Predominant effects of litter chemistry on lignin degradation in the early stage of leaf litter decomposition

Aims Lignin has long been considered a recalcitrant component of plant materials. Its degradation is critical for litter decomposition and the formation of soil organic matter. However, little is known about lignin degradation dynamics and its controlling factors during leaf litter decomposition, es...

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Bibliographic Details
Published in:Plant and soil 2019-09, Vol.442 (1/2), p.453-469
Main Authors: He, Mei, Zhao, Rudong, Tian, Qiuxiang, Huang, Lin, Wang, Xinggang, Liu, Feng
Format: Article
Language:English
Subjects:
Aldehydes
Analysis
Biomedical and Life Sciences
Carbon
Carbon content
Community composition
Control methods
Copper oxide
Cuprite
Decomposition
Degradation
Ecology
Ecosystems
Environment models
Fagus lucida
Forest ecosystems
Forests
Leaf litter
Leaves
Life Sciences
Lignin
Microbial activity
Microorganisms
Nitrogen
Organic chemistry
Organic matter
Organic soils
Oxidation
Phenols
Phosphorus
Plant communities
Plant Physiology
Plant Sciences
Plant species
REGULAR ARTICLE
Schima parviflora
Soil dynamics
Soil formation
Soil microbiology
Soil organic matter
Soil Science & Conservation
Soils
Terrestrial ecosystems
Tropical forests
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Summary:Aims Lignin has long been considered a recalcitrant component of plant materials. Its degradation is critical for litter decomposition and the formation of soil organic matter. However, little is known about lignin degradation dynamics and its controlling factors during leaf litter decomposition, especially in forest ecosystems. The objective of this study was to evaluate lignin degradation dynamics during litter decomposition and its controlling factors. Methods We conducted a lab incubation experiment for 180 days with leaves of two tree species ( Fagus lucida and Schima parviflora ) from a mid-subtropical forest in China. The CuO oxidation method was applied for lignin determination. The mass loss of bulk litter and lignin (including V-, S- and C-type phenols) and the dynamics of litter microbial community composition, carbon, nitrogen (N) and phosphorus (P) were determined during the incubation. Results Lignin degradation appeared to be a two-phase process over the incubation period, including a fast decomposition phase (early stage) followed by a relatively slow decomposition phase (late stage). Additionally, 21.9% and 18.5% of the initial lignin contents were lost from F. lucida and S. parviflora litter, respectively. The acid to aldehyde ratios of V-type phenols [(Ac/Al) V ] and S-type phenols [(Ac/Al) S ] of both litters increased with incubation. Lignin degradation was significantly affected by the litter types but not by the soil microbial communities, given that the soil microbial communities were distinctly different for the two plant communities. In the early stage, the mass loss of lignin from the F. lucida litter was faster than the S. parviflora litter: the mass loss of S-type phenols from the F. lucida litter was faster than the S. parviflora litter, whereas the dynamics of the V-type phenols were comparable for the two species. For F. lucida litter, lignin was lost faster than the bulk litter in the early stage but no difference was observed after day 133. For S. parviflora litter, the degradation of lignin and bulk litter were generally comparable over the incubation period. The mass loss of lignin in the early stage was significantly correlated with lignin, N and P contents, and the carbon/N, carbon/P and N/P ratios. Among these factors, P played a prominent role in controlling lignin degradation. Conclusions The important role of litter chemistry emphasized the importance of taking this into account in plant-soil models assessing carbo
ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-019-04207-6