Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota

Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota

Abstract Background Soils are a key component of agricultural productivity, and soil microbiota determine the availability of many essential plant nutrients. Agricultural domestication of soils, that is, the conversion of previously uncultivated soils to a cultivated state, is frequently accompanied...

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Main Authors: Joseph Edwards, Christian Santos-Medellín, Bao Nguyen, John Kilmer, Zachary Liechty, Esteban Veliz, Jiadong Ni, Gregory Phillips, Venkatesan Sundaresan
Format: Article
Language:English
Published: BMC 2019-10-01
Series:Genome Biology
Online Access:http://link.springer.com/article/10.1186/s13059-019-1825-x
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spelling doaj-865b1530c10049b58c07c67692406c932020-11-25T03:34:43ZengBMCGenome Biology1474-760X2019-10-0120111410.1186/s13059-019-1825-xSoil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiotaJoseph Edwards0Christian Santos-Medellín1Bao Nguyen2John Kilmer3Zachary Liechty4Esteban Veliz5Jiadong Ni6Gregory Phillips7Venkatesan Sundaresan8Department of Plant Biology, University of California, DavisDepartment of Plant Biology, University of California, DavisDepartment of Plant Biology, University of California, DavisDepartment of Agriculture, Arkansas State UniversityDepartment of Plant Biology, University of California, DavisDepartment of Plant Biology, University of California, DavisDepartment of Plant Biology, University of California, DavisDepartment of Agriculture, Arkansas State UniversityDepartment of Plant Biology, University of California, DavisAbstract Background Soils are a key component of agricultural productivity, and soil microbiota determine the availability of many essential plant nutrients. Agricultural domestication of soils, that is, the conversion of previously uncultivated soils to a cultivated state, is frequently accompanied by intensive monoculture, especially in the developing world. However, there is limited understanding of how continuous cultivation alters the structure of prokaryotic soil microbiota after soil domestication, including to what extent crop plants impact soil microbiota composition, and how changes in microbiota composition arising from cultivation affect crop performance. Results We show here that continuous monoculture (> 8 growing seasons) of the major food crop rice under flooded conditions is associated with a pronounced shift in soil bacterial and archaeal microbiota structure towards a more consistent composition, thereby domesticating microbiota of previously uncultivated sites. Aside from the potential effects of agricultural cultivation practices, we provide evidence that rice plants themselves are important drivers of the domestication process, acting through selective enrichment of specific taxa, including methanogenic archaea, in their rhizosphere that differ from those of native plants growing in the same environment. Furthermore, we find that microbiota from soils domesticated by rice cultivation contribute to plant-soil feedback, by imparting a negative effect on rice seedling vigor. Conclusions Soil domestication through continuous monoculture cultivation of rice results in compositional changes in the soil microbiota, which are in part driven by the rice plants. The consequences include a negative impact on plant performance and increases in greenhouse gas emitting microbes.http://link.springer.com/article/10.1186/s13059-019-1825-x
collection DOAJ
language English
format Article
sources DOAJ
author Joseph Edwards
Christian Santos-Medellín
Bao Nguyen
John Kilmer
Zachary Liechty
Esteban Veliz
Jiadong Ni
Gregory Phillips
Venkatesan Sundaresan
spellingShingle Joseph Edwards
Christian Santos-Medellín
Bao Nguyen
John Kilmer
Zachary Liechty
Esteban Veliz
Jiadong Ni
Gregory Phillips
Venkatesan Sundaresan
Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota
Genome Biology
author_facet Joseph Edwards
Christian Santos-Medellín
Bao Nguyen
John Kilmer
Zachary Liechty
Esteban Veliz
Jiadong Ni
Gregory Phillips
Venkatesan Sundaresan
author_sort Joseph Edwards
title Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota
title_short Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota
title_full Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota
title_fullStr Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota
title_full_unstemmed Soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota
title_sort soil domestication by rice cultivation results in plant-soil feedback through shifts in soil microbiota
publisher BMC
series Genome Biology
issn 1474-760X
publishDate 2019-10-01
description Abstract Background Soils are a key component of agricultural productivity, and soil microbiota determine the availability of many essential plant nutrients. Agricultural domestication of soils, that is, the conversion of previously uncultivated soils to a cultivated state, is frequently accompanied by intensive monoculture, especially in the developing world. However, there is limited understanding of how continuous cultivation alters the structure of prokaryotic soil microbiota after soil domestication, including to what extent crop plants impact soil microbiota composition, and how changes in microbiota composition arising from cultivation affect crop performance. Results We show here that continuous monoculture (> 8 growing seasons) of the major food crop rice under flooded conditions is associated with a pronounced shift in soil bacterial and archaeal microbiota structure towards a more consistent composition, thereby domesticating microbiota of previously uncultivated sites. Aside from the potential effects of agricultural cultivation practices, we provide evidence that rice plants themselves are important drivers of the domestication process, acting through selective enrichment of specific taxa, including methanogenic archaea, in their rhizosphere that differ from those of native plants growing in the same environment. Furthermore, we find that microbiota from soils domesticated by rice cultivation contribute to plant-soil feedback, by imparting a negative effect on rice seedling vigor. Conclusions Soil domestication through continuous monoculture cultivation of rice results in compositional changes in the soil microbiota, which are in part driven by the rice plants. The consequences include a negative impact on plant performance and increases in greenhouse gas emitting microbes.
url http://link.springer.com/article/10.1186/s13059-019-1825-x
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