Jeffrey A. Back scite author profile

Abstract. Eutrophication has become one of the most widespread anthropogenic forces impacting freshwater biological diversity. One potentially important mechanism driving biodiversity changes in response to eutrophication is the alteration of seasonal patterns of succession, particularly among species with short, synchronous, life cycles. We tested the hypothesis that eutrophication reduces seasonally driven variation in species assemblages by focusing on an understudied aspect of biodiversity: temporal beta diversity (b t ). We estimated the effect of eutrophication on b t by sampling benthic macroinvertebrate assemblages bimonthly for two years across 35 streams spanning a steep gradient of total phosphorus (P) and benthic algal biomass (as chlorophyll a [chl a]). Two widely used metrics of b diversity both declined sharply in response to increasing P and chl a, regardless of covariates. The most parsimonious explanatory model for b t included an interaction between P and macroinvertebrate biomass, which revealed that b t was lower when macroinvertebrate biomass was relatively high. Macroinvertebrate biomass explained a greater amount of deviance in b t at lower to moderate concentrations of P, providing additional explanatory power where P concentration alone was unable to fully explain declines in b t . Chl a explained similar amounts of deviance in b t in comparison to the best P model, but only when temperature variability, which was positively related to b t , also was included in the model. Declines in b t suggest that nutrient enrichment decreases the competitive advantage that specialists gain by occupying particular temporal niches, which leads to assemblages dominated by generalists that exhibit little seasonal turnover. The collapse of seasonal variation in assemblage composition we observed in our study suggests that treating dynamic communities as static assemblages is a simplification that may fail to detect the full impact of anthropogenic stressors. Our results show that eutrophication leads to more temporally homogenous communities and therefore degrades a fundamental facet of biodiversity.

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Alder cover drives nitrogen availability in Kenai lowland headwater streams, Alaska

Shaftel

King

Back

2010

Biogeochemistry

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Terrestrial sources of nitrogen (N), particularly N-fixing alder, may be important for sustaining production in headwater streams that typically lack substantial subsidies of marine-derived nutrients from spawning salmon yet support upstream-dispersing juvenile salmonids. However, other physiographic characteristics, such as watershed slope and topographic wetness, also control transport of nutrients to streams and may confound apparent linkages between alder and stream N. Seasonal patterns in precipitation and temperature may interact with watershed characteristics to modulate stream N availability. We empirically modeled the effect of alder cover and other watershed physiographic variables on stream N and contrasted these relationships over the growing season among 25 first-order streams from the lower Kenai Peninsula, Alaska. For each date, percent alder cover, mean topographic wetness, and mean slope were used as watershed predictors of NO x -N concentration (nitrate ? nitrite) and daily NO x -N yield using Generalized Additive Models (GAM) and compared using Akaike's Information Criterion (AIC c ). Alder cover was the only probable model and explained 75-96% of the variation in NO x -N concentration and 83-89% of the variation in daily NO x -N yield. The relationship between alder and both NO x -N concentration and daily NO x -N yield changed from constant inputs in May across the range of alder cover (linear fit) to increasing inputs in July and September (non-linear fits) implying that high-alder watersheds were Nsaturated. The strong linkage between alder and stream N coupled with the concurrent timing of maximum stream N from alder in the spring to salmon fry emergence indicates the potential importance of this subsidy to headwater stream ecosystems.

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Jeffrey A. Back

Does nutrient enrichment decouple algal–bacterial production in periphyton?

Freshwater eutrophication drives sharp reductions in temporal beta diversity

Alder cover drives nitrogen availability in Kenai lowland headwater streams, Alaska

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