Local Adaptation to Soil Hypoxia Determines the Structure of an Arbuscular Mycorrhizal Fungal Community in Roots from Natural CO2 Springs

Irena Macek; Alex J. Dumbrell; Michaela Nelson; Alastair H. Fitter; Dominik Vodnik; Thorunn Helgason

doi:10.1128/AEM.00139-11

Local Adaptation to Soil Hypoxia Determines the Structure of an Arbuscular Mycorrhizal Fungal Community in Roots from Natural CO2 Springs

Irena Macek, Alex J. Dumbrell, Michaela Nelson, Alastair H. Fitter, Dominik Vodnik, Thorunn Helgason

Biology

Research output: Contribution to journal › Article › peer-review

Abstract

The processes responsible for producing and maintaining the diversity of natural arbuscular mycorrhizal (AM) fungal communities remain largely unknown. We used natural CO2 springs (mofettes), which create hypoxic soil environments, to determine whether a long-term, directional, abiotic selection pressure could change AM fungal community structure and drive the selection of particular AM fungal phylotypes. We explored whether those phylotypes that appear exclusively in hypoxic soils are local specialists or widespread generalists able to tolerate a range of soil conditions. AM fungal community composition was characterized by cloning, restriction fragment length polymorphism typing, and the sequencing of small subunit rRNA genes from roots of four plant species growing at high (hypoxic) and low (control) geological CO2 exposure. We found significant levels of AM fungal community turnover (beta diversity) between soil types and the numerical dominance of two AM fungal phylotypes in hypoxic soils. Our results strongly suggest that direct environmental selection acting on AM fungi is a major factor regulating AM fungal communities and their phylogeographic patterns. Consequently, some AM fungi are more strongly associated with local variations in the soil environment than with their host plant's distribution.

Original language	English
Pages (from-to)	4770-4777
Number of pages	8
Journal	Applied and Environmental Microbiology
Volume	77
Issue number	14
DOIs	https://doi.org/10.1128/AEM.00139-11
Publication status	Published - Jul 2011

Keywords

CARBON-DIOXIDE
DIVERSITY
PLANTS
GLOMEROMYCOTA
WOODLAND
L.
PHOTOSYNTHESIS
BIODIVERSITY
EVOLUTION
ECOSYSTEM

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10.1128/AEM.00139-11

http://aem.asm.org/content/77/14/4770

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title = "Local Adaptation to Soil Hypoxia Determines the Structure of an Arbuscular Mycorrhizal Fungal Community in Roots from Natural CO2 Springs",

abstract = "The processes responsible for producing and maintaining the diversity of natural arbuscular mycorrhizal (AM) fungal communities remain largely unknown. We used natural CO2 springs (mofettes), which create hypoxic soil environments, to determine whether a long-term, directional, abiotic selection pressure could change AM fungal community structure and drive the selection of particular AM fungal phylotypes. We explored whether those phylotypes that appear exclusively in hypoxic soils are local specialists or widespread generalists able to tolerate a range of soil conditions. AM fungal community composition was characterized by cloning, restriction fragment length polymorphism typing, and the sequencing of small subunit rRNA genes from roots of four plant species growing at high (hypoxic) and low (control) geological CO2 exposure. We found significant levels of AM fungal community turnover (beta diversity) between soil types and the numerical dominance of two AM fungal phylotypes in hypoxic soils. Our results strongly suggest that direct environmental selection acting on AM fungi is a major factor regulating AM fungal communities and their phylogeographic patterns. Consequently, some AM fungi are more strongly associated with local variations in the soil environment than with their host plant's distribution.",

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author = "Irena Macek and Dumbrell, {Alex J.} and Michaela Nelson and Fitter, {Alastair H.} and Dominik Vodnik and Thorunn Helgason",

year = "2011",

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AU - Dumbrell, Alex J.

AU - Nelson, Michaela

AU - Fitter, Alastair H.

AU - Vodnik, Dominik

AU - Helgason, Thorunn

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AB - The processes responsible for producing and maintaining the diversity of natural arbuscular mycorrhizal (AM) fungal communities remain largely unknown. We used natural CO2 springs (mofettes), which create hypoxic soil environments, to determine whether a long-term, directional, abiotic selection pressure could change AM fungal community structure and drive the selection of particular AM fungal phylotypes. We explored whether those phylotypes that appear exclusively in hypoxic soils are local specialists or widespread generalists able to tolerate a range of soil conditions. AM fungal community composition was characterized by cloning, restriction fragment length polymorphism typing, and the sequencing of small subunit rRNA genes from roots of four plant species growing at high (hypoxic) and low (control) geological CO2 exposure. We found significant levels of AM fungal community turnover (beta diversity) between soil types and the numerical dominance of two AM fungal phylotypes in hypoxic soils. Our results strongly suggest that direct environmental selection acting on AM fungi is a major factor regulating AM fungal communities and their phylogeographic patterns. Consequently, some AM fungi are more strongly associated with local variations in the soil environment than with their host plant's distribution.

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Local Adaptation to Soil Hypoxia Determines the Structure of an Arbuscular Mycorrhizal Fungal Community in Roots from Natural CO2 Springs

Abstract

Keywords

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