Nitrogen fixation contribution to nitrogen cycling during cyanobacterial blooms in Utah Lake

Hanyan Li; Theron Miller; Jingrang Lu; Ramesh Goel

doi:10.1016/j.chemosphere.2022.134784

Nitrogen fixation contribution to nitrogen cycling during cyanobacterial blooms in Utah Lake

Chemosphere. 2022 Sep:302:134784. doi: 10.1016/j.chemosphere.2022.134784. Epub 2022 Apr 30.

Authors

Hanyan Li¹, Theron Miller², Jingrang Lu³, Ramesh Goel⁴

Affiliations

¹ Department of Civil and Environmental Engineering, The University of Utah, 110 S Central Campus Drive, Salt Lake City, UT, 84112, USA.
² Wasatch Front Water Quality Council, Salt Lake City, UT, USA.
³ United States Environmental Protection Agency, Office of Research and Development, Cincinnati, OH, USA. Electronic address: lu.jingrang@epa.gov.
⁴ Department of Civil and Environmental Engineering, The University of Utah, 110 S Central Campus Drive, Salt Lake City, UT, 84112, USA. Electronic address: ram.goel@utah.edu.

Abstract

Nitrogen (N) cycling is an essential process in lake systems and N-fixation is an important component of it. Recent studies have also found that nitrate reduction through heterotrophic denitrification in lake systems did not prevent harmful cyanobacterial blooms, but instead, may have favored the dominance of N₂-fixing cyanobacteria. The overall objective of this study was to estimate nitrogen fixation rates and the expressions of associated nitrogenase (nif gene) functional gene at several sites at different occasions in freshwater Utah Lake. For comparison purposes, one time sampling was also conducted in the brackish Farmington Bay of Great Salt Lake (GSL). The microbial ecology of the top 20-cm of surface water was investigated to assess the dominant cyanobacterial communities and N-related metabolisms. Our study revealed that Dolichospermum and Nodularia were potential N₂-fixers for Utah Lake and brackish Farmington Bay, respectively. The in situ N₂-fixation rates were 0-0.73 nmol N hr^-1L^-1 for Utah Lake and 0-0.85 nmol N hr^-1L^-1 for Farmington Bay, and these rates positively correlated with the abundance and expressions of the nif gene. In addition, nitrate reduction was measured in sediment (0.002-0.094 mg N VSS^-1 hr^-1). Significantly positive correlations were found among amoA, nirS and nirK abundance (R = 0.56-0.87, p < 0.05, Spearman) in both lakes. An exception was the lower nirK gene abundance detected at one site in Farmington Bay where high ammonium retentions were also detected. Based on a mass balance approach, we concluded that the amount of inorganic N loss through denitrification still exceeded the N input by N₂-fixation, much like in most lakes, rivers, and marine ecosystems. This indicates that N cycling processes such as denitrification mediated by heterotrophic bacteria contributes to N-export from the lakes resulting in N limitations.

Keywords: Brackish water; Cyanobacterial bloom; Denitrification; Freshwater; N fixation; Nitrogenase gene.

MeSH terms

Cyanobacteria* / genetics
Cyanobacteria* / metabolism
Ecosystem
Eutrophication
Lakes* / microbiology
Nitrates
Nitrogen / analysis
Nitrogen Fixation
Utah

Substances

Nitrates
Nitrogen

Grants and funding

EPA999999/ImEPA/Intramural EPA/United States