Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities

Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities

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The phyllosphere epiphytic microbiome is composed of microorganisms that colonize the external aerial portions of plants. Relationships of plant responses to specific microorganisms–both pathogenic and beneficial–have been examined, but the phyllosphere microbiome functional and metabolic profile re...

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Main Authors: Barbara A. Methe, David Hiltbrand, Jeffrey Roach, Wenwei Xu, Stuart G. Gordon, Brad W. Goodner, Ann E. Stapleton, Sara Amancio
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2020-01-01
Series:PLoS ONE
Online Access:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7500591/?tool=EBI
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spelling doaj-fb33cfa1c0f54d17b969414df216aabc2020-11-25T03:29:05ZengPublic Library of Science (PLoS)PLoS ONE1932-62032020-01-01159Functional gene categories differentiate maize leaf drought-related microbial epiphytic communitiesBarbara A. MetheDavid HiltbrandJeffrey RoachWenwei XuStuart G. GordonBrad W. GoodnerAnn E. StapletonSara AmancioThe phyllosphere epiphytic microbiome is composed of microorganisms that colonize the external aerial portions of plants. Relationships of plant responses to specific microorganisms–both pathogenic and beneficial–have been examined, but the phyllosphere microbiome functional and metabolic profile responses are not well described. Changing crop growth conditions, such as increased drought, can have profound impacts on crop productivity. Also, epiphytic microbial communities provide a new target for crop yield optimization. We compared Zea mays leaf microbiomes collected under drought and well-watered conditions by examining functional gene annotation patterns across three physically disparate locations each with and without drought treatment, through the application of short read metagenomic sequencing. Drought samples exhibited different functional sequence compositions at each of the three field sites. Maize phyllosphere functional profiles revealed a wide variety of metabolic and regulatory processes that differed in drought and normal water conditions and provide key baseline information for future selective breeding.https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7500591/?tool=EBI
collection DOAJ
language English
format Article
sources DOAJ
author Barbara A. Methe
David Hiltbrand
Jeffrey Roach
Wenwei Xu
Stuart G. Gordon
Brad W. Goodner
Ann E. Stapleton
Sara Amancio
spellingShingle Barbara A. Methe
David Hiltbrand
Jeffrey Roach
Wenwei Xu
Stuart G. Gordon
Brad W. Goodner
Ann E. Stapleton
Sara Amancio
Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities
PLoS ONE
author_facet Barbara A. Methe
David Hiltbrand
Jeffrey Roach
Wenwei Xu
Stuart G. Gordon
Brad W. Goodner
Ann E. Stapleton
Sara Amancio
author_sort Barbara A. Methe
title Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities
title_short Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities
title_full Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities
title_fullStr Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities
title_full_unstemmed Functional gene categories differentiate maize leaf drought-related microbial epiphytic communities
title_sort functional gene categories differentiate maize leaf drought-related microbial epiphytic communities
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2020-01-01
description The phyllosphere epiphytic microbiome is composed of microorganisms that colonize the external aerial portions of plants. Relationships of plant responses to specific microorganisms–both pathogenic and beneficial–have been examined, but the phyllosphere microbiome functional and metabolic profile responses are not well described. Changing crop growth conditions, such as increased drought, can have profound impacts on crop productivity. Also, epiphytic microbial communities provide a new target for crop yield optimization. We compared Zea mays leaf microbiomes collected under drought and well-watered conditions by examining functional gene annotation patterns across three physically disparate locations each with and without drought treatment, through the application of short read metagenomic sequencing. Drought samples exhibited different functional sequence compositions at each of the three field sites. Maize phyllosphere functional profiles revealed a wide variety of metabolic and regulatory processes that differed in drought and normal water conditions and provide key baseline information for future selective breeding.
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7500591/?tool=EBI
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