The Effect of Re-Planting Trees on Soil Microbial Communities in a Wildfire-Induced Subalpine Grassland

Chang, Ed‐Haun; Tian, Guangming; Chiu, Chih‐Yu

doi:10.3390/f8100385

Cited by 3 publications

(3 citation statements)

References 66 publications

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“…Based on our data, and on previous studies, soil bacterial communities seem to recover faster than fungal communities [20]. After recovery, dominant species within soil microbial communities shift from fast-growing, pathogenic bacteria to beneficial, slow-growing fungal species, and pathogenic bacterial populations are eliminated [21,36]; thus, the bacterial community in NFS was similar to that in FPR (Figure 3). Furthermore, because the composition of the active functional fungal community changed from fast-growing and pathogenic fungal species to beneficial and slower-growing fungal species [21], the dominant fungal phylum in our groups shifted from Ascomycota to Basidiomycota (Figure 2).…”

Section: Changes In Soil Bacterial and Fungal Communitiessupporting

confidence: 78%

Microbial Taxa and Soil Organic Carbon Accumulation Driven by Tree Roots

Song

Liu

2018

Forests

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Rhizosphere microbes in forests are key elements for carbon accumulation in terrestrial ecosystems. To date, little is known on the rhizomicrobial community changes occurring during soil carbon accumulation. Using high-throughput DNA sequencing, we identified the phyla composing the rhizomicrobial communities of Pinus tabuliformis Carr. and Quercus variabilis Blume forests in North China and their abundance. These results were correlated with the soil organic carbon (SOC) accumulation driven by tree roots. Rhizomicrobial community composition and abundance and SOC accumulation varied with tree species, but root presence benefited SOC accumulation significantly. Different phyla played different roles in root-driven carbon accumulation during the succession of a recovery forest ecosystem, but Proteobacteria and Basidiomycota were keystones for root-driven carbon accumulation.

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Section: Changes In Soil Bacterial and Fungal Communitiessupporting

confidence: 78%

Microbial Taxa and Soil Organic Carbon Accumulation Driven by Tree Roots

Song

Liu

2018

Forests

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“…We observed significant differences in fungal biomass among the three forests. The fungal biomass is a determinant of enzyme activities in forest soil ( 32 ) and contributes to total microbial biomass ( 33 ). Increased fungal biomass could indicate faster litter composition in the soil ( 34 ), affecting fungal biomass ( 35 ).…”

Section: Discussionmentioning

confidence: 99%

Soil Fungal Community Structure and Function Shift during a Disease-Driven Forest Succession

Braima

Liu

et al. 2022

Microbiol Spectr

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“…The bacterial Shannon index of the FPR group was still lower than those of the TPR, MPR, TQR, MQR, and DPR groups (P < 0.05). After recovery of the soil microbial community, the dominant species had been shifted from fast-growing, pathogenic bacteria to beneficial, slower-growing fungal species, and the bacterial populations were eliminated (Chang et al, 2017;Hannula et al, 2017); thus, the bacterial diversity and UniFrac distances of the NFS group were similar to those of the FPR group. Compared with the bacterial community, the fungal community changed slower and more significantly (Hannula et al, 2017; FIGURE 7 | The δ 15 N values of soil and roots of control soil; middle portion of Pinus tabuliformis roots; tips of P. tabuliformis roots; middle portion of Quercus variabilis roots; tips of Q. variabilis roots; post-fire planted forest of P. tabuliformis; dead P. tabuliformis roots; and natural P. tabuliformis forest.…”

Section: Influence Of Tree Roots On Soil Microbial Diversity and Commmentioning

confidence: 99%

Microbial Community, Newly Sequestered Soil Organic Carbon, and δ15N Variations Driven by Tree Roots

et al. 2020

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Rhizosphere microbes in forests are key elements of the carbon sequestration of terrestrial ecosystems. To date, little is known about how the diversity and species interactions of the active rhizomicrobial community change during soil carbon sequestration and what interactions drive these changes. In this study, we used a combination of DNA and stable isotope method to explore correlations between the composition of microbial communities, N transformation, and the sequestration de novo of carbon in soils around Pinus tabuliformis and Quercus variabilis roots in North China. Rhizosphere soils from degraded lands, primary stage land (tree roots had colonized in degraded soil for 1 year), and nature forest were sampled for analyses. The results showed that microbial communities and newly sequestered soil organic carbon (SOC) contents changed with different tree species, environments, and successive stages. The fungal unweighted and weighted UniFrac distances could better show the different microbial species structures and differences in successive stages. Newly sequestered SOC was positively correlated with the bacterial order Rhizobiales (in P. tabuliformis forests), the fungal order Russulales (in Q. variabilis forests), and δ 15 N. Consequently, the bacterial order Rhizobiales acted as an important taxa for P. tabuliformis rootdriven carbon sequestration, and the fungal order Russulales acted as an important taxa for Q. variabilis root-driven carbon sequestration. The two plant species allocated root exudates to different portion of their root systems, which in turn altered microbial community composition and function. The δ 15 N of soil organic matter could be an important indicator to estimate root-driven carbon sequestration.

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The Effect of Re-Planting Trees on Soil Microbial Communities in a Wildfire-Induced Subalpine Grassland

Cited by 3 publications

References 66 publications

Microbial Taxa and Soil Organic Carbon Accumulation Driven by Tree Roots

Microbial Taxa and Soil Organic Carbon Accumulation Driven by Tree Roots

Soil Fungal Community Structure and Function Shift during a Disease-Driven Forest Succession

Microbial Community, Newly Sequestered Soil Organic Carbon, and δ15N Variations Driven by Tree Roots

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