Quantitative Genetics of the Maize Leaf Microbiome

The degree to which the genotype of an organism can affect the composition of its associated microbial communities ("microbiome") varies by organism and habitat, and in many cases is unknown. We analyzed the metabolically active bacteria of maize leaves across 300 diverse maize lines growi...

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Main Authors: Jason G. Wallace, Karl A. Kremling, Lynsey L. Kovar, Edward S. Buckler
Format: Article
Language:English
Published: The American Phytopathological Society 2019-03-01
Series:Phytobiomes Journal
Online Access:https://apsjournals.apsnet.org/doi/full/10.1094/PBIOMES-02-18-0008-R
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spelling doaj-5e56ec90dfcb4a1f960e7c3ff5f22c592020-11-25T01:10:17ZengThe American Phytopathological SocietyPhytobiomes Journal2471-29062019-03-012420822410.1094/PBIOMES-02-18-0008-RQuantitative Genetics of the Maize Leaf MicrobiomeJason G. Wallace0Karl A. Kremling1Lynsey L. Kovar2Edward S. Buckler3Department of Crop & Soil Sciences, University of Georgia, Athens, GA and Institute of Plant Breeding, Genetics, and Genomics, University of Georgia, Athens, GADepartment of Plant Breeding and Genetics, Cornell University, Ithaca, NYInstitute of Plant Breeding, Genetics, and Genomics, University of Georgia, Athens, GAU.S. Department of Agriculture–Agricultural Research Service, Ithaca, NY and Institute for Genomic Diversity, Cornell University, Ithaca, NYThe degree to which the genotype of an organism can affect the composition of its associated microbial communities ("microbiome") varies by organism and habitat, and in many cases is unknown. We analyzed the metabolically active bacteria of maize leaves across 300 diverse maize lines growing in a common environment. We performed comprehensive heritability analysis for 49 community diversity metrics, 380 bacterial clades, and 9,042 predicted metagenomic functions. We find that only a few bacterial clades (5) and diversity metrics (2) are significantly heritable, while a much larger number of metabolic functions (200) are. Many of these associations appear to be driven by the Methylobacteria in each sample. Among these heritable metabolic traits, Fisher's exact test identifies significant overrepresentation of traits relating to short-chain carbon metabolism, secretion, and nitrotoluene degradation. Genome-wide association analysis identified a small number of associated loci for these heritable traits, including two that affect multiple traits. Our results indicate that while most of the maize leaf microbiome composition is driven by environmental factors and/or stochastic founder events, a subset of bacterial taxa and metabolic functions is nonetheless significantly impacted by host genetics. Additional work will be needed to identify the exact nature of these interactions and what effects they may have on their host.https://apsjournals.apsnet.org/doi/full/10.1094/PBIOMES-02-18-0008-R
collection DOAJ
language English
format Article
sources DOAJ
author Jason G. Wallace
Karl A. Kremling
Lynsey L. Kovar
Edward S. Buckler
spellingShingle Jason G. Wallace
Karl A. Kremling
Lynsey L. Kovar
Edward S. Buckler
Quantitative Genetics of the Maize Leaf Microbiome
Phytobiomes Journal
author_facet Jason G. Wallace
Karl A. Kremling
Lynsey L. Kovar
Edward S. Buckler
author_sort Jason G. Wallace
title Quantitative Genetics of the Maize Leaf Microbiome
title_short Quantitative Genetics of the Maize Leaf Microbiome
title_full Quantitative Genetics of the Maize Leaf Microbiome
title_fullStr Quantitative Genetics of the Maize Leaf Microbiome
title_full_unstemmed Quantitative Genetics of the Maize Leaf Microbiome
title_sort quantitative genetics of the maize leaf microbiome
publisher The American Phytopathological Society
series Phytobiomes Journal
issn 2471-2906
publishDate 2019-03-01
description The degree to which the genotype of an organism can affect the composition of its associated microbial communities ("microbiome") varies by organism and habitat, and in many cases is unknown. We analyzed the metabolically active bacteria of maize leaves across 300 diverse maize lines growing in a common environment. We performed comprehensive heritability analysis for 49 community diversity metrics, 380 bacterial clades, and 9,042 predicted metagenomic functions. We find that only a few bacterial clades (5) and diversity metrics (2) are significantly heritable, while a much larger number of metabolic functions (200) are. Many of these associations appear to be driven by the Methylobacteria in each sample. Among these heritable metabolic traits, Fisher's exact test identifies significant overrepresentation of traits relating to short-chain carbon metabolism, secretion, and nitrotoluene degradation. Genome-wide association analysis identified a small number of associated loci for these heritable traits, including two that affect multiple traits. Our results indicate that while most of the maize leaf microbiome composition is driven by environmental factors and/or stochastic founder events, a subset of bacterial taxa and metabolic functions is nonetheless significantly impacted by host genetics. Additional work will be needed to identify the exact nature of these interactions and what effects they may have on their host.
url https://apsjournals.apsnet.org/doi/full/10.1094/PBIOMES-02-18-0008-R
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