Quercus rubra invasion of temperate deciduous forest stands alters the structure and functions of the soil microbiome

Quercus rubra invasion of temperate deciduous forest stands alters the structure and functions of the soil microbiome

[Display omitted] •Differences in soil abiotic properties are primarily driven by soil depth.•Q. rubra decreases the soil microbiome diversity as compared to native vegetation.•Native vegetation recruits greater number of unique microbial taxa than Q. rubra.•Relative abundance of unique microbial ta...

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Bibliographic Details
Published in:Geoderma Vol. 430; p. 116328
Main Authors: Stanek, Małgorzata, Kushwaha, Priyanka, Murawska-Wlodarczyk, Kamila, Stefanowicz, Anna M., Babst-Kostecka, Alicja
Format: Journal Article
Language:English
Published: Elsevier B.V 01-02-2023
Subjects:
Northern red oak
Plant invasion
Plant-soil microbiome interactions
Soil biogeochemical properties
Soil microbiome
Unique microbial taxa
Soil microbiome
Soil biogeochemical properties
Plant invasion
Unique microbial taxa
Plant-soil microbiome interactions
Northern red oak
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Summary:[Display omitted] •Differences in soil abiotic properties are primarily driven by soil depth.•Q. rubra decreases the soil microbiome diversity as compared to native vegetation.•Native vegetation recruits greater number of unique microbial taxa than Q. rubra.•Relative abundance of unique microbial taxa is higher in Q. rubra vs native plots.•Invasion effect is stronger for fungal than bacterial/archaeal diversity. Invasive plants can modify the diversity and taxonomical structure of soil microbiomes. However, it is difficult to generalize the underlying factors as their influence often seems to depend on the complex plant-soil-microbial interactions. In this paper, we investigated how Quercus rubra impacts on the soil microbiome across two soil horizons in relation to native woodland. Five paired adjacent invaded vs native vegetation plots in a managed forest in southern Poland were investigated. Soil microbial communities were assessed along with soil enzyme activities and soil physicochemical parameters, separately for both organic and mineral horizons, as well as forest stand characteristics to explore plant-soil-microbe interactions. Although Q. rubra did not significantly affect pH, organic C, total N, available nutrients nor enzymatic activity, differences in soil abiotic properties (except C to N ratio) were primarily driven by soil depth for both vegetation types. Further, we found significant differences in soil microbiome under invasion in relation to native vegetation. Microbial richness and diversity were lower in both horizons of Q. rubra vs control plots. Moreover, Q. rubra increased relative abundance of unique amplicon sequence variants in both horizons and thereby significantly changed the structure of the core soil microbial communities, in comparison to the control plots. In addition, predicted microbial functional groups indicated a predominant soil depth effect in both vegetation plots with higher abundance of aerobic chemoheterotrophic bacteria and endophytic fungi in the organic horizon and greater abundance of methanotrophic and methylotrophic bacteria, and ectomycorrhizal fungi in the mineral horizon. Overall, our results indicate strong associations between Q. rubra invasion and changes in soil microbiome and associated functions, a finding that needs to be further investigated to predict modifications in ecosystem functioning caused by this invasive species.
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content type line 23
ISSN:0016-7061
1872-6259
DOI:10.1016/j.geoderma.2023.116328