Anthropogenic Perturbations to the Atmospheric Molybdenum Cycle

Wong, Michelle Y.; Rathod, Sagar; Marino, Roxanne; Li, Longlei; Howarth, Robert W.; Alastuey, Andrés; Alaimo, Maria Grazia; Barraza, Francisco; Carneiro, Manuel Castro; Chellam, Shankararaman; Chen, Yu Cheng; Cohen, David D.; Connelly, D. S.; Dongarrà, G.; Gómez, Darı́o; Hand, Jenny L.; Harrison, Roy M.; Hopke, Philip K.; Hueglin, Christoph; Kuang, Yuanwen; Lambert, Fabrice; Liang, James; Losno, R.; Maenhaut, Willy; Milando, Chad W.; Monteiro, Maria Inês Couto; Morera-Gómez, Yasser; Querol, Xavier; Rodrı́guez, Sergio; Smichowski, Patricia; Varrica, Daniela; Xiao, Yi hua; Xu, Yangjunjie; Mahowald, N. M.

doi:10.1029/2020gb006787

Cited by 15 publications

(21 citation statements)

References 178 publications

(320 reference statements)

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“…This shows that Mo depositions are generally low in pristine high‐latitude boreal forests and that Mo limitation of N 2 ‐fixation is likely widespread in boreal feather mosses. Mo deposition is expected to increase globally with human activities (Wong et al, 2021), which could possibly alleviate the Mo limitation and promote moss N 2 ‐fixation. Ma et al (2019) found that Mo addition increased cyanobacteria relative abundance in paddy soils, and Rousk, Degboe, et al (2017) observed higher cyanobacteria colonization of moss that had been supplemented with Mo.…”

Section: Discussionmentioning

confidence: 99%

“…Modification of the atmospheric deposition regime that is linked to the development of human activity is likely to affect nutrient inputs affecting both N 2 ‐fixation and cyanobacterial growth. For instance, atmospheric deposition of iron (Fe), molybdenum (Mo) and vanadium (V), the metal cofactors of the nitrogenase enzyme catalysing the N 2 ‐fixation reaction (Bishop et al, 1980), have substantially increased since the beginning of the Industrial Revolution and are expected to continue to rise (Hamilton et al, 2020; Schlesinger et al, 2017; Wong et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

“…This shows that Mo depositions are generally low in pristine high-latitude boreal forests and that Mo limitation of N 2 -fixation is likely widespread in boreal feather mosses. Mo deposition is expected to increase globally with human activities(Wong et al, 2021), which could possibly alleviate the Mo limitation and promote moss N 2 -fixation Ma et al (2019).…”

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confidence: 99%

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New insights into the drivers of moss‐associated nitrogen fixation and cyanobacterial biomass in the eastern Canadian boreal forest

et al. 2022

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Moss‐associated cyanobacteria nitrogen (N2‐) fixation can contribute to support moss growth and constitutes a major source of new N in boreal forest ecosystems. The biomass of moss‐colonizing cyanobacteria and their N2‐fixation are usually considered linearly correlated. Yet, recent evidence has shown that cyanobacterial biomass and N2‐fixation can be decoupled, suggesting that they are not necessary affected by the same environmental and ecological drivers. Climate and nutrients were reported as affecting moss‐associated N2‐fixation, with equivocal results, whereas drivers of moss cyanobacterial biomass remain unclear. In addition, these drivers are often determined through manipulative experiments (e.g. fertilization and incubation) and remain to be validated with complementary observational studies to help us better understand future impacts of global change on the moss–cyanobacteria symbiosis. We hypothesized that moss‐associated cyanobacterial biomass is controlled in situ by factors affecting bacterial growth, whereas N2‐fixation is controlled by factors affecting enzymatic reactions. Using random forests, Spearman correlations and linear mixed‐effects models, we determined the main drivers of cyanobacterial biomass and N2‐fixation of two feather moss species, which were collected over 3 years along a 1000‐km latitudinal transect in the eastern Canadian boreal forest. We found that temperature, precipitation and phosphorus were the main positive drivers of moss cyanobacterial biomass and that temperature and molybdenum were the main positive drivers of N2‐fixation. Vanadium was a negative driver of N2‐fixation, suggesting the use of alternative nitrogenases by cyanobacteria. Both cyanobacterial biomass and N2‐fixation were strongly influenced by the moss species and were negatively correlated with moss C:N stoichiometry, highlighting the role of N2‐fixation in moss N enrichment. Synthesis. We identified for the first time some environmental drivers of moss‐associated cyanobacterial biomass and showed that they contrast with the drivers of N2‐fixation, which should be considered in further research and confirmed in other experimental settings. This is an important advance in our knowledge of moss–cyanobacteria associations, which would greatly help in better predicting the impacts of global change on this symbiosis and on nitrogen inputs in boreal forest ecosystems.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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New insights into the drivers of moss‐associated nitrogen fixation and cyanobacterial biomass in the eastern Canadian boreal forest

et al. 2022

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“…Anthropogenic activities have markedly changed trace metal contents [i.e., iron (Fe), molybdenum (Mo), and vanadium (V)] in the atmosphere, which, in turn, have affected trace metal deposition. − A recent study reported that atmospheric Mo deposition might increase by 100 times or more in some industrialized regions owing to coal combustion and smelting operations . Schlesinger et al revealed that global wet V deposition had increased by 2.7 times from that in the preindustrial period (15 Gg V a –1 ).…”

Section: Introductionmentioning

confidence: 99%

“…Schlesinger et al revealed that global wet V deposition had increased by 2.7 times from that in the preindustrial period (15 Gg V a –1 ). In general, natural sources of trace metals in the atmosphere include dust, sea spray aerosols, volcanic activity, soil, and wildfire, among others, − and anthropogenic sources are mainly derived from the exploitation and combustion of fossil fuels (i.e., coal and oil) as well as biomass combustion, mineral mining, and traffic emissions. − ,− …”

Section: Introductionmentioning

confidence: 99%

Atmospheric Wet Iron, Molybdenum, and Vanadium Deposition in Chinese Terrestrial Ecosystems

Chen

Wang

Zhu

et al. 2022

Environ. Sci. Technol.

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Iron (Fe), molybdenum (Mo), and vanadium (V) are the main components of the three known biological nitrogenases, which constrain nitrogen fixation and affect ecosystem productivity. Atmospheric deposition is an important pathway of these trace metals into ecosystems. Here, we explored the deposition flux, spatiotemporal pattern, and influencing factors of atmospheric wet Fe, Mo, and V deposition based on China Wet Deposition Observation Network (ChinaWD) data from 2016 to 2020. Our results showed that atmospheric wet Fe, Mo, and V deposition was 7.77 ± 7.24, 0.16 ± 0.11, and 0.13 ± 0.12 mg m −2 a −1 in Chinese terrestrial ecosystems, respectively, and revealed obvious spatial patterns but no significant annual trends. Wet Fe deposition was significantly correlated with the soil Fe content. Mo and V deposition was more affected by anthropogenic activities than Fe deposition. Wet Mo deposition was significantly affected by Mo ore reserves and waste incineration. V deposition was significantly correlated with domestic biomass burning. This study quantified wet Fe, Mo, and V deposition in China for the first time, and the implications of atmospheric trace metal deposition on biological nitrogen fixation were discussed.

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Use of new Indices for the Assessment of Air Quality in the Safi Region (Morocco) using Lichen Biomonitoring of Air Contamination by Trace Elements

Mohamed,

Mohammed,

Abdelhay

2023

Bull Environ Contam Toxicol

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Anthropogenic Perturbations to the Atmospheric Molybdenum Cycle

Cited by 15 publications

References 178 publications

New insights into the drivers of moss‐associated nitrogen fixation and cyanobacterial biomass in the eastern Canadian boreal forest

New insights into the drivers of moss‐associated nitrogen fixation and cyanobacterial biomass in the eastern Canadian boreal forest

Atmospheric Wet Iron, Molybdenum, and Vanadium Deposition in Chinese Terrestrial Ecosystems

Use of new Indices for the Assessment of Air Quality in the Safi Region (Morocco) using Lichen Biomonitoring of Air Contamination by Trace Elements

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