Nitrogen Subsidies from Hillslope Alder Stands to Streamside Wetlands and Headwater Streams, Kenai Peninsula, Alaska

Callahan, Michael K.; Whigham, Dennis F.; Rains, Mark C.; Rains, Kai C.; King, Ryan S.; Walker, Coowe M.; Maurer, Jasmine R.; Baird, Steven J.

doi:10.1111/1752-1688.12508

Cited by 14 publications

(20 citation statements)

References 67 publications

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“…Shaftel et al (2012) observed a similar pattern in some of the same streams, where some mid-level-alder sites had lower than expected DIN concentrations in July and September than in May. We suspect that increased temperature-driven uptake or summer low flows (i.e., reduced hydrologic connection) along soil flow paths decreased the amount of alder-derived N being exported to the streams (Callahan et al 2017). Thus, N 2 fixation rates in these streams could be sensitive to temperature or precipitation changes at the reach and catchment scales via controls on landscape DIN export.…”

Section: Discussionmentioning

confidence: 54%

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Catchment-scale alder cover controls nitrogen fixation in boreal headwater streams

Hiatt¹,

Robbins²,

Back³

et al. 2017

Freshwater Science

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Alder (Alnus spp.) is a woody plant with bacterial symbionts that fix atmospheric N 2 into bioavailable N. We studied 12 North American boreal headwater streams spanning a steep gradient of catchment alder cover (0-27%) to test the hypothesis that increasing inputs of inorganic N associated with increasing alder cover would reduce or eliminate in-stream benthic N 2 fixation. We measured N 2 fixation rates, chlorophyll a, and ash-free dry mass (AFDM) of periphyton in early (May) and late (August) summer 2011. Dissolved inorganic N (DIN) concentrations, composed almost entirely of NO 3 /NO 2-N, ranged from below detection limits to nearly 2 mg/L and were strongly predicted by catchment alder cover in both months. Higher N 2 fixation rates were observed in August than in May. N 2 fixation rates declined sharply when alder cover exceeded~2% of catchment cover, corresponding to 20 to 40 lg/L DIN. This pattern also was evident among 3 streams with contrasting catchment alder cover sampled approximately every 2 wk during the study. The stream with no catchment alder cover exhibited a steady increase in N 2 fixation rates over the summer, whereas the streams with low and high alder in their catchments had very low N 2 fixation rates that did not vary over time. The influence of alder cover on periphyton biomass was not clear. The strong regulation of alder cover on in-stream N availability leads us to suggest that alder presence may be an important terrestrial regulator of stream N cycling.

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Section: Discussionmentioning

confidence: 54%

“…Because alder is an obligate N 2 fixer, landscape cover and distance from streams (length of soil flow path) determine N delivery from alder to streams (Shaftel et al 2012, Callahan et al 2017. Alder presence can be a robust predictor of N availability in areas with minimal anthropogenic N sources.…”

Section: Discussionmentioning

confidence: 99%

Catchment-scale alder cover controls nitrogen fixation in boreal headwater streams

Hiatt¹,

Robbins²,

Back³

et al. 2017

Freshwater Science

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“…Second, plant species composition in the sub‐basin may influence nitrogen levels in streams. Specifically, alders are nitrogen‐fixing shrubs responsible for increasing stream nitrate via groundwater (Callahan et al ). Thus, the high levels of alders observed at moose impacted sites could further increase nitrogen subsidies in these streams and may explain some of the variation in total nitrogen in the study sites (Table 1).…”

Section: Discussionmentioning

confidence: 99%

“…Streams with higher discharges are expected to have lower electrical conductivity and total nitrogen due to dilution. Streams surrounded by more speckled alders, a riparian nitrogen‐fixing shrub, are expected to have higher levels of total nitrogen (Callahan et al ).…”

Section: Methodsmentioning

confidence: 99%

Cross‐ecosystem effects of a large terrestrial herbivore on stream ecosystem functioning

MacSween

Leroux

Oakes

2018

Oikos

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Large terrestrial consumers have direct and indirect effects on forest ecosystem function, but few studies have investigated the impacts of terrestrial consumers on freshwater ecosystems. In the Cape Breton Highlands of Nova Scotia, browsing by hyper‐abundant moose following a spruce budworm outbreak has transformed boreal forest into grasslands. We conducted a field study to investigate the potential for cross‐ecosystem effects of hyper‐abundant moose following budworm outbreak on small boreal stream ecosystem structure and function. With our field study, we tested the prediction that watersheds with higher levels of moose‐mediated grasslands in their sub‐basin would have higher stream temperatures, total nitrogen, electrical conductivity, periphyton biomass and macroinvertebrate abundances. While our data supported several of our predictions pertaining to moose impacts on the abiotic variables (i.e. temperature range, total nitrogen, electrical conductivity) we found evidence of variable moose impacts on the benthic community. Specifically, we observed lower relative abundance of predatory invertebrates in streams with high moose impacts compared to streams with low moose impacts in their watersheds but no evidence of moose impacts on the relative abundance of shredders, filterers, gatherers, and grazers. This empirical study fills a key gap in our understanding of spatial ecosystem ecology by providing insight into the effects of large terrestrial consumers across ecosystem boundaries with potential implications for landscape‐scale management of hyper‐abundant ungulates. Given the broad availability and improvement in remote sensing technology, the novel integration of remote sensing and field studies employed here may provide a roadmap for future studies of meta‐ecosystem dynamics.

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“…We conducted our experiment in 2013 on the western Kenai Peninsula of Alaska in a first‐order tributary of the South Fork Anchor River, previously identified as SANC 1203 (King, Walker, Whigham, Baird, & Back, ; Shaftel, King, & Back, ; Walker, King, Whigham, & Baird, ; 59.77974°N, 151.55518°W; Figure a,b). We selected SANC 1203 for this experiment for several reasons: (1) well‐characterised catchment and water chemistry from previous studies, including cover estimates of wetlands (32%, largely discharge slope and riparian wetlands that export limited quantities of DOC; Shaftel et al, ; Walker et al, ; Whigham, Walker, King, & Baird, ) and N 2 ‐fixing alder (12.6%; Shaftel, King, & Back, ; Shaftel et al, ); (2) relatively high nutrient availability, specifically PO 4 ‐P ( c. 20–50 µg/L) related to volcanic deposition in the region and NO 3 ‐ N ( c. 200–500 µg/L) directly related to the alder (Callahan et al, ; Shaftel et al, ); (3) relatively low levels of ambient DOC (1.8–3.3 mg/L at baseflow) when compared to peat‐rich catchments nearby (10–20 mg/L, Walker et al, ); (4) similar channel width (1.4 m), depth (0.12 m), substrate (gravel‐cobble, woody debris), riparian vegetation (bluejoint grass: Calamagrostis canadensis ), and gradient (5%) over a distance of sufficient length to delineate reaches that would be comparable prior to any experimental manipulation; (5) representative of headwater streams throughout the Kenai lowlands (Whigham et al, ) and other boreal regions; and (6) moderate to high densities of juvenile Dolly Varden ( Salvelinus malma , Figure c), the most widespread and abundant salmonid in headwater streams in this region (King et al, ).…”

Section: Methodsmentioning

confidence: 99%

Low‐level dissolved organic carbon subsidies drive a trophic upsurge in a boreal stream

et al. 2020

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Energy pathways in stream food webs are often driven by allochthonous basal resources. However, allochthonous dissolved organic carbon (DOC) is generally viewed as a minor if not insignificant basal resource because much of the DOC pool comprises high molecular weight, recalcitrant compounds and is inefficiently incorporated into biomass. Nevertheless, there is increasing evidence that the relatively small, labile fraction of DOC may indeed fuel microbial activity to a level that stimulates productivity across multiple trophic levels, resulting in a trophic upsurge. Here, we tested the trophic upsurge hypothesis by subsidising the labile DOC pool of an Alaskan boreal stream that had relatively high nutrient availability but low levels of naturally occurring DOC. We continuously added ecologically relevant (0.250 mg C/L, c. 10% increase above ambient bulk DOC) concentrations of labile DOC (acetate‐C) for 62 days to a treatment reach that was statistically indistinguishable in its channel form and chemistry from an upstream reference reach. We measured responses of periphyton production and biomass, whole reach metabolism and nutrient uptake, benthic invertebrate abundances, and juvenile salmonid (Dolly Varden, Salvelinus malma) abundance and growth. Measurements of basal ecosystem responses collectively indicated increased energy mobilization at the base of the food web in response to labile DOC addition. Periphyton bacterial production in the treatment reach was generally >1.5× reference reach values, and periphyton ash‐free dry mass, chlorophyll‐a, and chlorophyll‐a:ash‐free dry mass were all greater in the treatment reach by the end of the study. Throughout dosing, ecosystem respiration was 1.3× greater in the treatment reach and dissolved inorganic nitrogen uptake was greater in the treatment reach on eight out of nine measurements. Benthic invertebrate counts, dominated by Baetis spp. and Chironomidae, were c. 4× greater after 28 dosing days and c. 8× greater after 56 days in the upstream portion of the treatment reach. Abundance generally declined with increasing distance from the dosing station. Dolly Varden fry and parr age classes were nearly 2× more abundant in the upstream portion of the treatment reach than in any section of the reference reach and also declined with increasing distance from the dosing station. Further, Dolly Varden tagged with passive integrated transponders prior to the experiment had significantly higher instantaneous growth rates in the treatment reach than those recaptured in the reference reach. The strong consumer responses to small quantities of labile DOC mirrored significant treatment reach increases in basal ecosystem function and therefore demonstrated a response consistent with a trophic upsurge. Terrestrial DOC has historically been viewed as contributing little to metazoan consumers, instead modulating the influence of nutrients and being respired out of a disconnected microbial loop. Because we dosed the treatment reach with a relevant concentration of labile...

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Nitrogen Subsidies from Hillslope Alder Stands to Streamside Wetlands and Headwater Streams, Kenai Peninsula, Alaska

Cited by 14 publications

References 67 publications

Catchment-scale alder cover controls nitrogen fixation in boreal headwater streams

Catchment-scale alder cover controls nitrogen fixation in boreal headwater streams

Cross‐ecosystem effects of a large terrestrial herbivore on stream ecosystem functioning

Low‐level dissolved organic carbon subsidies drive a trophic upsurge in a boreal stream

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