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Autori principali: Lawson, Gabriella M, Young, Jakob L, Aanderud, Zachary T, Jones, Erin F, Bratsman, Samuel, Daniels, Jonathan, Malmfeldt, Madeleine P, Baker, Michelle A, Abbott, Benjamin W, Daly, Scott, Paerl, Hans W, Carling, Greg, Brown, Brian, Lee, Raymond, Wood, Rachel L
Natura: Artículo científico
Lingua:en
Pubblicazione: Harmful algae 2025
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Accesso online:https://pubmed.ncbi.nlm.nih.gov/40032438/
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author Lawson, Gabriella M
Young, Jakob L
Aanderud, Zachary T
Jones, Erin F
Bratsman, Samuel
Daniels, Jonathan
Malmfeldt, Madeleine P
Baker, Michelle A
Abbott, Benjamin W
Daly, Scott
Paerl, Hans W
Carling, Greg
Brown, Brian
Lee, Raymond
Wood, Rachel L
author_facet Lawson, Gabriella M
Young, Jakob L
Aanderud, Zachary T
Jones, Erin F
Bratsman, Samuel
Daniels, Jonathan
Malmfeldt, Madeleine P
Baker, Michelle A
Abbott, Benjamin W
Daly, Scott
Paerl, Hans W
Carling, Greg
Brown, Brian
Lee, Raymond
Wood, Rachel L
Lawson, Gabriella M
Young, Jakob L
Aanderud, Zachary T
Jones, Erin F
Bratsman, Samuel
Daniels, Jonathan
Malmfeldt, Madeleine P
Baker, Michelle A
Abbott, Benjamin W
Daly, Scott
Paerl, Hans W
Carling, Greg
Brown, Brian
Lee, Raymond
Wood, Rachel L
collection PubMed - marine biology
contents Nutrient limitation and seasonality associated with phytoplankton communities and cyanotoxin production in a large, hypereutrophic lake. Lawson, Gabriella M Young, Jakob L Aanderud, Zachary T Jones, Erin F Bratsman, Samuel Daniels, Jonathan Malmfeldt, Madeleine P Baker, Michelle A Abbott, Benjamin W Daly, Scott Paerl, Hans W Carling, Greg Brown, Brian Lee, Raymond Wood, Rachel L Lakes Phytoplankton Seasons Cyanobacteria Phosphorus Nitrogen Harmful Algal Bloom Utah Bacterial Toxins Nutrients Marine Toxins Microcystins Though freshwater harmful algal blooms have been described and studied for decades, several important dynamics remain uncertain, including the relationships among nutrient concentrations, phytoplankton growth, and cyanotoxin production. To identify when and where nutrients limit phytoplankton, cyanobacteria, and cyanotoxins, we conducted in situ bioassay studies. We added nitrogen (N), phosphorus (P), or N + P across various seasons in water collected from three locations across Utah Lake, one of the largest freshwater lakes in the western U.S. This shallow, hypereutrophic lake provides a powerful testbed for quantifying nutrient-growth-toxin interactions. We assessed a range of parameters over time, including photopigment concentrations, phytoplankton abundance (cell counts), cyanotoxins, and nutrient concentrations. Despite high background nutrient concentrations in lake water, phytoplankton abundance and composition were strongly affected by nutrient addition. Phosphorus limitation was more common in the spring, with N limitation and N + P limitation becoming more common in the fall. Nutrient additions were positively associated with cyanobacteria (Microcystis, Aphanocapsa, Dolichospermum, Merismopedia, Aphanizomenon spp.), eukaryotes (Aulacoseira, Desmodesmus spp.), and two taxonomical categories of phytoplankton (i.e., unicellular and colonial green algae). When detected, anatoxin-a was positively associated with Aphanizomenon and negatively associated with Microcystis spp. However, overall cyanotoxin concentrations were not associated with cyanobacterial cell density but varied seasonally. These findings highlight the importance of considering seasonal nutrient availability dynamics and provide insights into specific nutrient targets, species, and cyanotoxins that play a significant role in the health and management of similar eutrophic lake environments around the world.
format Artículo científico
id pubmed_40032438
institution PubMed
language en
publishDate 2025
publisher Harmful algae
record_format pubmed
spellingShingle Nutrient limitation and seasonality associated with phytoplankton communities and cyanotoxin production in a large, hypereutrophic lake.
Lawson, Gabriella M
Young, Jakob L
Aanderud, Zachary T
Jones, Erin F
Bratsman, Samuel
Daniels, Jonathan
Malmfeldt, Madeleine P
Baker, Michelle A
Abbott, Benjamin W
Daly, Scott
Paerl, Hans W
Carling, Greg
Brown, Brian
Lee, Raymond
Wood, Rachel L
Lakes
Phytoplankton
Seasons
Cyanobacteria
Phosphorus
Nitrogen
Harmful Algal Bloom
Utah
Bacterial Toxins
Nutrients
Marine Toxins
Microcystins
Nutrient limitation and seasonality associated with phytoplankton communities and cyanotoxin production in a large, hypereutrophic lake. Lawson, Gabriella M Young, Jakob L Aanderud, Zachary T Jones, Erin F Bratsman, Samuel Daniels, Jonathan Malmfeldt, Madeleine P Baker, Michelle A Abbott, Benjamin W Daly, Scott Paerl, Hans W Carling, Greg Brown, Brian Lee, Raymond Wood, Rachel L Lakes Phytoplankton Seasons Cyanobacteria Phosphorus Nitrogen Harmful Algal Bloom Utah Bacterial Toxins Nutrients Marine Toxins Microcystins Though freshwater harmful algal blooms have been described and studied for decades, several important dynamics remain uncertain, including the relationships among nutrient concentrations, phytoplankton growth, and cyanotoxin production. To identify when and where nutrients limit phytoplankton, cyanobacteria, and cyanotoxins, we conducted in situ bioassay studies. We added nitrogen (N), phosphorus (P), or N + P across various seasons in water collected from three locations across Utah Lake, one of the largest freshwater lakes in the western U.S. This shallow, hypereutrophic lake provides a powerful testbed for quantifying nutrient-growth-toxin interactions. We assessed a range of parameters over time, including photopigment concentrations, phytoplankton abundance (cell counts), cyanotoxins, and nutrient concentrations. Despite high background nutrient concentrations in lake water, phytoplankton abundance and composition were strongly affected by nutrient addition. Phosphorus limitation was more common in the spring, with N limitation and N + P limitation becoming more common in the fall. Nutrient additions were positively associated with cyanobacteria (Microcystis, Aphanocapsa, Dolichospermum, Merismopedia, Aphanizomenon spp.), eukaryotes (Aulacoseira, Desmodesmus spp.), and two taxonomical categories of phytoplankton (i.e., unicellular and colonial green algae). When detected, anatoxin-a was positively associated with Aphanizomenon and negatively associated with Microcystis spp. However, overall cyanotoxin concentrations were not associated with cyanobacterial cell density but varied seasonally. These findings highlight the importance of considering seasonal nutrient availability dynamics and provide insights into specific nutrient targets, species, and cyanotoxins that play a significant role in the health and management of similar eutrophic lake environments around the world.
title Nutrient limitation and seasonality associated with phytoplankton communities and cyanotoxin production in a large, hypereutrophic lake.
topic Lakes
Phytoplankton
Seasons
Cyanobacteria
Phosphorus
Nitrogen
Harmful Algal Bloom
Utah
Bacterial Toxins
Nutrients
Marine Toxins
Microcystins
url https://pubmed.ncbi.nlm.nih.gov/40032438/