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Auteurs principaux: Zhao, Sharon, Krichels, Alexander H, Stephens, Elizah Z, Calma, Anthony D, Aronson, Emma L, Jenerette, G Darrel, Spasojevic, Marko J, Schimel, Joshua P, Hanan, Erin J, Homyak, Peter M
Format: Artículo científico
Langue:en
Publié: Global change biology 2025
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Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/40145597/
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author Zhao, Sharon
Krichels, Alexander H
Stephens, Elizah Z
Calma, Anthony D
Aronson, Emma L
Jenerette, G Darrel
Spasojevic, Marko J
Schimel, Joshua P
Hanan, Erin J
Homyak, Peter M
author_facet Zhao, Sharon
Krichels, Alexander H
Stephens, Elizah Z
Calma, Anthony D
Aronson, Emma L
Jenerette, G Darrel
Spasojevic, Marko J
Schimel, Joshua P
Hanan, Erin J
Homyak, Peter M
Zhao, Sharon
Krichels, Alexander H
Stephens, Elizah Z
Calma, Anthony D
Aronson, Emma L
Jenerette, G Darrel
Spasojevic, Marko J
Schimel, Joshua P
Hanan, Erin J
Homyak, Peter M
collection PubMed - marine biology
contents Nitrogen Availability and Changes in Precipitation Alter Microbially Mediated NO and NO Emissions From a Pinyon-Juniper Dryland. Zhao, Sharon Krichels, Alexander H Stephens, Elizah Z Calma, Anthony D Aronson, Emma L Jenerette, G Darrel Spasojevic, Marko J Schimel, Joshua P Hanan, Erin J Homyak, Peter M Nitrous Oxide Nitrogen Nitric Oxide Seasons Climate Change Soil Rain Archaea Soil Microbiology Bacteria Air Pollutants Climate change is altering precipitation regimes that control nitrogen (N) cycling in terrestrial ecosystems. In ecosystems exposed to frequent drought, N can accumulate in soils as they dry, stimulating the emission of both nitric oxide (NO; an air pollutant at high concentrations) and nitrous oxide (NO; a powerful greenhouse gas) when the dry soils wet up. Because changes in both N availability and soil moisture can alter the capacity of nitrifying organisms such as ammonia-oxidizing bacteria (AOB) and archaea (AOA) to process N and emit N gases, predicting whether shifts in precipitation may alter NO and NO emissions requires understanding how both AOA and AOB may respond. Thus, we ask: How does altering summer and winter precipitation affect nitrifier-derived N trace gas emissions in a dryland ecosystem? To answer this question, we manipulated summer and winter precipitation and measured AOA- and AOB-derived N trace gas emissions, AOA and AOB abundance, and soil N concentrations. We found that excluding summer precipitation increased AOB-derived NO emissions, consistent with the increase in soil N availability, and that increasing summer precipitation amount promoted AOB activity. Excluding precipitation in the winter (the most extreme water limitation we imposed) did not alter nitrifier-derived NO emissions despite N accumulating in soils. Instead, nitrate that accumulated under drought correlated with high NO emission via denitrification upon wetting dry soils. Increases in the timing and intensity of precipitation that are forecasted under climate change may, therefore, influence the emission of N gases according to the magnitude and season during which the changes occur.
format Artículo científico
id pubmed_40145597
institution PubMed
language en
publishDate 2025
publisher Global change biology
record_format pubmed
spellingShingle Nitrogen Availability and Changes in Precipitation Alter Microbially Mediated NO and NO Emissions From a Pinyon-Juniper Dryland.
Zhao, Sharon
Krichels, Alexander H
Stephens, Elizah Z
Calma, Anthony D
Aronson, Emma L
Jenerette, G Darrel
Spasojevic, Marko J
Schimel, Joshua P
Hanan, Erin J
Homyak, Peter M
Nitrous Oxide
Nitrogen
Nitric Oxide
Seasons
Climate Change
Soil
Rain
Archaea
Soil Microbiology
Bacteria
Air Pollutants
Nitrogen Availability and Changes in Precipitation Alter Microbially Mediated NO and NO Emissions From a Pinyon-Juniper Dryland. Zhao, Sharon Krichels, Alexander H Stephens, Elizah Z Calma, Anthony D Aronson, Emma L Jenerette, G Darrel Spasojevic, Marko J Schimel, Joshua P Hanan, Erin J Homyak, Peter M Nitrous Oxide Nitrogen Nitric Oxide Seasons Climate Change Soil Rain Archaea Soil Microbiology Bacteria Air Pollutants Climate change is altering precipitation regimes that control nitrogen (N) cycling in terrestrial ecosystems. In ecosystems exposed to frequent drought, N can accumulate in soils as they dry, stimulating the emission of both nitric oxide (NO; an air pollutant at high concentrations) and nitrous oxide (NO; a powerful greenhouse gas) when the dry soils wet up. Because changes in both N availability and soil moisture can alter the capacity of nitrifying organisms such as ammonia-oxidizing bacteria (AOB) and archaea (AOA) to process N and emit N gases, predicting whether shifts in precipitation may alter NO and NO emissions requires understanding how both AOA and AOB may respond. Thus, we ask: How does altering summer and winter precipitation affect nitrifier-derived N trace gas emissions in a dryland ecosystem? To answer this question, we manipulated summer and winter precipitation and measured AOA- and AOB-derived N trace gas emissions, AOA and AOB abundance, and soil N concentrations. We found that excluding summer precipitation increased AOB-derived NO emissions, consistent with the increase in soil N availability, and that increasing summer precipitation amount promoted AOB activity. Excluding precipitation in the winter (the most extreme water limitation we imposed) did not alter nitrifier-derived NO emissions despite N accumulating in soils. Instead, nitrate that accumulated under drought correlated with high NO emission via denitrification upon wetting dry soils. Increases in the timing and intensity of precipitation that are forecasted under climate change may, therefore, influence the emission of N gases according to the magnitude and season during which the changes occur.
title Nitrogen Availability and Changes in Precipitation Alter Microbially Mediated NO and NO Emissions From a Pinyon-Juniper Dryland.
topic Nitrous Oxide
Nitrogen
Nitric Oxide
Seasons
Climate Change
Soil
Rain
Archaea
Soil Microbiology
Bacteria
Air Pollutants
url https://pubmed.ncbi.nlm.nih.gov/40145597/