Biofilm Growth in Two Streams Draining Mountainous Permafrost Catchments in NE Greenland

Pastor, Ada; Skovsholt, Louis J.; Riis, Tenna

doi:10.1029/2019jg005557

Cited by 5 publications

(4 citation statements)

References 54 publications

(90 reference statements)

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“…S4 and S5), suggesting that this seasonality is, in part, related to upregulated terrestrial nutrient demand during the growing season (Weintraub and Schimel 2005 b ). This pattern creates persistent nutrient limitation of algal growth during summer (Peterson et al 1983; Pastor et al 2020), which appeared to suppress summer GPP in all but the two most nutrient rich streams (> 90 μ g DIN L −1 ) and led to positive correlations between the temporal variability in GPP and DIN concentrations at the more N poor sites (20–30 μ g L −1 ). Notably, based on the relative area of different streams, DIN‐driven metabolic patterns during the open water season appear to operate across ca.…”

Section: Discussionmentioning

confidence: 99%

“…Superimposed on this light regime is a strongly seasonal pattern of stream nutrient concentrations, with relatively high levels in winter, and lowest during summer (e.g., Holmes et al 2000;Mann et al 2012), potentially due to catchment nutrient retention during the terrestrial growing season (Weintraub and Schimel 2005b;Ohte 2012). As a result, tundra streams are often strongly nutrient limited when incident light is greatest, as evidenced from studies in Alaska (Peterson et al 1983), Northern Sweden (Myrstener et al 2018), Iceland (Friberg et al 2009), and Greenland (Pastor et al 2020). At the same time, elevated nutrient concentrations in spring and autumn may create time windows that support elevated GPP.…”

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confidence: 99%

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Nutrients influence seasonal metabolic patterns and total productivity of Arctic streams

Myrstener

Gómez‐Gener

Rocher-Ros

et al. 2020

Limnology & Oceanography

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The seasonality of gross primary production (GPP) in streams is driven by multiple physical and chemical factors, yet incident light is often thought to be most important. In Arctic tundra streams, however, light is available in saturating amounts throughout the summer, but sharp declines in nutrient supply during the terrestrial growing season may constrain aquatic productivity. Given the opposing seasonality of these drivers, we hypothesized that “shoulder seasons”—spring and autumn—represent critical time windows when light and nutrients align to optimize rates of stream productivity in the Arctic. To test this, we measured annual patterns of GPP and biofilm accumulation in eight streams in Arctic Sweden. We found that the aquatic growing season length differed by 4 months across streams and was determined largely by the timing of ice‐off in spring. During the growing season, temporal variability in GPP for nitrogen (N) poor streams was correlated with inorganic N concentration, while in more N‐rich streams GPP was instead linked to changes in phosphorus and light. Annual GPP varied ninefold among streams and was enhanced by N availability, the length of ice‐free period, and low flood frequency. Finally, network scale estimates of GPP highlight the overall significance of the shoulder seasons, which accounted for 48% of annual productivity. We suggest that the timing of ice off and nutrient supply from land interact to regulate the annual metabolic regimes of nutrient poor, Arctic streams, leading to unexpected peaks in productivity that are offset from the terrestrial growing season.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Nutrients influence seasonal metabolic patterns and total productivity of Arctic streams

Myrstener

Gómez‐Gener

Rocher-Ros

et al. 2020

Limnology & Oceanography

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“…By comparison, streams with strong groundwater connections or in close proximity to solifluction tend to be nutrient enriched and more hydrologically stable, and typically support higher rates of metabolism and biomass accrual (Huryn et al, 2005;Myrstener et al, 2021;Pastor et al, 2020). At the extreme end of this habitat gradient are 5.…”

Section: Introductionmentioning

confidence: 99%

“…Such conditions are typical for upland tundra streams, which lie near the nutrient‐poor and low‐productivity end of the habitat gradient in Artic landscapes. By comparison, streams with strong groundwater connections or in close proximity to solifluction tend to be nutrient enriched and more hydrologically stable, and typically support higher rates of metabolism and biomass accrual (Huryn et al., 2005; Myrstener et al., 2021; Pastor et al., 2020). At the extreme end of this habitat gradient are spring‐fed streams, which sustain flow throughout the year, are comparatively rich in nutrients, and are home to notably productive biological communities (Huryn et al., 2014).…”

Section: Introductionmentioning

confidence: 99%

Nitrogen supply and physical disturbance shapes Arctic stream nitrogen uptake through effects on metabolic activity

et al. 2021

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Spatial and temporal patterns of stream nutrient limitation in an Arctic catchment

Hauptmann

Myrstener

2023

Hydrobiologia

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Arctic stream biofilm responses to ongoing climate-related changes in physical and chemical conditions have major implications for stream food webs and biogeochemical cycles. Yet, such effects have rarely been studied outside summer months or at sub-catchment scales in the Arctic. We used deployments of nutrient diffusing substrates (NDS) to assess the spatial (20 deployments) and seasonal patterns (10 deployments) and physical and chemical drivers of nutrient limitation within an Arctic stream catchment. Results show that nutrient limitation of autotrophic processes was common during summer, but that light inhibited biomass accrual under the ice in winter. Alongside single N, P and C responses, co-limitation dominated the overall pattern of limitation over time and across the catchment. However, the primary limiting nutrient to autotrophs changed from N to P in parts of the catchment with higher N concentrations. As Arctic studies are often conducted at individual sites during summer, these may miss shifts in the drivers of stream productivity that arise from variable nutrient, temperature, and light regimes. Our results caution against focusing on one single most important limiting nutrient, as we found that this can shift seasonally and over small spatial scales in this Arctic catchment.

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Biofilm Growth in Two Streams Draining Mountainous Permafrost Catchments in NE Greenland

Cited by 5 publications

References 54 publications

Nutrients influence seasonal metabolic patterns and total productivity of Arctic streams

Nutrients influence seasonal metabolic patterns and total productivity of Arctic streams

Nitrogen supply and physical disturbance shapes Arctic stream nitrogen uptake through effects on metabolic activity

Spatial and temporal patterns of stream nutrient limitation in an Arctic catchment

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