Plant–Soil Feedback of Companion Species during Grassland Community Succession

The responses of dominant species to plant–soil feedback (PSF) are well established; however, the changes in the PSF of companion species remain unclear. This study aims to assess the direction and intensity of PSF, determine the main factors influencing it, and interpret the ecological significance...

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Published inForests Vol. 14; no. 8; p. 1634
Main Authors Zhang, Li, Zhang, Linhui, Huang, Lulu, Zhou, Huiling, Xue, Sha, Wang, Minggang, Xu, Hongwei
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.08.2023
Subjects
Artemisia capillaris
Artemisia giraldii
Artemisia sacrorum
Associated species
Biomass
Carbon
community succession
companion species
Dominant species
Ecological effects
Ecological succession
Environmental aspects
Experiments
Feedback
Forestry research
Fungi
Grasslands
Microorganisms
Nitrogen
Nutrient content
Phosphorus
Plant growth
plant traits
Plant-soil relationships
plant–soil feedback
Seeds
Soil erosion
soil microbial activity
Soil nutrients
Soils
Vegetation
Water conservation
Water shortages
China
Loess Plateau
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Summary:The responses of dominant species to plant–soil feedback (PSF) are well established; however, the changes in the PSF of companion species remain unclear. This study aims to assess the direction and intensity of PSF, determine the main factors influencing it, and interpret the ecological significance of PSF in companion species within the context of grassland community succession. Three typical companion species, namely Artemisia sacrorum, Artemisia capillaris, and Artemisia giraldii, were planted in soils at three grassland community succession stages (early, middle, and late) on the Loess Plateau. Our results indicate that during both plant growth periods, the shoot biomass of A. sacrorum, A. capillaris, and A. giraldii in early- and late-stage soils was higher than that in the middle-stage soil, suggesting consistent growth of the three companion species during the two growth periods. However, plant growth simultaneously led to a reduction in soil nutrient content and microbial biomass, resulting in an overall decrease in the biomass of the three species, indicating a negative PSF effect in companion species. In conclusion, the negative PSF observed in all three associated species explains the temporary dominance of companion species during succession. This study enhances our understanding of the mechanisms driving PSF in community succession.
ISSN:1999-4907
1999-4907
DOI:10.3390/f14081634