Abstract
Plant species affect soil bacterial diversity and compositions. However, little is known about the role of dominant plant species in shaping the soil bacterial community during the restoration of sandy grasslands in Horqin Sandy Land, northern China. We established a mesocosm pots experiment to investigate short‐term responses of soil bacterial diversity and composition, and the related soil properties in degraded soils without vegetation (bare sand as the control, CK) to restoration with five plant species that dominate across restoration stages: Agriophyllum squarrosum (AS), Artemisia halodendron (AH), Setaria viridis (SV), Chenopodium acuminatum (CA), and Corispermum macrocarpum (CM). We used redundancy analysis (RDA) to analyze the association between soil bacterial composition and soil properties in different plant species. Our results indicated that soil bacterial diversity was significantly lower in vegetated soils independent of plant species than in the CK. Specifically, soil bacterial species richness and diversity were lower under the shrub AH and the herbaceous plants AS, SV, and CA, and soil bacterial abundance was lower under AH compared with the CK. A field investigation confirmed the same trends where soil bacteria diversity was lower under AS and AH than in bare sand. The high‐sequence annotation analysis showed that Proteobacteria, Actinobacteria, and Bacteroidetes were the most common phyla in sandy land irrespective of soil plant cover. The OTUs (operational taxonomic units) indicated that some bacterial species were specific to the host plants. Relative to bare sand (CK), soils with vegetative cover exhibited lower soil water content and temperature, and higher soil carbon and nitrogen contents. The RDA result indicated that, in addition to plant species, soil water and nitrogen contents were the most important factors shaping soil bacterial composition in semiarid sandy land. Our study from the pot and field investigations clearly demonstrated that planting dominant species in bare sand impacts bacterial diversity. In semiarid ecosystems, changes in the dominant plant species during vegetation restoration efforts can affect the soil bacterial diversity and composition through the direct effects of plants and the indirect effects of soil properties that are driven by plant species.
Highlights
Ecological restoration refers to the recovery process of degraded ecosystems to either the near pre- or preexiting state, in terms of ecosystem composition, structure, dynamics, and function (Aronson, Floret, Floc’H, Ovalle, & Pontanier, 1993; Davis & Slobodkin, 2004; Keenelyside, Dudley, Cairns, Hall, & Stolton, 2012)
Our results showed that soil properties shifted in responses to the plant species, and soil water content and nitrogen were the main factors that were significantly correlated with the soil bacterial community structure
Our findings clearly illustrated the associations among soil bacterial diversity and composition with plant species changes and plant-induced soil properties in sandy grassland ecosystem
Summary
Ecological restoration refers to the recovery process of degraded ecosystems to either the near pre- or preexiting state, in terms of ecosystem composition, structure, dynamics, and function (Aronson, Floret, Floc’H, Ovalle, & Pontanier, 1993; Davis & Slobodkin, 2004; Keenelyside, Dudley, Cairns, Hall, & Stolton, 2012). The role of microbes in soil processes is relatively well understood, the plant–microbe interactions and their associated role in enhancing plant performance have only recently started to be addressed (Jacoby et al, 2017) It is unclear how the bacterial community responds to restoration efforts in semiarid grassland ecosystems and whether certain bacteria are only associated with specific host-plant species. Such information is important to better understand the mechanistic processes associated with the plant–microbe interactions related to the establishment and performance of plants, which can be used to improve and enhance the restoration efforts and ecosystem services of degraded lands. We used Illumina high-t hroughput sequencing to assess soil bacterial community composition, determine whether specific bacterial taxa are associated with selected host plants in the short term, and identify soil factors that determine bacterial community
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