Association genetics, geography and ecophysiology link stomatal patterning in Populus trichocarpa with carbon gain and disease resistance trade-offs.
Identifieur interne : 000047 ( Main/Exploration ); précédent : 000046; suivant : 000048Association genetics, geography and ecophysiology link stomatal patterning in Populus trichocarpa with carbon gain and disease resistance trade-offs.
Auteurs : Athena D. Mckown [Canada] ; Robert D. Guy ; Linda Quamme ; Jaroslav Klápšt ; Jonathan La Mantia ; C P Constabel ; Yousry A. El-Kassaby ; Richard C. Hamelin ; Michael Zifkin ; M S AzamSource :
- Molecular ecology [ 1365-294X ] ; 2014.
Descripteurs français
- KwdFr :
- Caractère quantitatif héréditaire (MeSH), Carbone (MeSH), Environnement (MeSH), Feuilles de plante (composition chimique), Gènes de plante (MeSH), Génotype (MeSH), Géographie (MeSH), Photosynthèse (physiologie), Polymorphisme de nucléotide simple (MeSH), Populus (génétique), Populus (physiologie), Résistance à la maladie (MeSH), Stomates de plante (anatomie et histologie), Stomates de plante (physiologie), Tanins (composition chimique), Variation génétique (MeSH), Études d'associations génétiques (MeSH).
- MESH :
- anatomie et histologie : Stomates de plante.
- composition chimique : Feuilles de plante, Tanins.
- génétique : Populus.
- physiologie : Photosynthèse, Populus, Stomates de plante.
- Caractère quantitatif héréditaire, Carbone, Environnement, Gènes de plante, Génotype, Géographie, Polymorphisme de nucléotide simple, Résistance à la maladie, Variation génétique, Études d'associations génétiques.
English descriptors
- KwdEn :
- Carbon (MeSH), Disease Resistance (MeSH), Environment (MeSH), Genes, Plant (MeSH), Genetic Association Studies (MeSH), Genetic Variation (MeSH), Genotype (MeSH), Geography (MeSH), Photosynthesis (physiology), Plant Leaves (chemistry), Plant Stomata (anatomy & histology), Plant Stomata (physiology), Polymorphism, Single Nucleotide (MeSH), Populus (genetics), Populus (physiology), Quantitative Trait, Heritable (MeSH), Tannins (chemistry).
- MESH :
- chemical , chemistry : Tannins.
- chemical : Carbon.
- anatomy & histology : Plant Stomata.
- chemistry : Plant Leaves.
- genetics : Populus.
- physiology : Photosynthesis, Plant Stomata, Populus.
- Disease Resistance, Environment, Genes, Plant, Genetic Association Studies, Genetic Variation, Genotype, Geography, Polymorphism, Single Nucleotide, Quantitative Trait, Heritable.
Abstract
Stomata are essential for diffusive entry of gases to support photosynthesis, but may also expose internal leaf tissues to pathogens. To uncover trade-offs in range-wide adaptation relating to stomata, we investigated the underlying genetics of stomatal traits and linked variability in these traits with geoclimate, ecophysiology, condensed foliar tannins and pathogen susceptibility in black cottonwood (Populus trichocarpa). Upper (adaxial) and lower (abaxial) leaf stomatal traits were measured from 454 accessions collected throughout much of the species range. We calculated broad-sense heritability (H(2) ) of stomatal traits and, using SNP data from a 34K Populus SNP array, performed a genome-wide association studies (GWAS) to uncover genes underlying stomatal trait variation. H(2) values for stomatal traits were moderate (average H(2) = 0.33). GWAS identified genes associated primarily with adaxial stomata, including polarity genes (PHABULOSA), stomatal development genes (BRASSINOSTEROID-INSENSITIVE 2) and disease/wound-response genes (GLUTAMATE-CYSTEINE LIGASE). Stomatal traits correlated with latitude, gas exchange, condensed tannins and leaf rust (Melampsora) infection. Latitudinal trends of greater adaxial stomata numbers and guard cell pore size corresponded with higher stomatal conductance (gs ) and photosynthesis (Amax ), faster shoot elongation, lower foliar tannins and greater Melampsora susceptibility. This suggests an evolutionary trade-off related to differing selection pressures across the species range. In northern environments, more adaxial stomata and larger pore sizes reflect selection for rapid carbon gain and growth. By contrast, southern genotypes have fewer adaxial stomata, smaller pore sizes and higher levels of condensed tannins, possibly linked to greater pressure from natural leaf pathogens, which are less significant in northern ecosystems.
DOI: 10.1111/mec.12969
PubMed: 25319679
Affiliations:
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To uncover trade-offs in range-wide adaptation relating to stomata, we investigated the underlying genetics of stomatal traits and linked variability in these traits with geoclimate, ecophysiology, condensed foliar tannins and pathogen susceptibility in black cottonwood (Populus trichocarpa). Upper (adaxial) and lower (abaxial) leaf stomatal traits were measured from 454 accessions collected throughout much of the species range. We calculated broad-sense heritability (H(2) ) of stomatal traits and, using SNP data from a 34K Populus SNP array, performed a genome-wide association studies (GWAS) to uncover genes underlying stomatal trait variation. H(2) values for stomatal traits were moderate (average H(2) = 0.33). GWAS identified genes associated primarily with adaxial stomata, including polarity genes (PHABULOSA), stomatal development genes (BRASSINOSTEROID-INSENSITIVE 2) and disease/wound-response genes (GLUTAMATE-CYSTEINE LIGASE). Stomatal traits correlated with latitude, gas exchange, condensed tannins and leaf rust (Melampsora) infection. Latitudinal trends of greater adaxial stomata numbers and guard cell pore size corresponded with higher stomatal conductance (gs ) and photosynthesis (Amax ), faster shoot elongation, lower foliar tannins and greater Melampsora susceptibility. This suggests an evolutionary trade-off related to differing selection pressures across the species range. In northern environments, more adaxial stomata and larger pore sizes reflect selection for rapid carbon gain and growth. By contrast, southern genotypes have fewer adaxial stomata, smaller pore sizes and higher levels of condensed tannins, possibly linked to greater pressure from natural leaf pathogens, which are less significant in northern ecosystems.</div></front></TEI><pubmed><MedlineCitation Status="MEDLINE" Owner="NLM"><PMID Version="1">25319679</PMID><DateCompleted><Year>2015</Year><Month>02</Month><Day>21</Day></DateCompleted><DateRevised><Year>2014</Year><Month>11</Month><Day>27</Day></DateRevised><Article PubModel="Print-Electronic"><Journal><ISSN IssnType="Electronic">1365-294X</ISSN><JournalIssue CitedMedium="Internet"><Volume>23</Volume><Issue>23</Issue><PubDate><Year>2014</Year><Month>Dec</Month></PubDate></JournalIssue><Title>Molecular ecology</Title><ISOAbbreviation>Mol Ecol</ISOAbbreviation></Journal><ArticleTitle>Association genetics, geography and ecophysiology link stomatal patterning in Populus trichocarpa with carbon gain and disease resistance trade-offs.</ArticleTitle><Pagination><MedlinePgn>5771-90</MedlinePgn></Pagination><ELocationID EIdType="doi" ValidYN="Y">10.1111/mec.12969</ELocationID><Abstract><AbstractText>Stomata are essential for diffusive entry of gases to support photosynthesis, but may also expose internal leaf tissues to pathogens. To uncover trade-offs in range-wide adaptation relating to stomata, we investigated the underlying genetics of stomatal traits and linked variability in these traits with geoclimate, ecophysiology, condensed foliar tannins and pathogen susceptibility in black cottonwood (Populus trichocarpa). Upper (adaxial) and lower (abaxial) leaf stomatal traits were measured from 454 accessions collected throughout much of the species range. We calculated broad-sense heritability (H(2) ) of stomatal traits and, using SNP data from a 34K Populus SNP array, performed a genome-wide association studies (GWAS) to uncover genes underlying stomatal trait variation. H(2) values for stomatal traits were moderate (average H(2) = 0.33). GWAS identified genes associated primarily with adaxial stomata, including polarity genes (PHABULOSA), stomatal development genes (BRASSINOSTEROID-INSENSITIVE 2) and disease/wound-response genes (GLUTAMATE-CYSTEINE LIGASE). Stomatal traits correlated with latitude, gas exchange, condensed tannins and leaf rust (Melampsora) infection. Latitudinal trends of greater adaxial stomata numbers and guard cell pore size corresponded with higher stomatal conductance (gs ) and photosynthesis (Amax ), faster shoot elongation, lower foliar tannins and greater Melampsora susceptibility. This suggests an evolutionary trade-off related to differing selection pressures across the species range. In northern environments, more adaxial stomata and larger pore sizes reflect selection for rapid carbon gain and growth. By contrast, southern genotypes have fewer adaxial stomata, smaller pore sizes and higher levels of condensed tannins, possibly linked to greater pressure from natural leaf pathogens, which are less significant in northern ecosystems.</AbstractText><CopyrightInformation>© 2014 John Wiley & Sons Ltd.</CopyrightInformation></Abstract><AuthorList CompleteYN="Y"><Author ValidYN="Y"><LastName>McKown</LastName><ForeName>Athena D</ForeName><Initials>AD</Initials><AffiliationInfo><Affiliation>Department of Forest and Conservation Sciences, Faculty of Forestry, Forest Sciences Centre, University of British Columbia, 2424 Main Mall, Vancouver, BC, V6T 1Z4, Canada.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Guy</LastName><ForeName>Robert D</ForeName><Initials>RD</Initials></Author><Author ValidYN="Y"><LastName>Quamme</LastName><ForeName>Linda</ForeName><Initials>L</Initials></Author><Author ValidYN="Y"><LastName>Klápště</LastName><ForeName>Jaroslav</ForeName><Initials>J</Initials></Author><Author ValidYN="Y"><LastName>La Mantia</LastName><ForeName>Jonathan</ForeName><Initials>J</Initials></Author><Author ValidYN="Y"><LastName>Constabel</LastName><ForeName>C P</ForeName><Initials>CP</Initials></Author><Author ValidYN="Y"><LastName>El-Kassaby</LastName><ForeName>Yousry A</ForeName><Initials>YA</Initials></Author><Author ValidYN="Y"><LastName>Hamelin</LastName><ForeName>Richard C</ForeName><Initials>RC</Initials></Author><Author ValidYN="Y"><LastName>Zifkin</LastName><ForeName>Michael</ForeName><Initials>M</Initials></Author><Author ValidYN="Y"><LastName>Azam</LastName><ForeName>M S</ForeName><Initials>MS</Initials></Author></AuthorList><Language>eng</Language><PublicationTypeList><PublicationType UI="D016428">Journal Article</PublicationType><PublicationType UI="D013485">Research Support, Non-U.S. Gov't</PublicationType></PublicationTypeList><ArticleDate DateType="Electronic"><Year>2014</Year><Month>11</Month><Day>08</Day></ArticleDate></Article><MedlineJournalInfo><Country>England</Country><MedlineTA>Mol Ecol</MedlineTA><NlmUniqueID>9214478</NlmUniqueID><ISSNLinking>0962-1083</ISSNLinking></MedlineJournalInfo><ChemicalList><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="D013634">Tannins</NameOfSubstance></Chemical><Chemical><RegistryNumber>7440-44-0</RegistryNumber><NameOfSubstance UI="D002244">Carbon</NameOfSubstance></Chemical></ChemicalList><CitationSubset>IM</CitationSubset><MeshHeadingList><MeshHeading><DescriptorName UI="D002244" MajorTopicYN="Y">Carbon</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D060467" MajorTopicYN="Y">Disease Resistance</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D004777" MajorTopicYN="N">Environment</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D017343" MajorTopicYN="N">Genes, Plant</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D056726" MajorTopicYN="N">Genetic Association Studies</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D014644" MajorTopicYN="N">Genetic Variation</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D005838" MajorTopicYN="N">Genotype</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D005843" MajorTopicYN="N">Geography</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D010788" MajorTopicYN="N">Photosynthesis</DescriptorName><QualifierName UI="Q000502" MajorTopicYN="N">physiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D018515" MajorTopicYN="N">Plant Leaves</DescriptorName><QualifierName UI="Q000737" MajorTopicYN="N">chemistry</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D054046" MajorTopicYN="N">Plant Stomata</DescriptorName><QualifierName UI="Q000033" MajorTopicYN="Y">anatomy & histology</QualifierName><QualifierName UI="Q000502" MajorTopicYN="N">physiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D020641" MajorTopicYN="N">Polymorphism, Single Nucleotide</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D032107" MajorTopicYN="N">Populus</DescriptorName><QualifierName UI="Q000235" MajorTopicYN="Y">genetics</QualifierName><QualifierName UI="Q000502" MajorTopicYN="N">physiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D019655" MajorTopicYN="N">Quantitative Trait, Heritable</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D013634" MajorTopicYN="N">Tannins</DescriptorName><QualifierName UI="Q000737" MajorTopicYN="N">chemistry</QualifierName></MeshHeading></MeshHeadingList><KeywordList Owner="NOTNLM"><Keyword MajorTopicYN="N">Melampsora</Keyword><Keyword MajorTopicYN="N">adaxial-abaxial patterning</Keyword><Keyword MajorTopicYN="N">amphistomaty</Keyword><Keyword MajorTopicYN="N">evolutionary trade-offs</Keyword><Keyword MajorTopicYN="N">genome-wide association studies</Keyword><Keyword MajorTopicYN="N">stomatal conductance</Keyword><Keyword MajorTopicYN="N">stomatal ratio</Keyword></KeywordList></MedlineCitation><PubmedData><History><PubMedPubDate PubStatus="received"><Year>2014</Year><Month>06</Month><Day>04</Day></PubMedPubDate><PubMedPubDate PubStatus="revised"><Year>2014</Year><Month>09</Month><Day>29</Day></PubMedPubDate><PubMedPubDate PubStatus="accepted"><Year>2014</Year><Month>10</Month><Day>12</Day></PubMedPubDate><PubMedPubDate PubStatus="entrez"><Year>2014</Year><Month>10</Month><Day>17</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="pubmed"><Year>2014</Year><Month>10</Month><Day>17</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="medline"><Year>2015</Year><Month>2</Month><Day>24</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate></History><PublicationStatus>ppublish</PublicationStatus><ArticleIdList><ArticleId IdType="pubmed">25319679</ArticleId><ArticleId IdType="doi">10.1111/mec.12969</ArticleId></ArticleIdList></PubmedData></pubmed><affiliations><list><country><li>Canada</li></country><region><li>Colombie-Britannique </li></region><settlement><li>Vancouver</li></settlement><orgName><li>Université de la Colombie-Britannique</li></orgName></list><tree><noCountry><name sortKey="Azam, M S" sort="Azam, M S" uniqKey="Azam M" first="M S" last="Azam">M S Azam</name><name sortKey="Constabel, C P" sort="Constabel, C P" uniqKey="Constabel C" first="C P" last="Constabel">C P Constabel</name><name sortKey="El Kassaby, Yousry A" sort="El Kassaby, Yousry A" uniqKey="El Kassaby Y" first="Yousry A" last="El-Kassaby">Yousry A. El-Kassaby</name><name sortKey="Guy, Robert D" sort="Guy, Robert D" uniqKey="Guy R" first="Robert D" last="Guy">Robert D. Guy</name><name sortKey="Hamelin, Richard C" sort="Hamelin, Richard C" uniqKey="Hamelin R" first="Richard C" last="Hamelin">Richard C. Hamelin</name><name sortKey="Klapst, Jaroslav" sort="Klapst, Jaroslav" uniqKey="Klapst J" first="Jaroslav" last="Klápšt">Jaroslav Klápšt</name><name sortKey="La Mantia, Jonathan" sort="La Mantia, Jonathan" uniqKey="La Mantia J" first="Jonathan" last="La Mantia">Jonathan La Mantia</name><name sortKey="Quamme, Linda" sort="Quamme, Linda" uniqKey="Quamme L" first="Linda" last="Quamme">Linda Quamme</name><name sortKey="Zifkin, Michael" sort="Zifkin, Michael" uniqKey="Zifkin M" first="Michael" last="Zifkin">Michael Zifkin</name></noCountry><country name="Canada"><region name="Colombie-Britannique "><name sortKey="Mckown, Athena D" sort="Mckown, Athena D" uniqKey="Mckown A" first="Athena D" last="Mckown">Athena D. 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