extracted for 16S rRNA gene (bacteria) and ITS region (fungi) high-throughput sequencing. Microbial diversity, composition, and co-occurrence networks were analyzed using QIIME2 and Gephi. Litter quality was measured via elemental analysis and spectrophotometry. Canonical Correlation Analysis (CCA) was used to assess relationships between microbial communities and environmental factors.
The microbial community structure and composition exhibited significant differences at both the class and genus levels throughout the entire decomposition process. Specifically, the dominant fungal taxa, Dothideomycetes, was partially replaced by Sordariomycetes, Tremellomycetes and Leotiomycetes as degradation progressed. Meanwhile, Actinobacteria, Alphaproteobacteria, and Gammaproteobacteria dominated the bacterial communities throughout the entire degradation period, while the abundance of Gammaproteobacteria decreased at later stage and Actinobacteria peaked at t4 stage. Co-correlation networks revealed that the bacterial community had a higher average clustering coefficient and shorter average path lengths compared to fungi, suggesting greater functional diversity and resilience against external disturbances. With the decomposition of leaf litter, the total N content increased gradually, while other nutrients (C, P, K, cellulose and hemicellulose) decreased progressively. Litter characteristics had significant effects on microbial community structure: C/N, TK and residual hemicellulose (RH) were the primary driving factors affecting fungal community structure, whereas bacterial community structure was influenced by TK, RH, residual cellulose (RC) and lignin contents.
Overall, the decomposition of poplar litter is a complex process accompanied by dynamic succession of phyllosphere microbial communities. These results provide insights into the decomposition mechanisms of poplar leaf litter and offer a scientific basis for enhancing nutrient conversion efficiency and productivity of poplar plantations.
凋落物分解驱动陆地生态系统中的养分循环,然而在此过程中叶际微生物群落的动态变化仍知之甚少。由于杨树落叶广泛用于人工造林,其分解过程尤为关键。虽然先前的研究强调了微生物在分解中的作用,但特定阶段的群落演替模式及其驱动因素仍未得到充分探索。我们假设微生物结构和功能与凋落物养分动态相关。这项工作推进了对杨树凋落物分解机制的深入理解,并为可持续人工林管理提供了依据。
在342天的分解期内定期采集杨树落叶。提取DNA用于16S rRNA基因(细菌)和ITS区域(真菌)的高通量测序。使用QIIME2和Gephi分析微生物多样性、组成和共现网络。通过元素分析和分光光度法测量凋落物质量。使用典范相关分析(CCA)评估微生物群落与环境因素之间的关系。
在整个分解过程中,微生物群落结构和组成在纲和属水平上均表现出显著差异。具体而言,随着降解的进行,优势真菌类群座囊菌纲(Dothideomycetes)部分被粪壳菌纲(Sordariomycetes)、银耳纲(Tremellomycetes)和锤舌菌纲(Leotiomycetes)取代。同时,放线菌门(Actinobacteria)、α-变形菌纲(Alphaproteobacteria)和γ-变形菌纲(Gammaproteobacteria)在整个降解期主导细菌群落,而γ-变形菌纲的丰度在后期下降,放线菌门在t4阶段达到峰值。共相关网络显示,与真菌相比,细菌群落具有更高的平均聚类系数和更短的平均路径长度,表明其功能多样性更高且对外部干扰的恢复力更强。随着落叶的分解,总氮含量逐渐增加,而其他养分(碳、磷、钾、纤维素和半纤维素)逐渐减少。凋落物特征对微生物群落结构有显著影响:碳氮比、全钾和残余半纤维素(RH)是影响真菌群落结构的主要驱动因素,而细菌群落结构受全钾、残余半纤维素、残余纤维素(RC)和木质素含量的影响。
总体而言,杨树凋落物的分解是一个复杂的过程,伴随着叶际微生物群落的动态演替。这些结果为杨树落叶的分解机制提供了见解,并为提高杨树人工林的养分转化效率和生产力提供了科学依据。
