Nitrogen fixation varies spatially and seasonally in linked stream-lake ecosystems

Marcarelli, Amy; Wurtsbaugh, Wayne A.

doi:10.1007/s10533-009-9311-2

Cited by 38 publications

(27 citation statements)

References 52 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Some studies have indicated that N-fixing cyanobacteria become dominant in summer with a nitrogen shortage (Mugidde et al 2003;Marcarelli and Wurtsbaugh 2009;Paterson et al 2011). However, N-fixing cyanobacteria did not dominate the phytoplankton community in several additional studies under analogous circumstances (Havens et al 2003;Scott and McCarthy 2010;Gikuma-Njuru et al 2013).…”

Section: Discussionmentioning

confidence: 99%

Differences in phytoplankton dynamics and community structure between a wet year and dry year in the Zhoucun Reservoir

Qiu

Zeng

2016

Journal of Freshwater Ecology

View full text Add to dashboard Cite

Rainfall-induced nutrient fluctuations in surface water affect phytoplankton communities and cause algal blooms. To examine this influence in the Zhoucun Reservoir, China, field surveys were performed weekly or biweekly from February 2013 (a wet year) to December 2014 (a dry year). Physical conditions, nutrient levels, and phytoplankton functional groups were investigated during monitoring. Nutrient levels increased in the summer of 2013 (TN: 0.85À2.66 mg/L; TP: 0.037À0.138 mg/L), while nitrogen deficiency occurred in the summer of 2014 (TN: 0.38À0.73 mg/L, TP: 0.044À0.079 mg/L). A cyanobacteria bloom that appeared in the summer of 2013 had the dominant phytoplankton functional groups M and Tc. In the summer of 2014, algal cell density and biomass were much lower than those during the corresponding period in 2013, and the co-dominant phytoplankton groups were F, L 0 , Tc, and S2. Non-N-fixing cyanobacteria were not abundant in summer 2013 probably because of the low ratio of NO 3 ¡ to NH 4 C , although nitrogen was also deficient. In contrast to these summer trends, little difference was noted between phytoplankton dynamics and community structure in the two winters and two springs, regardless of nutrient conditions. Redundancy analysis indicated that rainfall-induced nitrogen fluctuations were the primary factor causing phytoplankton dynamics to differ between the wet and dry year. The effects of water temperature, stratification, and light on the phytoplankton community were independent of nutrient fluctuations. This study shows that rainfall fluctuations change summer nutrient conditions and that cyanobacteria blooms are likely to occur in wet years in the Zhoucun Reservoir.

show abstract

Section: Discussionmentioning

confidence: 99%

Differences in phytoplankton dynamics and community structure between a wet year and dry year in the Zhoucun Reservoir

Qiu

Zeng

2016

Journal of Freshwater Ecology

View full text Add to dashboard Cite

show abstract

“…N fixation, like all biogeochemical processes, is a spatially and temporally patchy process; thus small-scale experiments may misrepresent its extent. There is also growing appreciation for the potential N fixation in benthic habitats (Marcarelli and Wurtsbaugh 2009) that is difficult if not impossible to quantify in microcosms. Thus, an approach to measuring N fixation that integrates over space and time has become increasingly needed to understand how eutrophication changes the importance of N fixation in aquatic ecosystems.…”

Section: Discussionmentioning

confidence: 99%

Assessing nonpoint‐source nitrogen loading and nitrogen fixation in lakes using δ¹⁵N and nutrient stoichiometry

Jankowski

Schindler

Holtgrieve

2012

Limnology & Oceanography

View full text Add to dashboard Cite

Runoff from human-dominated watersheds has greatly altered nitrogen (N) and phosphorus (P) cycling in lakes. Nutrients from human sources are distinct from those from undisturbed ecosystems in several ways including lower N : P ratios, which can drive ecosystems to N-limited conditions, and enriched stable N isotope ratios. In this study, we used these distinct characteristics to estimate shifts in N sources to 27 lakes across a human density gradient in western Washington. We compared an N stable isotope two-source mixing model with a mixing model that coupled N stable isotopes to N : P stoichiometry and included N fixation. We found that a two-source mixing model (human and watershed sources) did not explain observed variation in d 15 N of particulate organic matter (POM) and primary consumers (R 2 5 0.60) as well as a model that included a third N source (N fixation; R 2 5 0.72). When fixed N was facultatively added to the ecosystem below a critical N : P ratio, the more complex mixing model captured the observed patterns in POM and primary-consumer d 15 N among lakes extremely well. In lakes with P concentrations . 20 mg L 21 (N : P mass ratio , 15.3), N fixation became an increasingly important component of the N cycle, accounting for . 50% of lake N budgets. This model provides a novel way to estimate the contribution of nonpoint N sources and N fixation to lakes in watersheds subject to human nutrient inputs.

show abstract

“…Alternatively, and perhaps more plausibly, if the majority of DON results from within-lake biological uptake of nitrate, as nitrate concentrations decline with increasing lake landscape position less new autochthonous organic nitrogen would be produced. With little landscape variability in rates of nitrogen fixation or uptake in streams (Arp and Baker 2007;Marcarelli and Wurtsbaugh 2009), DON concentrations would cease to increase with increasing lake landscape position as nitrogen was primarily cycled between inorganic and organic fractions in association with biological processes.…”

Section: Landscape Controls On Dissolved Nitrogenmentioning

confidence: 99%

The Influence of Landscape Position and Catchment Characteristics on Aquatic Biogeochemistry in High-Elevation Lake-Chains

2011

View full text Add to dashboard Cite

To examine the influence of landscape characteristics and landscape position on aquatic biogeochemistry, we sampled a total of 76 lakes within 14 different lake-chains spanning the latitudinal extent of the high-elevation Sierra Nevada (California). We measured water chemistry, dissolved organic matter (DOM), nutrients, and biotic variables in study catchments that encompassed representative ranges of area (3-22 km 2 ), elevation (2,200-3,700 m.a.s.l), elevation change (50-700 m), and average slope (13°-26°). Hierarchical models were used to account for variability in biogeochemistry because they explicitly maintain the framework of lakes within individual lake-chains while accounting for variation among lake-chains. Uncon ditional means models, where lake-chain was a random effect, revealed significant differences among lake-chains for nearly all biogeochemical variables. Models explained 42-95% of this variability, with the majority of the variation (70%) explained by the among lake-chain component. To explore the amount of additional variation explained by lake landscape position, we added lake network number (LNN) to models. LNN explained a significant amount of additional variation (7% average) in 8 of 23 biogeochemical parameters. However, it explained more variability within individual lake-chains (75%), where among lake-chain differences did not obscure patterns. Patterns of increase with LNN were found for dissolved organic carbon and nitrogen, fluorescence of DOM, alkalinity, and bacterioplankton abundance, whereas nitrate and nitrogen to phosphorus nutrient ratios decreased. LNN explained variation because it served as a proxy for underlying catchment characteristics that changed consistently along downstream flow paths. To characterize the amount of variation explained by catchment characteristics alone, we fit a third model that included lake-chain as a random effect and landscape or lake morphometry attributes as fixed effects. Catchment characteristics explained about as much additional variation (6%) as LNN, but for substantially more biogeochemical parameters (18 out of 23). The catchment characteristics most predictive of biogeochemistry were land-cover factors delineating alpine and subalpine zones (elevation, slope, or proportions of rock or shrub cover). In general, catchment characteristics were stronger predictors of biogeochemistry than characteristics of lake morphometry, emphasizing the relative importance of landscape processes in snowmelt-dominated lake ecosystems.

show abstract

Nitrogen fixation varies spatially and seasonally in linked stream-lake ecosystems

Cited by 38 publications

References 52 publications

Differences in phytoplankton dynamics and community structure between a wet year and dry year in the Zhoucun Reservoir

Differences in phytoplankton dynamics and community structure between a wet year and dry year in the Zhoucun Reservoir

Assessing nonpoint‐source nitrogen loading and nitrogen fixation in lakes using δ¹⁵N and nutrient stoichiometry

The Influence of Landscape Position and Catchment Characteristics on Aquatic Biogeochemistry in High-Elevation Lake-Chains

Contact Info

Product

Resources

About

Nitrogen fixation varies spatially and seasonally in linked stream-lake ecosystems

Cited by 38 publications

References 52 publications

Differences in phytoplankton dynamics and community structure between a wet year and dry year in the Zhoucun Reservoir

Differences in phytoplankton dynamics and community structure between a wet year and dry year in the Zhoucun Reservoir

Assessing nonpoint‐source nitrogen loading and nitrogen fixation in lakes using δ15N and nutrient stoichiometry

The Influence of Landscape Position and Catchment Characteristics on Aquatic Biogeochemistry in High-Elevation Lake-Chains

Contact Info

Product

Resources

About

Assessing nonpoint‐source nitrogen loading and nitrogen fixation in lakes using δ¹⁵N and nutrient stoichiometry