Nitrous oxide production by ammonia oxidizers: Physiological diversity, niche differentiation and potential mitigation strategies

Prosser, James I.; Hink, Linda; Gubry‐Rangin, Cécile; Nicol, Graeme W.

doi:10.1111/gcb.14877

Cited by 309 publications

(190 citation statements)

References 148 publications

(336 reference statements)

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“…We further reveal that AOB was more abundant than AOA in Wheat-Corn soils. AOB is favoured by inorganic fertilization and produces high N 2 O emission, whilst AOA is favoured by organic or slow-release fertilizer, yielding lower N 2 O emission [40]. Together, we deduce that Wheat-Corn soils have higher N 2 O emissions and consequently lower fertilizer use efficiency.…”

Section: Abundance and Diversity Of Chosen N-cycling Functional Genesmentioning

confidence: 75%

The Structure and Diversity of Nitrogen Functional Groups from Different Cropping Systems in Yellow River Delta

Miao

Zhang

et al. 2020

Microorganisms

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The Yellow River Delta (YRD) region is an important production base in Shandong Province. It encompasses an array of diversified crop systems, including the corn–wheat rotation system (Wheat–Corn), soybean–corn rotation system (Soybean–Corn), fruits or vegetables system (Fruit), cotton system (Cotton) and rice system (Rice). In this study, the communities of ammonia oxidizer–, denitrifier– and nitrogen (N)–fixing bacteria in those cropping systems were investigated by Illumina Miseq sequencing. We found that Rice soil exhibited significantly higher diversity indices of investigated N–cycling microbial communities than other crop soils, possibly due to its high soil water content. Wheat–Corn soils had higher abundances of nitrification gene amoA and denitrification genes nirK and nirS, and exhibited higher soil potential nitrification rate (PNR), compared with Soybean–Corn, Cotton and Fruit soils. Consistently, redundancy analysis (RDA) showed that soil water content (SWC), electrical conductivity (EC), and total nitrogen (TN) were the most important influencing factors of the diversity and structure of the investigated N–cycling microbial.

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Section: Abundance and Diversity Of Chosen N-cycling Functional Genesmentioning

confidence: 75%

The Structure and Diversity of Nitrogen Functional Groups from Different Cropping Systems in Yellow River Delta

Miao

Zhang

et al. 2020

Microorganisms

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“…The alternatives are starkly presented here in the comprehensive GCB primer by Editor Sage (). GCB will be adding increased focus to the biology of means of offsetting and adapting to change, as represented in this issue (Lavallee, ; Prosser, Hink, Gubry‐Rangin, & Nicol, ; Sihi, Davidson, Savage, & Liang, ; Smith et al, ), and further develop our strong social media presence.…”

Section: To the Futurementioning

confidence: 99%

Twenty‐five years of GCB: Putting the biology into global change

Long

2020

Global Change Biology

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Putting the biology into global change The study and impact of global change has undergone dramatic transformations over the last 25 years. Global change in the early 1990s was viewed predominantly as the domain of the physical and chemical sciences, with biology very much a junior partner. Just 28 of the 365 pages of the first Intergovernmental Panel on Climate Change (IPCC) Scientific Assessment in 1991 were devoted to biology and ecosystems. Global Circulation Models of the time either

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“…Hink et al, 2017) are a critical factor in evaluating the microbial response to changing environmental conditions, as shown for the terrestrial environment (Prosser at al., 2020).…”

Section: Nitrous Oxide In Marine Environmentsmentioning

confidence: 99%

Ideas and perspectives: A strategic assessment of methane and nitrous oxide measurements in the marine environment

Wilson¹,

Al‐Haj²,

Bourbonnais³

et al. 2020

Preprint

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Abstract. In the current era of rapid climate change, accurate characterization of climate-relevant gas dynamics – namely production, consumption and net emissions – is required for all biomes, especially those ecosystems most susceptible to the impact of change. Marine environments include regions that act as net sources or sinks for a number of climate-active trace gases including methane (CH4) and nitrous oxide (N2O). The temporal and spatial distributions of CH4 and N2O are controlled by the interaction of complex biogeochemical and physical processes. To evaluate and quantify the importance of these mechanisms relevant to marine CH4 and N2O cycling requires a combination of traditional scientific disciplines including oceanography, microbiology, and numerical modeling. Fundamental to all of these efforts is ensuring that the datasets produced by independent scientists around the world are comparable and interoperable. Equally critical is transparent communication within the research community about the technical improvements required to increase our collective understanding of marine CH4 and N2O. An Ocean Carbon & Biogeochemistry (OCB) sponsored workshop was organized to enhance dialogue and collaborations pertaining to marine CH4 and N2O. Here, we summarize the outcomes from the workshop to describe the challenges and opportunities for near-future CH4 and N2O research in the marine environment.

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Nitrous oxide production by ammonia oxidizers: Physiological diversity, niche differentiation and potential mitigation strategies

Cited by 309 publications

References 148 publications

The Structure and Diversity of Nitrogen Functional Groups from Different Cropping Systems in Yellow River Delta

The Structure and Diversity of Nitrogen Functional Groups from Different Cropping Systems in Yellow River Delta

Twenty‐five years of GCB: Putting the biology into global change

Ideas and perspectives: A strategic assessment of methane and nitrous oxide measurements in the marine environment

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