School of Agriculture, Food and Ecosystem Sciences - Research Publications

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Author: Burrows, Ryan × End date: 2019 ×

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    Seasonal resource limitation of heterotrophic biofilms in boreal streams
    Burrows, RM ; Laudon, H ; McKie, BG ; Sponseller, RA (WILEY, 2017-01)
    Abstract Unraveling the potentially shifting controls over microbial activity among habitats and across seasonal transitions is critical for understanding how freshwater ecosystems influence broader elemental cycles, and how these systems may respond to global changes. We used nutrient‐diffusing substrates to investigate seasonal patterns and constraints on microbial activity of biofilms in streams draining distinct landscape features of the boreal biome (forests, mires, and lakes). Microbial respiration (MR) largely mirrored spatial and temporal variation in water temperature. However, limitation by labile carbon (C) was a constraint to microbial activity during ice‐covered periods, when MR of control nutrient‐diffusing substrates fell below rates predicted from stream temperature alone. Variation in C limitation among the study streams was reflective of putative organic C availability, with C limitation of biofilms weakest in the dissolved organic C (DOC)‐rich, mire‐outlet stream and greatest in the relatively DOC‐poor, forest stream. Incidences of nutrient limitation were only observed during warmer months. Our study illustrates how variation in processes mediated by heterotrophic biofilms and seasonal shifts in resource limitation can emerge in a stream network draining a heterogeneous landscape. In addition, our results show that, for a large portion of the year, heterotrophic processes in boreal streams can be strongly limited by the availability of labile C, despite high DOC concentrations. Metabolic constraints to dissolved organic matter processing at near‐freezing temperatures, coupled with hydrological controls over the delivery of more labile organic resources to streams (e.g., soil freezing and flooding), have potentially strong influences on the productivity of boreal streams.
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    Sediment Respiration Pulses in Intermittent Rivers and Ephemeral Streams
    von Schiller, D ; Datry, T ; Corti, R ; Foulquier, A ; Tockner, K ; Marce, R ; Garcia-Baquero, G ; Odriozola, I ; Obrador, B ; Elosegi, A ; Mendoza-Lera, C ; Gessner, MO ; Stubbington, R ; Albarino, R ; Allen, DC ; Altermatt, F ; Arce, M ; Arnon, S ; Banas, D ; Banegas-Medina, A ; Beller, E ; Blanchette, ML ; Blanco-Libreros, JF ; Blessing, J ; Boechat, IG ; Boersma, KS ; Bogan, MT ; Bonada, N ; Bond, NR ; Brintrup, K ; Bruder, A ; Burrows, RM ; Cancellario, T ; Carlson, SM ; Cauvy-Fraunie, S ; Cid, N ; Danger, M ; de Freitas Terra, B ; Dehedin, A ; De Girolamo, AM ; del Campo, R ; Diaz-Villanueva, V ; Duerdoth, CP ; Dyer, F ; Faye, E ; Febria, C ; Figueroa, R ; Four, B ; Gafny, S ; Gomez, R ; Gomez-Gener, L ; Graca, MAS ; Guareschi, S ; Gucker, B ; Hoppeler, F ; Hwan, JL ; Kubheka, S ; Laini, A ; Langhans, SD ; Leigh, C ; Little, CJ ; Lorenz, S ; Marshall, J ; Martin, EJ ; McIntosh, A ; Meyer, E ; Milisa, M ; Mlambo, MC ; Moleon, M ; Morais, M ; Negus, P ; Niyogi, D ; Papatheodoulou, A ; Pardo, I ; Paril, P ; Pesic, V ; Piscart, C ; Polasek, M ; Rodriguez-Lozano, P ; Rolls, RJ ; Sanchez-Montoya, MM ; Savic, A ; Shumilova, O ; Steward, A ; Taleb, A ; Uzan, A ; Vander Vorste, R ; Waltham, N ; Woelfle-Erskine, C ; Zak, D ; Zarfl, C ; Zoppini, A (AMER GEOPHYSICAL UNION, 2019-10-16)
    Intermittent rivers and ephemeral streams (IRES) may represent over half the global stream network, but their contribution to respiration and carbon dioxide (CO2) emissions is largely undetermined. In particular, little is known about the variability and drivers of respiration in IRES sediments upon rewetting, which could result in large pulses of CO2. We present a global study examining sediments from 200 dry IRES reaches spanning multiple biomes. Results from standardized assays show that mean respiration increased 32-fold to 66-fold upon sediment rewetting. Structural equation modeling indicates that this response was driven by sediment texture and organic matter quantity and quality, which, in turn, were influenced by climate, land use, and riparian plant cover. Our estimates suggest that respiration pulses resulting from rewetting of IRES sediments could contribute significantly to annual CO2 emissions from the global stream network, with a single respiration pulse potentially increasing emission by 0.2–0.7%. As the spatial and temporal extent of IRES increases globally, our results highlight the importance of recognizing the influence of wetting-drying cycles on respiration and CO2 emissions in stream networks.
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    Simulating rewetting events in intermittent rivers and ephemeral streams: A global analysis of leached nutrients and organic matter
    Shumilova, O ; Zak, D ; Datry, T ; von Schiller, D ; Corti, R ; Foulquier, A ; Obrador, B ; Tockner, K ; Allan, DC ; Altermatt, F ; Isabel Arce, M ; Arnon, S ; Banas, D ; Banegas-Medina, A ; Beller, E ; Blanchette, ML ; Blanco-Libreros, JF ; Blessing, J ; Boechat, IG ; Boersma, K ; Bogan, MT ; Bonada, N ; Bond, NR ; Brintrup, K ; Bruder, A ; Burrows, R ; Cancellario, T ; Carlson, SM ; Cauvy-Fraunie, S ; Cid, N ; Danger, M ; de Freitas Terra, B ; De Girolamo, AM ; del Campo, R ; Dyer, F ; Elosegi, A ; Faye, E ; Febria, C ; Figueroa, R ; Four, B ; Gessner, MO ; Gnohossou, P ; Cerezo, RG ; Gomez-Gener, L ; Graca, MAS ; Guareschi, S ; Guecker, B ; Hwan, JL ; Kubheka, S ; Langhans, SD ; Leigh, C ; Little, CJ ; Lorenz, S ; Marshall, J ; McIntosh, A ; Mendoza-Lera, C ; Meyer, EI ; Milisa, M ; Mlambo, MC ; Moleon, M ; Negus, P ; Niyogi, D ; Papatheodoulou, A ; Pardo, I ; Paril, P ; Pesic, V ; Rodriguez-Lozano, P ; Rolls, RJ ; Sanchez-Montoya, MM ; Savic, A ; Steward, A ; Stubbington, R ; Taleb, A ; Vander Vorste, R ; Waltham, N ; Zoppini, A ; Zarfl, C (WILEY, 2019-05-01)
    Climate change and human pressures are changing the global distribution and the extent of intermittent rivers and ephemeral streams (IRES), which comprise half of the global river network area. IRES are characterized by periods of flow cessation, during which channel substrates accumulate and undergo physico-chemical changes (preconditioning), and periods of flow resumption, when these substrates are rewetted and release pulses of dissolved nutrients and organic matter (OM). However, there are no estimates of the amounts and quality of leached substances, nor is there information on the underlying environmental constraints operating at the global scale. We experimentally simulated, under standard laboratory conditions, rewetting of leaves, riverbed sediments, and epilithic biofilms collected during the dry phase across 205 IRES from five major climate zones. We determined the amounts and qualitative characteristics of the leached nutrients and OM, and estimated their areal fluxes from riverbeds. In addition, we evaluated the variance in leachate characteristics in relation to selected environmental variables and substrate characteristics. We found that sediments, due to their large quantities within riverbeds, contribute most to the overall flux of dissolved substances during rewetting events (56%–98%), and that flux rates distinctly differ among climate zones. Dissolved organic carbon, phenolics, and nitrate contributed most to the areal fluxes. The largest amounts of leached substances were found in the continental climate zone, coinciding with the lowest potential bioavailability of the leached OM. The opposite pattern was found in the arid zone. Environmental variables expected to be modified under climate change (i.e. potential evapotranspiration, aridity, dry period duration, land use) were correlated with the amount of leached substances, with the strongest relationship found for sediments. These results show that the role of IRES should be accounted for in global biogeochemical cycles, especially because prevalence of IRES will increase due to increasing severity of drying events.
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    Land use influences macroinvertebrate community composition in boreal headwaters through altered stream conditions
    Jonsson, M ; Burrows, RM ; Lidman, J ; Faltstrom, E ; Laudon, H ; Sponseller, RA (SPRINGER, 2017-04)
    Land use is known to alter the nature of land-water interactions, but the potential effects of widespread forest management on headwaters in boreal regions remain poorly understood. We evaluated the importance of catchment land use, land cover, and local stream variables for macroinvertebrate community and functional trait diversity in 18 boreal headwater streams. Variation in macroinvertebrate metrics was often best explained by in-stream variables, primarily water chemistry (e.g. pH). However, variation in stream variables was, in turn, significantly associated with catchment-scale forestry land use. More specifically, streams running through catchments that were dominated by young (11-50 years) forests had higher pH, greater organic matter standing stock, higher abundance of aquatic moss, and the highest macroinvertebrate diversity, compared to streams running through recently clear-cut and old forests. This indicates that catchment-scale forest management can modify in-stream habitat conditions with effects on stream macroinvertebrate communities and that characteristics of younger forests may promote conditions that benefit headwater biodiversity.
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    Composition of riparian litter input regulates organic matter decomposition: Implications for headwater stream functioning in a managed forest landscape
    Lidman, J ; Jonsson, M ; Burrows, RM ; Bundschuh, M ; Sponseller, RA (WILEY, 2017-02)
    Although the importance of stream condition for leaf litter decomposition has been extensively studied, little is known about how processing rates change in response to altered riparian vegetation community composition. We investigated patterns of plant litter input and decomposition across 20 boreal headwater streams that varied in proportions of riparian deciduous and coniferous trees. We measured a suite of in-stream physical and chemical characteristics, as well as the amount and type of litter inputs from riparian vegetation, and related these to decomposition rates of native (alder, birch, and spruce) and introduced (lodgepole pine) litter species incubated in coarse- and fine-mesh bags. Total litter inputs ranged more than fivefold among sites and increased with the proportion of deciduous vegetation in the riparian zone. In line with differences in initial litter quality, mean decomposition rate was highest for alder, followed by birch, spruce, and lodgepole pine (12, 55, and 68% lower rates, respectively). Further, these rates were greater in coarse-mesh bags that allow colonization by macroinvertebrates. Variance in decomposition rate among sites for different species was best explained by different sets of environmental conditions, but litter-input composition (i.e., quality) was overall highly important. On average, native litter decomposed faster in sites with higher-quality litter input and (with the exception of spruce) higher concentrations of dissolved nutrients and open canopies. By contrast, lodgepole pine decomposed more rapidly in sites receiving lower-quality litter inputs. Birch litter decomposition rate in coarse-mesh bags was best predicted by the same environmental variables as in fine-mesh bags, with additional positive influences of macroinvertebrate species richness. Hence, to facilitate energy turnover in boreal headwaters, forest management with focus on conifer production should aim at increasing the presence of native deciduous trees along streams, as they promote conditions that favor higher decomposition rates of terrestrial plant litter.
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    High rates of organic carbon processing in the hyporheic zone of intermittent streams
    Burrows, RM ; Rutlidge, H ; Bond, NR ; Eberhard, SM ; Auhl, A ; Andersen, MS ; Valdez, DG ; Kennard, MJ (NATURE PORTFOLIO, 2017-10-16)
    Organic carbon cycling is a fundamental process that underpins energy transfer through the biosphere. However, little is known about the rates of particulate organic carbon processing in the hyporheic zone of intermittent streams, which is often the only wetted environment remaining when surface flows cease. We used leaf litter and cotton decomposition assays, as well as rates of microbial respiration, to quantify rates of organic carbon processing in surface and hyporheic environments of intermittent and perennial streams under a range of substrate saturation conditions. Leaf litter processing was 48% greater, and cotton processing 124% greater, in the hyporheic zone compared to surface environments when calculated over multiple substrate saturation conditions. Processing was also greater in more saturated surface environments (i.e. pools). Further, rates of microbial respiration on incubated substrates in the hyporheic zone were similar to, or greater than, rates in surface environments. Our results highlight that intermittent streams are important locations for particulate organic carbon processing and that the hyporheic zone sustains this fundamental process even without surface flow. Not accounting for carbon processing in the hyporheic zone of intermittent streams may lead to an underestimation of its local ecological significance and collective contribution to landscape carbon processes.
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    Persistent nitrogen limitation of stream biofilm communities along climate gradients in the Arctic
    Myrstener, M ; Rocher-Ros, G ; Burrows, RM ; Bergstrom, A-K ; Giesler, R ; Sponseller, RA (WILEY, 2018-08)
    Climate change is rapidly reshaping Arctic landscapes through shifts in vegetation cover and productivity, soil resource mobilization, and hydrological regimes. The implications of these changes for stream ecosystems and food webs is unclear and will depend largely on microbial biofilm responses to concurrent shifts in temperature, light, and resource supply from land. To study those responses, we used nutrient diffusing substrates to manipulate resource supply to biofilm communities along regional gradients in stream temperature, riparian shading, and dissolved organic carbon (DOC) loading in Arctic Sweden. We found strong nitrogen (N) limitation across this gradient for gross primary production, community respiration and chlorophyll-a accumulation. For unamended biofilms, activity and biomass accrual were not closely related to any single physical or chemical driver across this region. However, the magnitude of biofilm response to N addition was: in tundra streams, biofilm response was constrained by thermal regimes, whereas variation in light availability regulated this response in birch and coniferous forest streams. Furthermore, heterotrophic responses to experimental N addition increased across the region with greater stream water concentrations of DOC relative to inorganic N. Thus, future shifts in resource supply to these ecosystems are likely to interact with other concurrent environmental changes to regulate stream productivity. Indeed, our results suggest that in the absence of increased nutrient inputs, Arctic streams will be less sensitive to future changes in other habitat variables such as temperature and DOC loading.