Assessing the role of forests in mitigating eutrophication downstream of pasture during spring snowmelt

Chiwa, Masaaki; Inoue, Shintaro; Tashiro, Nobutada; Ohgi, Daisuke; Uehara, Yoshitoshi; Shibata, Hideaki; Kume, Atsushi

doi:10.1002/hyp.10189

Cited by 9 publications

(4 citation statements)

References 48 publications

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“…This finding supports other reports that instream retention and removal is most efficient when concentrations are lowest, but has a muted effect on high concentrations. As a result, when terrestrial inputs vary widely, they largely control spatial variability in concentrations (Chiwa et al, 2015;Lin et al, 2015;Scanlon et al, 2010).…”

Section: In-stream Effectsmentioning

confidence: 99%

Nitrogen inputs drive nitrogen concentrations in U.S. streams and rivers during summer low flow conditions

Bellmore

Compton

Brooks

et al. 2018

Science of The Total Environment

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Ecological and human health impairments related to excess nitrogen (N) in streams and rivers remain widespread in the United States (U.S.) despite recent efforts to reduce N pollution. Many studies have quantified the relationship between N loads to streams in terms of N mass and N inputs to watersheds; however, N concentrations, rather than loads, are more closely related to impacts on human health and aquatic life. Additionally, concentrations, rather than loads, trigger regulatory responses. In this study, we examined how N concentrations are related to N inputs to watersheds (atmospheric deposition, synthetic fertilizer, manure applied to agricultural land, cultivated biological N fixation, and point sources), land cover characteristics, and stream network characteristics, including stream size and the extent of lakes and reservoirs. N concentration data were collected across the conterminous U.S. during the U.S. Environmental Protection Agency's 2008-09 National Rivers and Streams Assessment (n = 1966). Median watershed N inputs were 15.7 kg N ha yr. Atmospheric deposition accounted for over half the N inputs in 49% of watersheds, but watersheds with the highest N input rates were dominated by agriculture-related sources. Total N input to watersheds explained 42% and 38% of the variability in total N and dissolved inorganic N concentrations, respectively. Land cover characteristics were also important predictors, with wetland cover muting the effect of agricultural N inputs on N concentrations and riparian disturbance exacerbating it. In contrast, stream variables showed little correlation with N concentrations. This suggests that terrestrial factors that can be managed, such as agricultural N use practices and wetland or riparian areas, control the spatial variability in stream N concentrations across the conterminous U.S.

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Section: In-stream Effectsmentioning

confidence: 99%

Nitrogen inputs drive nitrogen concentrations in U.S. streams and rivers during summer low flow conditions

Bellmore

Compton

Brooks

et al. 2018

Science of The Total Environment

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show abstract

“…In the present study, we focused on the relationship between spatially varied nitrogen deposition and soil microbial properties within a cool temperate forest in the eastern area of Hokkaido, Japan. Eastern Hokkaido, including the investigated forest, receives relatively low nitrogen deposition from the atmosphere (2-5 kg N ha −1 yr −1 as a typical value) (Chiwa et al 2015; Network Center for EANET 2021), while nitrogen deposition in the boundary area of the forest (i.e., forest edge) is possibly more than that in the interior area of the forest (forest interior) owing to advection of nitrogen fertilizer, which was supplied to surrounding pasture grasslands ( Fig. 1) (Reinmann and Hutyra 2017;Remy et al 2016Remy et al , 2017Remy et al , 2018aRemy et al , 2018b.…”

Section: Introductionmentioning

confidence: 99%

Soil microbial community responding to moderately elevated nitrogen deposition in a Japanese cool temperate forest surrounded by fertilized grasslands

Nagano

Nakayama

Katata

et al. 2021

Preprint

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In order to examine the hypothesis that the soil microbial community in a nitrogen-limited forest responds to moderately elevated nitrogen deposition (< 10kg N ha-1 yr-1), correlations between nitrogen deposition and soil microbial properties were analyzed in a cool temperate forest surrounded by normally fertilized pasture grasslands in northern Japan. Three experimental plots were established in forest edges adjacent to the grasslands and the other three plots were in forest interiors at least 700 m away from the grasslands. Nitrogen deposition in each plot was measured from May to November 2018. In August 2018, litter and surface soil samples were collected from all plots to measure net nitrogen mineralization and nitrification rates as indicators of microbial activity, and microbial biomass and various gene abundances (i.e., bacterial 16S rRNA, fungal ITS, and bacterial and archaeal amoA genes) as indicators of microbial abundance. Nitrogen deposition in forest edges was 1.4-fold greater than that in forest interiors, whereas maximum deposition was 3.7 kg N ha−1. Nitrogen deposition was significantly correlated with net nitrogen mineralization and nitrification rates and 16S rRNA and bacterial amoA gene abundances. Microbial community structures analyzed for bacterial 16S rRNA and fungal ITS gene amplicons were different between litter and soil samples, but were similar between the forest edge and interior. Nitrogen deposition was also correlated with the soil carbon-to-nitrogen ratio and nitrate and ammonium contents. Thus, it was suggested that some soil microbial activities and abundances in a nitrogen-limited forest likely responded to moderately elevated nitrogen deposition. These findings provide primary information on soil microbial response to moderately elevated nitrogen deposition.

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“…In the present study, we focused on the relationship between spatially varied nitrogen deposition and soil microbial properties within a cool temperate forest in the eastern area of Hokkaido, Japan. Eastern Hokkaido, including the investigated forest, receives relatively low nitrogen deposition from the atmosphere (2-5 kg N ha −1 yr −1 as a typical value) (Chiwa et al 2015; Network Center for EANET 2021), while nitrogen deposition in the boundary area of the forest (i.e., forest edge) is possibly more than that in the interior area of the forest (forest interior) owing to advection of nitrogen fertilizer, which was supplied to surrounding pasture grasslands (Fig. 1) (Reinmann and Hutyra 2017;Remy et al 2016Remy et al , 2017Remy et al , 2018aRemy et al , 2018b.…”

Section: Introductionmentioning

confidence: 99%

Soil microbial community responding to moderately elevated nitrogen deposition in a Japanese cool temperate forest surrounded by fertilized grasslands

Nagano

Nakayama

Katata

et al. 2021

Soil Science and Plant Nutrition

View full text Add to dashboard Cite

In order to examine the hypothesis that the soil microbial community in a nitrogen-limited forest responds to moderately elevated nitrogen deposition (< 10kg N ha -1 yr -1 ), correlations between nitrogen deposition and soil microbial properties were analyzed in a cool temperate forest surrounded by normally fertilized pasture grasslands in northern Japan. Three experimental plots were established in forest edges adjacent to the grasslands and the other three plots were in forest interiors at least 700 m away from the grasslands. Nitrogen deposition in each plot was measured from May to November 2018. In August 2018, litter and surface soil samples were collected from all plots to measure net nitrogen mineralization and nitri cation rates as indicators of microbial activity, and microbial biomass and various gene abundances (i.e., bacterial 16S rRNA, fungal ITS, and bacterial and archaeal amoA genes) as indicators of microbial abundance. Nitrogen deposition in forest edges was 1.4-fold greater than that in forest interiors, whereas maximum deposition was 3.7 kg N ha −1 . Nitrogen deposition was signi cantly correlated with net nitrogen mineralization and nitri cation rates and 16S rRNA and bacterial amoA gene abundances.Microbial community structures analyzed for bacterial 16S rRNA and fungal ITS gene amplicons were different between litter and soil samples, but were similar between the forest edge and interior. Nitrogen deposition was also correlated with the soil carbon-to-nitrogen ratio and nitrate and ammonium contents.Thus, it was suggested that some soil microbial activities and abundances in a nitrogen-limited forest likely responded to moderately elevated nitrogen deposition. These ndings provide primary information on soil microbial response to moderately elevated nitrogen deposition.

show abstract

Assessing the role of forests in mitigating eutrophication downstream of pasture during spring snowmelt

Cited by 9 publications

References 48 publications

Nitrogen inputs drive nitrogen concentrations in U.S. streams and rivers during summer low flow conditions

Nitrogen inputs drive nitrogen concentrations in U.S. streams and rivers during summer low flow conditions

Soil microbial community responding to moderately elevated nitrogen deposition in a Japanese cool temperate forest surrounded by fertilized grasslands

Soil microbial community responding to moderately elevated nitrogen deposition in a Japanese cool temperate forest surrounded by fertilized grasslands

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