Reduced microbial stability in the active layer is associated with carbon loss under alpine permafrost degradation

Ding

et al. 2022

Land

Artificial cultivation had been applied to recover the meadow suffering from serious degradation in the Qinghai–Tibet Plateau. Studies focusing only on the changes in vegetation, soil and microbes along the meadow degradation were insufficient, and artificial cultivation as an important part of succession was always neglected. Here, the variables of vegetation, soil, and soil bacteria are surveyed in four types of alpine meadow in the protected lands of the Qinghai–Tibet Plateau: intact alpine meadow (IAM), moderate degradation alpine meadow (MDAM), extreme degradation alpine meadow (black soil beach (BSB)), and artificial alpine grassland (AAG). The results indicated that degradation and cultivation significantly changed the characteristics of the vegetation community, physicochemical features of the soil, and soil bacterial community diversity. Soil bacteria took a considerably longer time to adapt to degradation and cultivation than vegetation and soil. Compared to IAM and BSB, ADAM and AAG had more specific bacteria identified by ANOVA and LEfSe analysis, implying an unstable state. Combined with vegetation and soil variables, it was speculated that the unstable AAG was not significantly improved from the degraded meadow, and also lagged significantly compared to IAM. Correlation analysis revealed that aboveground biomass, species richness, vegetation coverage, SOC, C/N, BD, WC, and pH were significantly associated with bacterial diversity under community level. Aboveground biomass was an effective indicator for soil bacterial gene copies. Redundancy analysis demonstrated that the soil bacterial community is mainly regulated by the vegetation coverage, Gleason index, Simpson index, TN, TP, and pH under phylum and genus level. Partial mantel test analysis indicated that the physicochemical features of the soil were the most important factor correlating with the soil bacterial community along the degradation and cultivation, compared to other environmental factors.

Section: Degradation and Cultivation Significantly Changes The Biotic...supporting

confidence: 79%

Variations and Mutual Relations of Vegetation–Soil–Microbes of Alpine Meadow in the Qinghai-Tibet Plateau under Degradation and Cultivation

Ding

et al. 2022

Land

“…Equally important, we found that community assembly exhibited a distinct pattern of nonlinear responses to increasing aridity. Although the coexistence networks based on Spearman correlation may be biased for compositional data (compared with SparCC) ( 60 ), the networks can still meet the overall trend of coexistence relationships ( 61 – 63 ). Specifically, the relative influence of stochastic processes on rare taxa and deterministic processes on abundant taxa increased with increasing aridity under lower aridity stress.…”

Section: Discussionmentioning

confidence: 99%

Aridity Threshold Induces Abrupt Change of Soil Abundant and Rare Bacterial Biogeography in Dryland Ecosystems

et al. 2022

“…Microbial community stability is crucial to ensure ecosystem functioning ( Wu et al, 2021 ). Our study found that aboveground herbivores were quite capable of disturbing rhizofungal community stability.…”

Section: Discussionmentioning

confidence: 99%

“…Mounting evidence has revealed that species interactions in biological community networks are crucial for their stability ( Neutel et al, 2002 ; Coux et al, 2016 ). Likewise, the capacity of soil microbial communities to maintaining stability under disturbances largely depends on the complexity of interactions between species within that community ( Steele et al, 2011 ; Schmitt et al, 2012 ; Wu et al, 2021 ). Recently, co-occurrence network approaches have been increasingly applied to investigate in detail the association relationships among microbial individuals ( Faust et al, 2012 ; Ma et al, 2018b ; Shi et al, 2020a ; Yuan et al, 2021a ).…”

Section: Introductionmentioning

confidence: 99%

“…Recently, co-occurrence network approaches have been increasingly applied to investigate in detail the association relationships among microbial individuals ( Faust et al, 2012 ; Ma et al, 2018b ; Shi et al, 2020a ; Yuan et al, 2021a ). In addition, network robustness, calculated as the degree of natural connectivity determined by “attacking” the edges and nodes characterizing the network (removing the nodes and edges in the network randomly; Albert et al, 2000 ; Peng and Wu, 2016 ) is frequently being used ( Fan et al, 2018 ; Shi et al, 2019b ; Wu et al, 2021 ); higher robustness of networks (greater resistance of natural connectivity under attack) indicates that the community is more stable, while a sharply declining slope indicates lower network stability. It is conceivable that rhizofungal community networks may be sensitive to aboveground insect herbivory, as a form of biotic disturbance; nevertheless, their property changes and stability in response to insect herbivory remain largely unknown.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Foliar Herbivory Reduces Rhizosphere Fungal Diversity and Destabilizes the Co-occurrence Network

Shi

et al. 2022

Front. Microbiol.

Insect herbivores can adversely impact terrestrial plants throughout ontogeny and across various ecosystems. Simultaneously, the effects of foliar herbivory may extend belowground, to the soil microbial community. However, the responses in terms of the diversity, assembly, and stability of rhizosphere fungi to aboveground herbivory remain understudied. Here, using high-throughput sequencing, the effects of foliar insect herbivory on rhizosphere fungal microbes were investigated in a common garden experiment that manipulated herbivory intensity and time from herbivore removal. The number of observed fungal species was reduced by a greater herbivory intensity, with some species evidently sensitive to herbivory intensity and time since herbivore removal. Rhizofungal assembly processes were altered by both herbivory intensity and time since herbivore removal. Further, we found evidence that both factors strongly influenced fungal community stability: a high intensity of herbivory coupled with a shorter time since herbivore removal resulted in low stability. These results suggest that foliar herbivory can adversely alter fungal diversity and stability, which would in turn be harmful for plant health. Fortunately, the effect seems to gradually diminish with time elapsed after herbivore removal. Our findings provide a fresh, in-depth view into the roles of rhizofungi in enhancing the adaption ability of plants under environmental stress.