Nutrient demand and fungal access to resources control the carbon allocation to the symbiotic partners in tripartite interactions of Medicago truncatula.
Identifieur interne : 000421 ( Main/Exploration ); précédent : 000420; suivant : 000422Nutrient demand and fungal access to resources control the carbon allocation to the symbiotic partners in tripartite interactions of Medicago truncatula.
Auteurs : Arjun Kafle [États-Unis] ; Kevin Garcia [États-Unis] ; Xiurong Wang [États-Unis, République populaire de Chine] ; Philip E. Pfeffer ; Gary D. Strahan ; Heike Bücking [États-Unis]Source :
- Plant, cell & environment [ 1365-3040 ] ; 2019.
Descripteurs français
- KwdFr :
- Azote (métabolisme), Carbone (métabolisme), Interactions hôte-microbes (physiologie), Medicago truncatula (microbiologie), Medicago truncatula (métabolisme), Medicago truncatula (physiologie), Mycorhizes (métabolisme), Mycorhizes (physiologie), Nitrogenase (métabolisme), Phosphore (métabolisme), Protéines de transport membranaire (métabolisme), Protéines végétales (métabolisme), Racines de plante (microbiologie), Racines de plante (métabolisme), Symbiose (MeSH), Transcriptome (MeSH).
- MESH :
- microbiologie : Medicago truncatula, Racines de plante.
- métabolisme : Azote, Carbone, Medicago truncatula, Mycorhizes, Nitrogenase, Phosphore, Protéines de transport membranaire, Protéines végétales, Racines de plante.
- physiologie : Interactions hôte-microbes, Medicago truncatula, Mycorhizes.
- Symbiose, Transcriptome.
English descriptors
- KwdEn :
- Carbon (metabolism), Host Microbial Interactions (physiology), Medicago truncatula (metabolism), Medicago truncatula (microbiology), Medicago truncatula (physiology), Membrane Transport Proteins (metabolism), Mycorrhizae (metabolism), Mycorrhizae (physiology), Nitrogen (metabolism), Nitrogenase (metabolism), Phosphorus (metabolism), Plant Proteins (metabolism), Plant Roots (metabolism), Plant Roots (microbiology), Symbiosis (MeSH), Transcriptome (MeSH).
- MESH :
- chemical , metabolism : Carbon, Membrane Transport Proteins, Nitrogen, Nitrogenase, Phosphorus, Plant Proteins.
- metabolism : Medicago truncatula, Mycorrhizae, Plant Roots.
- microbiology : Medicago truncatula, Plant Roots.
- physiology : Host Microbial Interactions, Medicago truncatula, Mycorrhizae.
- Symbiosis, Transcriptome.
Abstract
Legumes form tripartite interactions with arbuscular mycorrhizal fungi and rhizobia, and both root symbionts exchange nutrients against carbon from their host. The carbon costs of these interactions are substantial, but our current understanding of how the host controls its carbon allocation to individual root symbionts is limited. We examined nutrient uptake and carbon allocation in tripartite interactions of Medicago truncatula under different nutrient supply conditions, and when the fungal partner had access to nitrogen, and followed the gene expression of several plant transporters of the Sucrose Uptake Transporter (SUT) and Sugars Will Eventually be Exported Transporter (SWEET) family. Tripartite interactions led to synergistic growth responses and stimulated the phosphate and nitrogen uptake of the plant. Plant nutrient demand but also fungal access to nutrients played an important role for the carbon transport to different root symbionts, and the plant allocated more carbon to rhizobia under nitrogen demand, but more carbon to the fungal partner when nitrogen was available. These changes in carbon allocation were consistent with changes in the SUT and SWEET expression. Our study provides important insights into how the host plant controls its carbon allocation under different nutrient supply conditions and changes its carbon allocation to different root symbionts to maximize its symbiotic benefits.
DOI: 10.1111/pce.13359
PubMed: 29859016
Affiliations:
Links toward previous steps (curation, corpus...)
Le document en format XML
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Strahan</name><affiliation><nlm:affiliation>Eastern Regional Research Center, USDA, Agricultural Research Service, Wyndmoor, Pennslyvania.</nlm:affiliation><wicri:noCountry code="subField">Pennslyvania</wicri:noCountry></affiliation></author><author><name sortKey="Bucking, Heike" sort="Bucking, Heike" uniqKey="Bucking H" first="Heike" last="Bücking">Heike Bücking</name><affiliation wicri:level="2"><nlm:affiliation>South Dakota State University, Biology and Microbiology Department, Brookings, South Dakota.</nlm:affiliation><country xml:lang="fr">États-Unis</country><placeName><region type="state">Dakota du Sud</region></placeName><wicri:cityArea>South Dakota State University, Biology and Microbiology Department, Brookings</wicri:cityArea></affiliation></author></analytic><series><title level="j">Plant, cell & environment</title><idno type="eISSN">1365-3040</idno><imprint><date when="2019" type="published">2019</date></imprint></series></biblStruct></sourceDesc></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Carbon (metabolism)</term><term>Host Microbial Interactions (physiology)</term><term>Medicago truncatula (metabolism)</term><term>Medicago truncatula (microbiology)</term><term>Medicago truncatula (physiology)</term><term>Membrane Transport Proteins (metabolism)</term><term>Mycorrhizae (metabolism)</term><term>Mycorrhizae (physiology)</term><term>Nitrogen (metabolism)</term><term>Nitrogenase (metabolism)</term><term>Phosphorus (metabolism)</term><term>Plant Proteins (metabolism)</term><term>Plant Roots (metabolism)</term><term>Plant Roots (microbiology)</term><term>Symbiosis (MeSH)</term><term>Transcriptome (MeSH)</term></keywords><keywords scheme="KwdFr" xml:lang="fr"><term>Azote (métabolisme)</term><term>Carbone (métabolisme)</term><term>Interactions hôte-microbes (physiologie)</term><term>Medicago truncatula (microbiologie)</term><term>Medicago truncatula (métabolisme)</term><term>Medicago truncatula (physiologie)</term><term>Mycorhizes (métabolisme)</term><term>Mycorhizes (physiologie)</term><term>Nitrogenase (métabolisme)</term><term>Phosphore (métabolisme)</term><term>Protéines de transport membranaire (métabolisme)</term><term>Protéines végétales (métabolisme)</term><term>Racines de plante (microbiologie)</term><term>Racines de plante (métabolisme)</term><term>Symbiose (MeSH)</term><term>Transcriptome (MeSH)</term></keywords><keywords scheme="MESH" type="chemical" qualifier="metabolism" xml:lang="en"><term>Carbon</term><term>Membrane Transport Proteins</term><term>Nitrogen</term><term>Nitrogenase</term><term>Phosphorus</term><term>Plant Proteins</term></keywords><keywords scheme="MESH" qualifier="metabolism" xml:lang="en"><term>Medicago truncatula</term><term>Mycorrhizae</term><term>Plant Roots</term></keywords><keywords scheme="MESH" qualifier="microbiologie" xml:lang="fr"><term>Medicago truncatula</term><term>Racines de plante</term></keywords><keywords scheme="MESH" qualifier="microbiology" xml:lang="en"><term>Medicago truncatula</term><term>Plant Roots</term></keywords><keywords scheme="MESH" qualifier="métabolisme" xml:lang="fr"><term>Azote</term><term>Carbone</term><term>Medicago truncatula</term><term>Mycorhizes</term><term>Nitrogenase</term><term>Phosphore</term><term>Protéines de transport membranaire</term><term>Protéines végétales</term><term>Racines de plante</term></keywords><keywords scheme="MESH" qualifier="physiologie" xml:lang="fr"><term>Interactions hôte-microbes</term><term>Medicago truncatula</term><term>Mycorhizes</term></keywords><keywords scheme="MESH" qualifier="physiology" xml:lang="en"><term>Host Microbial Interactions</term><term>Medicago truncatula</term><term>Mycorrhizae</term></keywords><keywords scheme="MESH" xml:lang="en"><term>Symbiosis</term><term>Transcriptome</term></keywords><keywords scheme="MESH" xml:lang="fr"><term>Symbiose</term><term>Transcriptome</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Legumes form tripartite interactions with arbuscular mycorrhizal fungi and rhizobia, and both root symbionts exchange nutrients against carbon from their host. The carbon costs of these interactions are substantial, but our current understanding of how the host controls its carbon allocation to individual root symbionts is limited. We examined nutrient uptake and carbon allocation in tripartite interactions of Medicago truncatula under different nutrient supply conditions, and when the fungal partner had access to nitrogen, and followed the gene expression of several plant transporters of the Sucrose Uptake Transporter (SUT) and Sugars Will Eventually be Exported Transporter (SWEET) family. Tripartite interactions led to synergistic growth responses and stimulated the phosphate and nitrogen uptake of the plant. Plant nutrient demand but also fungal access to nutrients played an important role for the carbon transport to different root symbionts, and the plant allocated more carbon to rhizobia under nitrogen demand, but more carbon to the fungal partner when nitrogen was available. These changes in carbon allocation were consistent with changes in the SUT and SWEET expression. Our study provides important insights into how the host plant controls its carbon allocation under different nutrient supply conditions and changes its carbon allocation to different root symbionts to maximize its symbiotic benefits.</div></front></TEI><pubmed><MedlineCitation Status="MEDLINE" Owner="NLM"><PMID Version="1">29859016</PMID><DateCompleted><Year>2020</Year><Month>02</Month><Day>10</Day></DateCompleted><DateRevised><Year>2020</Year><Month>02</Month><Day>10</Day></DateRevised><Article PubModel="Print-Electronic"><Journal><ISSN IssnType="Electronic">1365-3040</ISSN><JournalIssue CitedMedium="Internet"><Volume>42</Volume><Issue>1</Issue><PubDate><Year>2019</Year><Month>01</Month></PubDate></JournalIssue><Title>Plant, cell & environment</Title><ISOAbbreviation>Plant Cell Environ</ISOAbbreviation></Journal><ArticleTitle>Nutrient demand and fungal access to resources control the carbon allocation to the symbiotic partners in tripartite interactions of Medicago truncatula.</ArticleTitle><Pagination><MedlinePgn>270-284</MedlinePgn></Pagination><ELocationID EIdType="doi" ValidYN="Y">10.1111/pce.13359</ELocationID><Abstract><AbstractText>Legumes form tripartite interactions with arbuscular mycorrhizal fungi and rhizobia, and both root symbionts exchange nutrients against carbon from their host. The carbon costs of these interactions are substantial, but our current understanding of how the host controls its carbon allocation to individual root symbionts is limited. We examined nutrient uptake and carbon allocation in tripartite interactions of Medicago truncatula under different nutrient supply conditions, and when the fungal partner had access to nitrogen, and followed the gene expression of several plant transporters of the Sucrose Uptake Transporter (SUT) and Sugars Will Eventually be Exported Transporter (SWEET) family. Tripartite interactions led to synergistic growth responses and stimulated the phosphate and nitrogen uptake of the plant. Plant nutrient demand but also fungal access to nutrients played an important role for the carbon transport to different root symbionts, and the plant allocated more carbon to rhizobia under nitrogen demand, but more carbon to the fungal partner when nitrogen was available. These changes in carbon allocation were consistent with changes in the SUT and SWEET expression. Our study provides important insights into how the host plant controls its carbon allocation under different nutrient supply conditions and changes its carbon allocation to different root symbionts to maximize its symbiotic benefits.</AbstractText><CopyrightInformation>© 2018 John Wiley & Sons Ltd.</CopyrightInformation></Abstract><AuthorList CompleteYN="Y"><Author ValidYN="Y"><LastName>Kafle</LastName><ForeName>Arjun</ForeName><Initials>A</Initials><AffiliationInfo><Affiliation>South Dakota State University, Biology and Microbiology Department, Brookings, South Dakota.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Garcia</LastName><ForeName>Kevin</ForeName><Initials>K</Initials><Identifier Source="ORCID">0000-0003-0821-1024</Identifier><AffiliationInfo><Affiliation>South Dakota State University, Biology and Microbiology Department, Brookings, South Dakota.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Wang</LastName><ForeName>Xiurong</ForeName><Initials>X</Initials><Identifier Source="ORCID">0000-0002-0699-8233</Identifier><AffiliationInfo><Affiliation>South Dakota State University, Biology and Microbiology Department, Brookings, South Dakota.</Affiliation></AffiliationInfo><AffiliationInfo><Affiliation>South China Agricultural University, State Key Laboratory for Conservation and Utilization of Subtropical Agro-Bioresources, Root Biology Center, Guangzhou, China.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Pfeffer</LastName><ForeName>Philip E</ForeName><Initials>PE</Initials><AffiliationInfo><Affiliation>Eastern Regional Research Center, USDA, Agricultural Research Service, Wyndmoor, Pennslyvania.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Strahan</LastName><ForeName>Gary D</ForeName><Initials>GD</Initials><AffiliationInfo><Affiliation>Eastern Regional Research Center, USDA, Agricultural Research Service, Wyndmoor, Pennslyvania.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Bücking</LastName><ForeName>Heike</ForeName><Initials>H</Initials><Identifier Source="ORCID">0000-0002-4040-0944</Identifier><AffiliationInfo><Affiliation>South Dakota State University, Biology and Microbiology Department, Brookings, South Dakota.</Affiliation></AffiliationInfo></Author></AuthorList><Language>eng</Language><PublicationTypeList><PublicationType UI="D016428">Journal Article</PublicationType><PublicationType UI="D013485">Research Support, Non-U.S. Gov't</PublicationType><PublicationType UI="D013486">Research Support, U.S. Gov't, Non-P.H.S.</PublicationType></PublicationTypeList><ArticleDate DateType="Electronic"><Year>2018</Year><Month>08</Month><Day>16</Day></ArticleDate></Article><MedlineJournalInfo><Country>United States</Country><MedlineTA>Plant Cell Environ</MedlineTA><NlmUniqueID>9309004</NlmUniqueID><ISSNLinking>0140-7791</ISSNLinking></MedlineJournalInfo><ChemicalList><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="D026901">Membrane Transport Proteins</NameOfSubstance></Chemical><Chemical><RegistryNumber>0</RegistryNumber><NameOfSubstance UI="D010940">Plant Proteins</NameOfSubstance></Chemical><Chemical><RegistryNumber>27YLU75U4W</RegistryNumber><NameOfSubstance UI="D010758">Phosphorus</NameOfSubstance></Chemical><Chemical><RegistryNumber>7440-44-0</RegistryNumber><NameOfSubstance UI="D002244">Carbon</NameOfSubstance></Chemical><Chemical><RegistryNumber>EC 1.18.6.1</RegistryNumber><NameOfSubstance UI="D009591">Nitrogenase</NameOfSubstance></Chemical><Chemical><RegistryNumber>N762921K75</RegistryNumber><NameOfSubstance UI="D009584">Nitrogen</NameOfSubstance></Chemical></ChemicalList><CitationSubset>IM</CitationSubset><MeshHeadingList><MeshHeading><DescriptorName UI="D002244" MajorTopicYN="N">Carbon</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="Y">metabolism</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D000076662" MajorTopicYN="Y">Host Microbial Interactions</DescriptorName><QualifierName UI="Q000502" MajorTopicYN="N">physiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D046913" MajorTopicYN="N">Medicago truncatula</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="Y">metabolism</QualifierName><QualifierName UI="Q000382" MajorTopicYN="N">microbiology</QualifierName><QualifierName UI="Q000502" MajorTopicYN="N">physiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D026901" MajorTopicYN="N">Membrane Transport Proteins</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="N">metabolism</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D038821" MajorTopicYN="N">Mycorrhizae</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="Y">metabolism</QualifierName><QualifierName UI="Q000502" MajorTopicYN="N">physiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D009584" MajorTopicYN="N">Nitrogen</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="N">metabolism</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D009591" MajorTopicYN="N">Nitrogenase</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="N">metabolism</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D010758" MajorTopicYN="N">Phosphorus</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="N">metabolism</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D010940" MajorTopicYN="N">Plant Proteins</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="N">metabolism</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D018517" MajorTopicYN="N">Plant Roots</DescriptorName><QualifierName UI="Q000378" MajorTopicYN="N">metabolism</QualifierName><QualifierName UI="Q000382" MajorTopicYN="N">microbiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D013559" MajorTopicYN="Y">Symbiosis</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D059467" MajorTopicYN="N">Transcriptome</DescriptorName></MeshHeading></MeshHeadingList><KeywordList Owner="NOTNLM"><Keyword MajorTopicYN="Y">Ensifer meliloti</Keyword><Keyword MajorTopicYN="Y">Rhizophagus irregularis</Keyword><Keyword MajorTopicYN="Y">arbuscular mycorrhizal symbiosis</Keyword><Keyword MajorTopicYN="Y">carbon transport</Keyword><Keyword MajorTopicYN="Y">legumes</Keyword><Keyword MajorTopicYN="Y">nitrogen uptake</Keyword><Keyword MajorTopicYN="Y">rhizobia</Keyword><Keyword MajorTopicYN="Y">sucrose transport</Keyword><Keyword MajorTopicYN="Y">sucrose uptake transporter (SUT)</Keyword><Keyword MajorTopicYN="Y">sugars will eventually be exported transporter (SWEET)</Keyword></KeywordList></MedlineCitation><PubmedData><History><PubMedPubDate PubStatus="received"><Year>2018</Year><Month>04</Month><Day>27</Day></PubMedPubDate><PubMedPubDate PubStatus="revised"><Year>2018</Year><Month>05</Month><Day>27</Day></PubMedPubDate><PubMedPubDate PubStatus="accepted"><Year>2018</Year><Month>05</Month><Day>28</Day></PubMedPubDate><PubMedPubDate PubStatus="pubmed"><Year>2018</Year><Month>6</Month><Day>3</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="medline"><Year>2020</Year><Month>2</Month><Day>11</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="entrez"><Year>2018</Year><Month>6</Month><Day>3</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate></History><PublicationStatus>ppublish</PublicationStatus><ArticleIdList><ArticleId IdType="pubmed">29859016</ArticleId><ArticleId IdType="doi">10.1111/pce.13359</ArticleId></ArticleIdList></PubmedData></pubmed><affiliations><list><country><li>République populaire de Chine</li><li>États-Unis</li></country><region><li>Dakota du Sud</li><li>Guangdong</li></region><settlement><li>Jiangmen</li></settlement></list><tree><noCountry><name sortKey="Pfeffer, Philip E" sort="Pfeffer, Philip E" uniqKey="Pfeffer P" first="Philip E" last="Pfeffer">Philip E. 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