Shift of Dominant Species in Plant Community and Soil Chemical Properties Shape Soil Bacterial Community Characteristics and Putative Functions: A Case Study on Topographic Variation in a Mountain Pasture

Eo, Jinu; Kim, Myung‐Hyun; Kim, Min-Kyeong; Choi, Soon-Kun

doi:10.3390/microorganisms9050961

Cited by 9 publications

(1 citation statement)

References 69 publications

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“…Our results showed that the dominant species were in the plant–bacterial networks, and most dominant plant species also were keystone species (Figure 3, Table S1). Actually, dominant plant species as locally abundant affected community structure and ecosystem function (Avolio et al, 2019), which shaped soil bacterial community (Eo et al, 2021; Wang et al, 2018). Moreover, we discovered that some species with low numbers were also identified as keystone species.…”

Section: Discussionmentioning

confidence: 99%

Soil bacterial community and ecosystem multifunctionality regulated by keystone plant species during secondary succession

Shang,

Li,

Huang

et al. 2023

Land Degrad Dev

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Plants and soil bacteria exert a vital function in mediating soil ecosystem multifunctionality (EMF). Nevertheless, plant and soil bacteria interaction during forest secondary succession is poorly understood, and their roles in soil EMF remain largely unexplored. The dynamics of soil physicochemical properties and bacterial diversity was studied in southwest China during forest succession from coniferous to monsoon broadleaf evergreen. Interdomain ecological networks (IDEN) were adopted for investigating plant–bacteria associations. With the purpose of assessing how soil factors, bacterial community and plant diversity influenced soil EMF, the structural equation model (SEM) was used. It was discovered that both soil bacterial diversity and soil EMF gradually increased with the succession. IDEN analysis revealed that plant–bacteria ecological networks differed significantly across successional stages. Keystone plant species richness (KSR) increased with succession, which benefited soil bacteria diversity (path coefficient = 0.802, p < 0.001) while having a direct negative impact on pH (path coefficient = −0.602, p < 0.05) and C:N (path coefficient = −0.759, p < 0.001). Soil pH and C:N ratio declines were observed during forest secondary succession and were found to be inversely related to soil EMF. Furthermore, soil pH was found to be inversely related to bacterial diversity. The SEM analysis explained 88.2% of the variation in soil multifunctionality. The findings suggested that keystone plant species played a key function in regulating the variations of soil bacterial community and EMF (total effect = 0.813). Our study clarified the critical functions of keystone species in driving soil bacterial diversity and multifunctionality during forest succession and provided a new perspective on the relationship between above‐ and below‐ground.

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Section: Discussionmentioning

confidence: 99%