Reduced snow cover alters root-microbe interactions and decreases nitrification rates in a northern hardwood forest.
Identifieur interne : 000153 ( Main/Exploration ); précédent : 000152; suivant : 000154Reduced snow cover alters root-microbe interactions and decreases nitrification rates in a northern hardwood forest.
Auteurs : Patrick O. Sorensen [États-Unis] ; Pamela H. Templer [États-Unis] ; Lynn Christenson [États-Unis] ; Jorge Duran [Portugal] ; Timothy Fahey [États-Unis] ; Melany C. Fisk [États-Unis] ; Peter M. Groffman [États-Unis] ; Jennifer L. Morse [États-Unis] ; Adrien C. Finzi [États-Unis]Source :
- Ecology [ 0012-9658 ] ; 2016.
Descripteurs français
- KwdFr :
- MESH :
- croissance et développement : Acer, Racines de plante.
- microbiologie : Acer, Racines de plante.
- Forêts, Neige, Nitrification.
English descriptors
- KwdEn :
- MESH :
- growth & development : Acer, Plant Roots.
- microbiology : Acer, Plant Roots.
- Forests, Nitrification, Snow.
Abstract
Snow cover is projected to decline during the next century in many ecosystems that currently experience a seasonal snowpack. Because snow insulates soils from frigid winter air temperatures, soils are expected to become colder and experience more winter soil freeze-thaw cycles as snow cover continues to decline. Tree roots are adversely affected by snowpack reduction, but whether loss of snow will affect root-microbe interactions remains largely unknown. The objective of this study was to distinguish and attribute direct (e.g., winter snow- and/or soil frost-mediated) vs. indirect (e.g., root-mediated) effects of winter climate change on microbial biomass, the potential activity of microbial exoenzymes, and net N mineralization and nitrification rates. Soil cores were incubated in situ in nylon mesh that either allowed roots to grow into the soil core (2 mm pore size) or excluded root ingrowth (50 μm pore size) for up to 29 months along a natural winter climate gradient at Hubbard Brook Experimental Forest, NH (USA). Microbial biomass did not differ among ingrowth or exclusion cores. Across sampling dates, the potential activities of cellobiohydrolase, phenol oxidase, and peroxidase, and net N mineralization rates were more strongly related to soil volumetric water content (P < 0.05; R2 = 0.25-0.46) than to root biomass, snow or soil frost, or winter soil temperature (R2 < 0.10). Root ingrowth was positively related to soil frost (P < 0.01; R2 = 0.28), suggesting that trees compensate for overwinter root mortality caused by soil freezing by re-allocating resources towards root production. At the sites with the deepest snow cover, root ingrowth reduced nitrification rates by 30% (P < 0.01), showing that tree roots exert significant influence over nitrification, which declines with reduced snow cover. If soil freezing intensifies over time, then greater compensatory root growth may reduce nitrification rates directly via plant-microbe N competition and indirectly through a negative feedback on soil moisture, resulting in lower N availability to trees in northern hardwood forests.
DOI: 10.1002/ecy.1599
PubMed: 27912011
Affiliations:
- Portugal, États-Unis
- Massachusetts, Ohio, Oregon, État de New York
- Ithaca (New York)
- Université Cornell
Links toward previous steps (curation, corpus...)
Le document en format XML
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Sorensen</name><affiliation wicri:level="2"><nlm:affiliation>Department of Biology, Boston University, Boston, Massachusetts, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Biology, Boston University, Boston, Massachusetts</wicri:regionArea><placeName><region type="state">Massachusetts</region></placeName></affiliation></author><author><name sortKey="Templer, Pamela H" sort="Templer, Pamela H" uniqKey="Templer P" first="Pamela H" last="Templer">Pamela H. Templer</name><affiliation wicri:level="2"><nlm:affiliation>Department of Biology, Boston University, Boston, Massachusetts, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Biology, Boston University, Boston, Massachusetts</wicri:regionArea><placeName><region type="state">Massachusetts</region></placeName></affiliation></author><author><name sortKey="Christenson, Lynn" sort="Christenson, Lynn" uniqKey="Christenson L" first="Lynn" last="Christenson">Lynn Christenson</name><affiliation wicri:level="2"><nlm:affiliation>Biology Department, Vassar College, Poughkeepsie, New York, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Biology Department, Vassar College, Poughkeepsie, New York</wicri:regionArea><placeName><region type="state">État de New York</region></placeName></affiliation></author><author><name sortKey="Duran, Jorge" sort="Duran, Jorge" uniqKey="Duran J" first="Jorge" last="Duran">Jorge Duran</name><affiliation wicri:level="1"><nlm:affiliation>Center for Functional Ecology, Department of Life Sciences, University of Coimbra, Coimbra, Portugal.</nlm:affiliation><country xml:lang="fr">Portugal</country><wicri:regionArea>Center for Functional Ecology, Department of Life Sciences, University of Coimbra, Coimbra</wicri:regionArea><wicri:noRegion>Coimbra</wicri:noRegion></affiliation></author><author><name sortKey="Fahey, Timothy" sort="Fahey, Timothy" uniqKey="Fahey T" first="Timothy" last="Fahey">Timothy Fahey</name><affiliation wicri:level="4"><nlm:affiliation>Department of Natural Resources, Cornell University, Ithaca, New York, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Natural Resources, Cornell University, Ithaca, New York</wicri:regionArea><placeName><region type="state">État de New York</region><settlement type="city">Ithaca (New York)</settlement></placeName><orgName type="university">Université Cornell</orgName></affiliation></author><author><name sortKey="Fisk, Melany C" sort="Fisk, Melany C" uniqKey="Fisk M" first="Melany C" last="Fisk">Melany C. Fisk</name><affiliation wicri:level="2"><nlm:affiliation>Department of Biology, Miami University, Oxford, Ohio, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Biology, Miami University, Oxford, Ohio</wicri:regionArea><placeName><region type="state">Ohio</region></placeName></affiliation></author><author><name sortKey="Groffman, Peter M" sort="Groffman, Peter M" uniqKey="Groffman P" first="Peter M" last="Groffman">Peter M. Groffman</name><affiliation wicri:level="2"><nlm:affiliation>Department of Earth and Environmental Sciences, Brooklyn College, City University of New York Advanced Science Research Center, New York, New York, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Earth and Environmental Sciences, Brooklyn College, City University of New York Advanced Science Research Center, New York, New York</wicri:regionArea><placeName><region type="state">État de New York</region></placeName></affiliation></author><author><name sortKey="Morse, Jennifer L" sort="Morse, Jennifer L" uniqKey="Morse J" first="Jennifer L" last="Morse">Jennifer L. Morse</name><affiliation wicri:level="2"><nlm:affiliation>Department of Environmental Science and Management, Portland State University, Portland, Oregon, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Environmental Science and Management, Portland State University, Portland, Oregon</wicri:regionArea><placeName><region type="state">Oregon</region></placeName></affiliation></author><author><name sortKey="Finzi, Adrien C" sort="Finzi, Adrien C" uniqKey="Finzi A" first="Adrien C" last="Finzi">Adrien C. Finzi</name><affiliation wicri:level="2"><nlm:affiliation>Department of Biology, Boston University, Boston, Massachusetts, USA.</nlm:affiliation><country xml:lang="fr">États-Unis</country><wicri:regionArea>Department of Biology, Boston University, Boston, Massachusetts</wicri:regionArea><placeName><region type="state">Massachusetts</region></placeName></affiliation></author></analytic><series><title level="j">Ecology</title><idno type="ISSN">0012-9658</idno><imprint><date when="2016" type="published">2016</date></imprint></series></biblStruct></sourceDesc></fileDesc><profileDesc><textClass><keywords scheme="KwdEn" xml:lang="en"><term>Acer (growth & development)</term><term>Acer (microbiology)</term><term>Forests (MeSH)</term><term>Nitrification (MeSH)</term><term>Plant Roots (growth & development)</term><term>Plant Roots (microbiology)</term><term>Snow (MeSH)</term></keywords><keywords scheme="KwdFr" xml:lang="fr"><term>Acer (croissance et développement)</term><term>Acer (microbiologie)</term><term>Forêts (MeSH)</term><term>Neige (MeSH)</term><term>Nitrification (MeSH)</term><term>Racines de plante (croissance et développement)</term><term>Racines de plante (microbiologie)</term></keywords><keywords scheme="MESH" qualifier="croissance et développement" xml:lang="fr"><term>Acer</term><term>Racines de plante</term></keywords><keywords scheme="MESH" qualifier="growth & development" xml:lang="en"><term>Acer</term><term>Plant Roots</term></keywords><keywords scheme="MESH" qualifier="microbiologie" xml:lang="fr"><term>Acer</term><term>Racines de plante</term></keywords><keywords scheme="MESH" qualifier="microbiology" xml:lang="en"><term>Acer</term><term>Plant Roots</term></keywords><keywords scheme="MESH" xml:lang="en"><term>Forests</term><term>Nitrification</term><term>Snow</term></keywords><keywords scheme="MESH" xml:lang="fr"><term>Forêts</term><term>Neige</term><term>Nitrification</term></keywords></textClass></profileDesc></teiHeader><front><div type="abstract" xml:lang="en">Snow cover is projected to decline during the next century in many ecosystems that currently experience a seasonal snowpack. Because snow insulates soils from frigid winter air temperatures, soils are expected to become colder and experience more winter soil freeze-thaw cycles as snow cover continues to decline. Tree roots are adversely affected by snowpack reduction, but whether loss of snow will affect root-microbe interactions remains largely unknown. The objective of this study was to distinguish and attribute direct (e.g., winter snow- and/or soil frost-mediated) vs. indirect (e.g., root-mediated) effects of winter climate change on microbial biomass, the potential activity of microbial exoenzymes, and net N mineralization and nitrification rates. Soil cores were incubated in situ in nylon mesh that either allowed roots to grow into the soil core (2 mm pore size) or excluded root ingrowth (50 μm pore size) for up to 29 months along a natural winter climate gradient at Hubbard Brook Experimental Forest, NH (USA). Microbial biomass did not differ among ingrowth or exclusion cores. Across sampling dates, the potential activities of cellobiohydrolase, phenol oxidase, and peroxidase, and net N mineralization rates were more strongly related to soil volumetric water content (P < 0.05; R<sup>2 </sup> = 0.25-0.46) than to root biomass, snow or soil frost, or winter soil temperature (R<sup>2 </sup> < 0.10). Root ingrowth was positively related to soil frost (P < 0.01; R<sup>2</sup> = 0.28), suggesting that trees compensate for overwinter root mortality caused by soil freezing by re-allocating resources towards root production. At the sites with the deepest snow cover, root ingrowth reduced nitrification rates by 30% (P < 0.01), showing that tree roots exert significant influence over nitrification, which declines with reduced snow cover. If soil freezing intensifies over time, then greater compensatory root growth may reduce nitrification rates directly via plant-microbe N competition and indirectly through a negative feedback on soil moisture, resulting in lower N availability to trees in northern hardwood forests.</div></front></TEI><pubmed><MedlineCitation Status="MEDLINE" Owner="NLM"><PMID Version="1">27912011</PMID><DateCompleted><Year>2017</Year><Month>06</Month><Day>02</Day></DateCompleted><DateRevised><Year>2017</Year><Month>06</Month><Day>02</Day></DateRevised><Article PubModel="Print"><Journal><ISSN IssnType="Print">0012-9658</ISSN><JournalIssue CitedMedium="Print"><Volume>97</Volume><Issue>12</Issue><PubDate><Year>2016</Year><Month>Dec</Month></PubDate></JournalIssue><Title>Ecology</Title><ISOAbbreviation>Ecology</ISOAbbreviation></Journal><ArticleTitle>Reduced snow cover alters root-microbe interactions and decreases nitrification rates in a northern hardwood forest.</ArticleTitle><Pagination><MedlinePgn>3359-3368</MedlinePgn></Pagination><ELocationID EIdType="doi" ValidYN="Y">10.1002/ecy.1599</ELocationID><Abstract><AbstractText>Snow cover is projected to decline during the next century in many ecosystems that currently experience a seasonal snowpack. Because snow insulates soils from frigid winter air temperatures, soils are expected to become colder and experience more winter soil freeze-thaw cycles as snow cover continues to decline. Tree roots are adversely affected by snowpack reduction, but whether loss of snow will affect root-microbe interactions remains largely unknown. The objective of this study was to distinguish and attribute direct (e.g., winter snow- and/or soil frost-mediated) vs. indirect (e.g., root-mediated) effects of winter climate change on microbial biomass, the potential activity of microbial exoenzymes, and net N mineralization and nitrification rates. Soil cores were incubated in situ in nylon mesh that either allowed roots to grow into the soil core (2 mm pore size) or excluded root ingrowth (50 μm pore size) for up to 29 months along a natural winter climate gradient at Hubbard Brook Experimental Forest, NH (USA). Microbial biomass did not differ among ingrowth or exclusion cores. Across sampling dates, the potential activities of cellobiohydrolase, phenol oxidase, and peroxidase, and net N mineralization rates were more strongly related to soil volumetric water content (P < 0.05; R<sup>2 </sup> = 0.25-0.46) than to root biomass, snow or soil frost, or winter soil temperature (R<sup>2 </sup> < 0.10). Root ingrowth was positively related to soil frost (P < 0.01; R<sup>2</sup> = 0.28), suggesting that trees compensate for overwinter root mortality caused by soil freezing by re-allocating resources towards root production. At the sites with the deepest snow cover, root ingrowth reduced nitrification rates by 30% (P < 0.01), showing that tree roots exert significant influence over nitrification, which declines with reduced snow cover. If soil freezing intensifies over time, then greater compensatory root growth may reduce nitrification rates directly via plant-microbe N competition and indirectly through a negative feedback on soil moisture, resulting in lower N availability to trees in northern hardwood forests.</AbstractText><CopyrightInformation>© 2016 by the Ecological Society of America.</CopyrightInformation></Abstract><AuthorList CompleteYN="Y"><Author ValidYN="Y"><LastName>Sorensen</LastName><ForeName>Patrick O</ForeName><Initials>PO</Initials><AffiliationInfo><Affiliation>Department of Biology, Boston University, Boston, Massachusetts, USA.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Templer</LastName><ForeName>Pamela H</ForeName><Initials>PH</Initials><AffiliationInfo><Affiliation>Department of Biology, Boston University, Boston, Massachusetts, USA.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Christenson</LastName><ForeName>Lynn</ForeName><Initials>L</Initials><AffiliationInfo><Affiliation>Biology Department, Vassar College, Poughkeepsie, New York, USA.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Duran</LastName><ForeName>Jorge</ForeName><Initials>J</Initials><AffiliationInfo><Affiliation>Center for Functional Ecology, Department of Life Sciences, University of Coimbra, Coimbra, Portugal.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Fahey</LastName><ForeName>Timothy</ForeName><Initials>T</Initials><AffiliationInfo><Affiliation>Department of Natural Resources, Cornell University, Ithaca, New York, USA.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Fisk</LastName><ForeName>Melany C</ForeName><Initials>MC</Initials><AffiliationInfo><Affiliation>Department of Biology, Miami University, Oxford, Ohio, USA.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Groffman</LastName><ForeName>Peter M</ForeName><Initials>PM</Initials><AffiliationInfo><Affiliation>Department of Earth and Environmental Sciences, Brooklyn College, City University of New York Advanced Science Research Center, New York, New York, USA.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Morse</LastName><ForeName>Jennifer L</ForeName><Initials>JL</Initials><AffiliationInfo><Affiliation>Department of Environmental Science and Management, Portland State University, Portland, Oregon, USA.</Affiliation></AffiliationInfo></Author><Author ValidYN="Y"><LastName>Finzi</LastName><ForeName>Adrien C</ForeName><Initials>AC</Initials><AffiliationInfo><Affiliation>Department of Biology, Boston University, Boston, Massachusetts, USA.</Affiliation></AffiliationInfo></Author></AuthorList><Language>eng</Language><PublicationTypeList><PublicationType UI="D016428">Journal Article</PublicationType></PublicationTypeList></Article><MedlineJournalInfo><Country>United States</Country><MedlineTA>Ecology</MedlineTA><NlmUniqueID>0043541</NlmUniqueID><ISSNLinking>0012-9658</ISSNLinking></MedlineJournalInfo><CitationSubset>IM</CitationSubset><MeshHeadingList><MeshHeading><DescriptorName UI="D031002" MajorTopicYN="N">Acer</DescriptorName><QualifierName UI="Q000254" MajorTopicYN="N">growth & development</QualifierName><QualifierName UI="Q000382" MajorTopicYN="Y">microbiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D065928" MajorTopicYN="Y">Forests</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D058465" MajorTopicYN="N">Nitrification</DescriptorName></MeshHeading><MeshHeading><DescriptorName UI="D018517" MajorTopicYN="N">Plant Roots</DescriptorName><QualifierName UI="Q000254" MajorTopicYN="N">growth & development</QualifierName><QualifierName UI="Q000382" MajorTopicYN="Y">microbiology</QualifierName></MeshHeading><MeshHeading><DescriptorName UI="D012914" MajorTopicYN="Y">Snow</DescriptorName></MeshHeading></MeshHeadingList><KeywordList Owner="NOTNLM"><Keyword MajorTopicYN="Y">Hubbard Brook</Keyword><Keyword MajorTopicYN="Y">nitrification</Keyword><Keyword MajorTopicYN="Y">phenol oxidase</Keyword><Keyword MajorTopicYN="Y">root production</Keyword><Keyword MajorTopicYN="Y">snow</Keyword><Keyword MajorTopicYN="Y">soil frost</Keyword><Keyword MajorTopicYN="Y">sugar maple (Acer saccharum)</Keyword></KeywordList></MedlineCitation><PubmedData><History><PubMedPubDate PubStatus="received"><Year>2016</Year><Month>02</Month><Day>04</Day></PubMedPubDate><PubMedPubDate PubStatus="revised"><Year>2016</Year><Month>08</Month><Day>22</Day></PubMedPubDate><PubMedPubDate PubStatus="accepted"><Year>2016</Year><Month>09</Month><Day>14</Day></PubMedPubDate><PubMedPubDate PubStatus="entrez"><Year>2016</Year><Month>12</Month><Day>3</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="pubmed"><Year>2016</Year><Month>12</Month><Day>3</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate><PubMedPubDate PubStatus="medline"><Year>2017</Year><Month>6</Month><Day>3</Day><Hour>6</Hour><Minute>0</Minute></PubMedPubDate></History><PublicationStatus>ppublish</PublicationStatus><ArticleIdList><ArticleId IdType="pubmed">27912011</ArticleId><ArticleId IdType="doi">10.1002/ecy.1599</ArticleId></ArticleIdList></PubmedData></pubmed><affiliations><list><country><li>Portugal</li><li>États-Unis</li></country><region><li>Massachusetts</li><li>Ohio</li><li>Oregon</li><li>État de New York</li></region><settlement><li>Ithaca (New York)</li></settlement><orgName><li>Université Cornell</li></orgName></list><tree><country name="États-Unis"><region name="Massachusetts"><name sortKey="Sorensen, Patrick O" sort="Sorensen, Patrick O" uniqKey="Sorensen P" first="Patrick O" last="Sorensen">Patrick O. Sorensen</name></region><name sortKey="Christenson, Lynn" sort="Christenson, Lynn" uniqKey="Christenson L" first="Lynn" last="Christenson">Lynn Christenson</name><name sortKey="Fahey, Timothy" sort="Fahey, Timothy" uniqKey="Fahey T" first="Timothy" last="Fahey">Timothy Fahey</name><name sortKey="Finzi, Adrien C" sort="Finzi, Adrien C" uniqKey="Finzi A" first="Adrien C" last="Finzi">Adrien C. Finzi</name><name sortKey="Fisk, Melany C" sort="Fisk, Melany C" uniqKey="Fisk M" first="Melany C" last="Fisk">Melany C. Fisk</name><name sortKey="Groffman, Peter M" sort="Groffman, Peter M" uniqKey="Groffman P" first="Peter M" last="Groffman">Peter M. Groffman</name><name sortKey="Morse, Jennifer L" sort="Morse, Jennifer L" uniqKey="Morse J" first="Jennifer L" last="Morse">Jennifer L. Morse</name><name sortKey="Templer, Pamela H" sort="Templer, Pamela H" uniqKey="Templer P" first="Pamela H" last="Templer">Pamela H. Templer</name></country><country name="Portugal"><noRegion><name sortKey="Duran, Jorge" sort="Duran, Jorge" uniqKey="Duran J" first="Jorge" last="Duran">Jorge Duran</name></noRegion></country></tree></affiliations></record>Pour manipuler ce document sous Unix (Dilib)
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