Climate warming promotes deterministic assembly of arbuscular mycorrhizal fungal communities

Xu, Xinyu; Qiu, Yunpeng; Zhang, Kangcheng; Yang, Fei; Luo, Xi; Yan, Xin; Wang, Peng; Chen, Huaihai; Guo, Hui; Jiang, Lin; Hu, Shuijin

doi:10.1111/gcb.15945

Cited by 41 publications

(19 citation statements)

References 107 publications

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“…Our analyses indicate that warming leads to changes in allocation, consistent with other observations and experimental evidence 22,23 . Liu et al 23 , for example, have shown that warming leads to a shift towards deeper rooting and more below-ground carbon allocation in alpine grasslands, allowing plants to acquire more water and nutrients.…”

Section: Discussionsupporting

confidence: 92%

“…Increased VPD and warming had negative effects in both areas, but when compared with other environmental factors, the impact of VPD and warming was greater in energy limited areas (−0.106±0.043% yr −1 , −0.132±0.031% yr −1 respectively) than water limited areas (−0.142±0.064% yr −1 , −0.078±0.026% yr −1 respectively). This difference in response reflects the fact that increased atmospheric aridity and warming in energy limited areas necessitates increased below-ground allocation for nutrient and water uptake 22,23 and is consistent with an inferred increase in the unit cost of constructing and maintaining leaves (zcost) (Supplementary Fig. 8).…”

Section: Resultssupporting

confidence: 63%

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Optimality principles explaining divergent responses of alpine vegetation to environmental change

Zhu

Wang

Harrison

et al. 2022

Global Change Biology

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Recent increases in vegetation cover, observed over much of the world, reflect increasing CO2 globally and warming in cold areas. However, the strength of the response to both CO2 and warming appears to be declining. Here we examine changes in vegetation cover on the Tibetan Plateau over the past 35 years. Although the climate trends are similar across the Plateau, drier regions have become greener by 0.31±0.14% yr −1 while wetter regions have become browner by 0.12±0.08% yr -1 . This divergent response is predicted by a universal model of primary production accounting for optimal carbon allocation to leaves, subject to constraint by water availability. Rising CO2 stimulates production in both greening and browning areas; increased precipitation enhances growth in dry regions, but growth is reduced in wetter regions because warming increases below-ground allocation costs. The declining sensitivity of vegetation to climate change reflects a shift from water to energy limitation. Main textA global increase in vegetation cover has been observed in recent decades 1-3 although this greening is not universal and some regions have experienced browning 4,5 . Greening has been attributed to human activities 1,2,6 . Recent increases in atmospheric CO2 concentration have had a positive impact on primary production and enhanced vegetation cover [7][8][9] . The impact of changes in climate has been more spatially heterogeneous 2,3 but it is thought that warming explains the marked greening trend observed in high northern latitudes [10][11][12] . There has been a 16% decline in the area of the northern extratropics where vegetation growth is limited by temperature over the past three decades, primarily at the southern margin of high-latitude ecosystems 10 . However, there is evidence that the thermal response of vegetation growth and carbon uptake has weakened over this period 13,14 for reasons that

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Section: Discussionsupporting

confidence: 92%

Section: Resultssupporting

confidence: 63%

Optimality principles explaining divergent responses of alpine vegetation to environmental change

Zhu

Wang

Harrison

et al. 2022

Global Change Biology

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“…To download the taxonomic compositions of soil microbes that conduct broad and narrow functions, in the "Analysis" function of the MG-RAST server (https://www.mg-rast.org/mgmain. html?mgpage=analysis, last access: 10 September 2019), we loaded SEED subsystems (levels 3, 2, and 1) as functional profiles and RefSeq (Tatusova et al, 2013) databases (genus, family, order, class, and phylum levels) as taxonomic compositions (Xu et al, 2021) for each soil metagenome. The detailed protocols of the MG-RAST server were followed to analyze the metagenomic functions (Meyer et al, 2008;Wilke et al, 2017).…”

Section: Data Collectionmentioning

confidence: 99%

“…Nowadays, metagenomics is increasingly being used as a promising comparative tool (Tringe et al, 2005) to study the relationship between functional and taxonomic diversities (Fierer et al, 2012(Fierer et al, , 2013Souza et al, 2015;Pan et al, 2014;Leff et al, 2015). The growing wealth of soil metagenome data is thus well poised to aid in the generalization of global patterns of microbial attributes and the standardization of frameworks for the consistent representation of microbial communities (Xu et al, 2021). However, a synthetic metagenomic analysis to assess how general microbial taxonomic and functional beta diversities differ between broad and narrow functions across the globe is still lacking.…”

Section: Introductionmentioning

confidence: 99%

Lower functional redundancy in “narrow” than “broad” functions in global soil metagenomics

Chen

Huang

et al. 2022

SOIL

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Abstract. Understanding the relationship between soil microbial taxonomic compositions and functional profiles is essential for predicting ecosystem functions under various environmental disturbances. However, even though microbial communities are sensitive to disturbance, ecosystem functions remain relatively stable, as soil microbes are likely to be functionally redundant. Microbial functional redundancy may be more associated with “broad” functions carried out by a wide range of microbes than with “narrow” functions in which specific microorganisms specialize. Thus, a comprehensive study to evaluate how microbial taxonomic compositions correlate with broad and narrow functional profiles is necessary. Here, we evaluated soil metagenomes worldwide to assess whether functional and taxonomic diversities differ significantly between the five broad and the five narrow functions that we chose. Our results revealed that, compared with the five broad functions, soil microbes capable of performing the five narrow functions were more taxonomically diverse, and thus their functional diversity was more dependent on taxonomic diversity, implying lower levels of functional redundancy in narrow functions. Co-occurrence networks indicated that microorganisms conducting broad functions were positively related, but microbes specializing in narrow functions were interacting mostly negatively. Our study provides strong evidence to support our hypothesis that functional redundancy is significantly different between broad and narrow functions in soil microbes, as the association of functional diversity with taxonomy was greater in the five narrow than in the five broad functions.

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“…The Mantel test indicated no strong correlation between the fungal community structure and soil factors. The results of an alpine meadows study showed that 3 years of warming enhances the deterministic processes of the fungal community (Xu et al, 2022 ). Unexpectedly, a decrease in the relative importance of random processes of the fungal communities was observed after one growing season of warming in our study, indicating that the fungal communities in alpine peatlands are highly sensitive to temperature change.…”

Section: Discussionmentioning

confidence: 99%

The divergent vertical pattern and assembly of soil bacterial and fungal communities in response to short-term warming in an alpine peatland

Wang

Yan

et al. 2022

Front. Plant Sci.

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Soil microbial communities are crucial in ecosystem-level decomposition and nutrient cycling processes and are sensitive to climate change in peatlands. However, the response of the vertical distribution of microbial communities to warming remains unclear in the alpine peatland. In this study, we examined the effects of warming on the vertical pattern and assembly of soil bacterial and fungal communities across three soil layers (0–10, 10–20, and 20–30 cm) in the Zoige alpine peatland under a warming treatment. Our results showed that short-term warming had no significant effects on the alpha diversity of either the bacterial or the fungal community. Although the bacterial community in the lower layers became more similar as soil temperature increased, the difference in the vertical structure of the bacterial community among different treatments was not significant. In contrast, the vertical structure of the fungal community was significantly affected by warming. The main ecological process driving the vertical assembly of the bacterial community was the niche-based process in all treatments, while soil carbon and nutrients were the main driving factors. The vertical structure of the fungal community was driven by a dispersal-based process in control plots, while the niche and dispersal processes jointly regulated the fungal communities in the warming plots. Plant biomass was significantly related to the vertical structure of the fungal community under the warming treatments. The variation in pH was significantly correlated with the assembly of the bacterial community, while soil water content, microbial biomass carbon/microbial biomass phosphorous (MBC/MBP), and microbial biomass nitrogen/ microbial biomass phosphorous (MBN/MBP) were significantly correlated with the assembly of the fungal community. These results indicate that the vertical structure and assembly of the soil bacterial and fungal communities responded differently to warming and could provide a potential mechanism of microbial community assembly in the alpine peatland in response to warming.

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Climate warming promotes deterministic assembly of arbuscular mycorrhizal fungal communities

Cited by 41 publications

References 107 publications

Optimality principles explaining divergent responses of alpine vegetation to environmental change

Optimality principles explaining divergent responses of alpine vegetation to environmental change

Lower functional redundancy in “narrow” than “broad” functions in global soil metagenomics

The divergent vertical pattern and assembly of soil bacterial and fungal communities in response to short-term warming in an alpine peatland

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