Quantum Dots Reveal Shifts in Organic Nitrogen Uptake by Fungi Exposed to Long-Term Nitrogen Enrichment

Anthropogenic nitrogen (N) enrichment can alter N dynamics associated with decomposing plant litter. However, it is unclear to what extent these alterations occur via microbial effects (e.g., changes in gene regulation, physiology, or community composition) versus plant litter effects (e.g., changes...

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Veröffentlicht in:	PloS one 2015-09, Vol.10 (9), p.e0138158-e0138158
Hauptverfasser:	Hynson, Nicole A, Allison, Steven D, Treseder, Kathleen K
Format:	Artikel
Sprache:	eng
Schlagworte:	Anthropogenic factors Biochemistry Chitosan Chitosan - metabolism Community composition Composition effects Decomposition Ecology Ecosystem Ecosystem biology Ecosystems Enrichment Environmental changes Environmental conditions ENVIRONMENTAL SCIENCES Enzymes Evolutionary biology Fertilization fungal genetics fungal pathogens fungal physiology Fungi Fungi - metabolism Gene expression Gene regulation Glycine Glycine - metabolism Hypotheses Laboratories Litter microbial physiology Microorganisms Molecular biology Nitrogen Nitrogen - metabolism Nitrogen enrichment Organic nitrogen Physiological aspects Physiology Plant communities plant physiology Quantum dots Quantum Dots - chemistry Soil Soil Microbiology Studies Yeast
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description	Anthropogenic nitrogen (N) enrichment can alter N dynamics associated with decomposing plant litter. However, it is unclear to what extent these alterations occur via microbial effects (e.g., changes in gene regulation, physiology, or community composition) versus plant litter effects (e.g., changes in composition of N and C compounds). To isolate microbial effects from plant litter effects, we collected plant litter from long-term N fertilized and control plots, reciprocally inoculated it with microbes from the two treatments, and incubated it in a common field setting for three months. We used quantum dots (QDs) to track fungal uptake of glycine and chitosan. Glycine is a relatively simple organic N compound; chitosan is more complex. We found that microbial and litter origins each contributed to a shift in fungal uptake capacities under N fertilization. Specifically, N fungi preferred glycine over chitosan, but control fungi did not. In comparison, litter effects were more subtle, and manifested as a three-way interaction between litter origin, microbial origin, and type of organic N (glycine versus chitosan). In particular, control fungi tended to target chitosan only when incubated with control litter, while N fungi targeted glycine regardless of litter type. Overall, microbial effects may mediate how N dynamics respond to anthropogenic N enrichment in ecosystems.
doi_str_mv	10.1371/journal.pone.0138158
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However, it is unclear to what extent these alterations occur via microbial effects (e.g., changes in gene regulation, physiology, or community composition) versus plant litter effects (e.g., changes in composition of N and C compounds). To isolate microbial effects from plant litter effects, we collected plant litter from long-term N fertilized and control plots, reciprocally inoculated it with microbes from the two treatments, and incubated it in a common field setting for three months. We used quantum dots (QDs) to track fungal uptake of glycine and chitosan. Glycine is a relatively simple organic N compound; chitosan is more complex. We found that microbial and litter origins each contributed to a shift in fungal uptake capacities under N fertilization. Specifically, N fungi preferred glycine over chitosan, but control fungi did not. In comparison, litter effects were more subtle, and manifested as a three-way interaction between litter origin, microbial origin, and type of organic N (glycine versus chitosan). In particular, control fungi tended to target chitosan only when incubated with control litter, while N fungi targeted glycine regardless of litter type. 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metabolism</topic><topic>Community composition</topic><topic>Composition effects</topic><topic>Decomposition</topic><topic>Ecology</topic><topic>Ecosystem</topic><topic>Ecosystem biology</topic><topic>Ecosystems</topic><topic>Enrichment</topic><topic>Environmental changes</topic><topic>Environmental conditions</topic><topic>ENVIRONMENTAL SCIENCES</topic><topic>Enzymes</topic><topic>Evolutionary biology</topic><topic>Fertilization</topic><topic>fungal genetics</topic><topic>fungal pathogens</topic><topic>fungal physiology</topic><topic>Fungi</topic><topic>Fungi - metabolism</topic><topic>Gene expression</topic><topic>Gene regulation</topic><topic>Glycine</topic><topic>Glycine - metabolism</topic><topic>Hypotheses</topic><topic>Laboratories</topic><topic>Litter</topic><topic>microbial physiology</topic><topic>Microorganisms</topic><topic>Molecular biology</topic><topic>Nitrogen</topic><topic>Nitrogen - metabolism</topic><topic>Nitrogen enrichment</topic><topic>Organic nitrogen</topic><topic>Physiological aspects</topic><topic>Physiology</topic><topic>Plant communities</topic><topic>plant physiology</topic><topic>Quantum dots</topic><topic>Quantum Dots - 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However, it is unclear to what extent these alterations occur via microbial effects (e.g., changes in gene regulation, physiology, or community composition) versus plant litter effects (e.g., changes in composition of N and C compounds). To isolate microbial effects from plant litter effects, we collected plant litter from long-term N fertilized and control plots, reciprocally inoculated it with microbes from the two treatments, and incubated it in a common field setting for three months. We used quantum dots (QDs) to track fungal uptake of glycine and chitosan. Glycine is a relatively simple organic N compound; chitosan is more complex. We found that microbial and litter origins each contributed to a shift in fungal uptake capacities under N fertilization. Specifically, N fungi preferred glycine over chitosan, but control fungi did not. In comparison, litter effects were more subtle, and manifested as a three-way interaction between litter origin, microbial origin, and type of organic N (glycine versus chitosan). In particular, control fungi tended to target chitosan only when incubated with control litter, while N fungi targeted glycine regardless of litter type. Overall, microbial effects may mediate how N dynamics respond to anthropogenic N enrichment in ecosystems.</abstract><cop>United States</cop><pub>Public Library of Science</pub><pmid>26367868</pmid><doi>10.1371/journal.pone.0138158</doi><tpages>e0138158</tpages><oa>free_for_read</oa></addata></record>
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subjects	Anthropogenic factors Biochemistry Chitosan Chitosan - metabolism Community composition Composition effects Decomposition Ecology Ecosystem Ecosystem biology Ecosystems Enrichment Environmental changes Environmental conditions ENVIRONMENTAL SCIENCES Enzymes Evolutionary biology Fertilization fungal genetics fungal pathogens fungal physiology Fungi Fungi - metabolism Gene expression Gene regulation Glycine Glycine - metabolism Hypotheses Laboratories Litter microbial physiology Microorganisms Molecular biology Nitrogen Nitrogen - metabolism Nitrogen enrichment Organic nitrogen Physiological aspects Physiology Plant communities plant physiology Quantum dots Quantum Dots - chemistry Soil Soil Microbiology Studies Yeast
title	Quantum Dots Reveal Shifts in Organic Nitrogen Uptake by Fungi Exposed to Long-Term Nitrogen Enrichment
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