Soil abiotic variables are more important than Salicaceae phylogeny or habitat specialization in determining soil microbial community structure

Erlandson, Sonya; Wei, Xiaojing; Savage, Jessica; Cavender‐Bares, Jeannine; Peay, Kabir G.

doi:10.1111/mec.14576

Cited by 52 publications

(52 citation statements)

References 108 publications

(166 reference statements)

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“…However, total and functional group fungal richness were affected by some different contemporary environmental factors in temperate and tropic-subtropical forests, as reported in Tedersoo et al (2014). It is highly possible that plants can modify soil environments through litter or root exudates and soil environments can affect plants in ways resulting in plant-soil feedback that can influence total and saprotrophic fungal richness in tropic-subtropical forest (Erlandson, Wei, Savage, Cavender-Bares, & Peay, 2018). It is highly possible that plants can modify soil environments through litter or root exudates and soil environments can affect plants in ways resulting in plant-soil feedback that can influence total and saprotrophic fungal richness in tropic-subtropical forest (Erlandson, Wei, Savage, Cavender-Bares, & Peay, 2018).…”

Section: Discussionmentioning

confidence: 77%

Late Quaternary climate change explains soil fungal community composition rather than fungal richness in forest ecosystems

Gao

Sandel

et al. 2019

Ecology and Evolution

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The dramatic climate fluctuations of the late Quaternary have influenced the diversity and composition of macroorganism communities, but how they structure belowground microbial communities is less well known. Fungi constitute an important component of soil microorganism communities. They play an important role in biodiversity maintenance, community assembly, and ecosystem functioning, and differ from many macroorganisms in many traits. Here, we examined soil fungal communities in Chinese temperate, subtropical, and tropic forests using Illumina MiSeq sequencing of the fungal ITS1 region. The relative effect of late Quaternary climate change and contemporary environment (plant, soil, current climate, and geographic distance) on the soil fungal community was analyzed. The richness of the total fungal community, along with saprotrophic, ectomycorrhizal (EM), and pathogenic fungal communities, was influenced primarily by the contemporary environment (plant and/or soil) but not by late Quaternary climate change. Late Quaternary climate change acted in concert with the contemporary environment to shape total, saprotrophic, EM, and pathogenic fungal community compositions and with a stronger effect in temperate forest than in tropic–subtropical forest ecosystems. Some contemporary environmental factors influencing total, saprotrophic, EM, and pathogenic fungal communities in temperate and tropic–subtropical forests were different. We demonstrate that late Quaternary climate change can help to explain current soil fungal community composition and argue that climatic legacies can help to predict soil fungal responses to climate change.

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Section: Discussionmentioning

confidence: 77%

Late Quaternary climate change explains soil fungal community composition rather than fungal richness in forest ecosystems

Gao

Sandel

et al. 2019

Ecology and Evolution

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“…; Erlandson et al. ), which vary across our populations (Fig. and Table ) and can also be altered by plant genotypes (Palomares‐Rius et al.…”

Section: Discussionmentioning

confidence: 91%

“…Several phenomena could explain this interactive effect of plant genotype and rhizosphere biota. Community composition of rhizosphere biota often differs strongly across abiotic source conditions (Bongers and Ferris 1999;Bulgarelli et al 2012;Erlandson et al 2018), which vary across our populations ( Fig. S2 and Table S1) and can also be altered by plant genotypes (Palomares-Rius et al 2012;Peiffer et al 2013;Lebeis et al 2015;Walters et al 2018), leading to genotype-by-source-environment dependent community composition.…”

Section: Plastic Responses and Trait Divergencementioning

confidence: 99%

Adaptive phenotypic divergence in an annual grass differs across biotic contexts*

et al. 2019

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Climate is a powerful force shaping adaptation within species, yet adaptation to climate occurs against a biotic background: species interactions can filter fitness consequences of genetic variation by altering phenotypic expression of genotypes. We investigated this process using populations of teosinte, a wild annual grass related to maize (Zea mays ssp. mexicana), sampling plants from 10 sites along an elevational gradient as well as rhizosphere biota from three of those sites. We grew half‐sibling teosinte families in each biota to test whether trait divergence among teosinte populations reflects adaptation or drift, and whether rhizosphere biota affect expression of diverged traits. We further assayed the influence of rhizosphere biota on contemporary additive genetic variation. We found that adaptation across environment shaped divergence of some traits, particularly flowering time and root biomass. We also observed that different rhizosphere biota shifted expressed values of these traits within teosinte populations and families and altered within‐population genetic variance and covariance. In sum, our results imply that changes in trait expression and covariance elicited by rhizosphere communities could have played a historical role in teosinte adaptation to environments and that they are likely to play a role in the response to future selection.

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“…The second section featured a number of manuscripts that investigated the structure of the microbiome in an attempt to understand the drivers of microbiota community assembly and turnover. Some contributions weighed in on the role of host phylogeny vs. ecology (Erlandson, Savage, Wei, Cavender‐Bares, & Peay, ; Ivens, Gadau, Kiers, & Kronauer, 2018; Hernandez‐Gomez, Briggler, & Williams, ; Kohl, Dearing, & Bordenstein, ; Nishida & Ochman, ; Roth‐Schulze et al., ; Schuelke, Pereira, Hardy, & Bik, ), others probed how the presence of hosts themselves alters the microbiota around them (Chen & Parfrey, ; Shukla, Vogel, Heckel, Vilcinskas, & Kaltenpoth, ), one investigated patterns of co‐infection (Rock et al, ) and one documented changes in microbiota during development (Prest, Kimball, Kueneman, & McKenzie, ). A few studies in this section studied the structure of the microbiome with manipulative experiments (e.g., Chen & Parfrey, ; Erlandson et al, ; Morella, Gomez, Wang, Leung, & Koskella, ; Raymann, Bobay, & Moran, ).…”

Section: Special Issuesmentioning

confidence: 99%

Editorial 2019

Geraldes¹,

Belkin²,

Chambers³

et al. 2019

Molecular Ecology

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Soil abiotic variables are more important than Salicaceae phylogeny or habitat specialization in determining soil microbial community structure

Cited by 52 publications

References 108 publications

Late Quaternary climate change explains soil fungal community composition rather than fungal richness in forest ecosystems

Late Quaternary climate change explains soil fungal community composition rather than fungal richness in forest ecosystems

Adaptive phenotypic divergence in an annual grass differs across biotic contexts*

Editorial 2019

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