Nutrient limitation determines biological interactions between a mixotrophic Chrysophyte and toxin-producing Microcystis

Version 1

published

• Created

  February 10, 2025 10:17 by jjk6146

• Updated

  February 10, 2025 10:17 by [unknown user]

• Added Creator Sarah Princiotta

  February 10, 2025 10:17 by jjk6146

• Added Creator Yasawantha Hiripitiyage

  February 10, 2025 10:17 by jjk6146

• Added Creator Devinda Hiripitiyage

  February 10, 2025 10:17 by jjk6146

• Added Creator D A Holen

  February 10, 2025 10:17 by jjk6146

• Added Creator Joshua J Kellogg

  February 10, 2025 10:17 by jjk6146

• Added Creator Belinda Sturm

  February 10, 2025 10:17 by jjk6146

• Added Creator Belinda Strum

  February 10, 2025 10:17 by jjk6146

• Added Creator Tedd Harris

  February 10, 2025 10:17 by jjk6146

• Updated Publisher, Publisher Identifier (DOI), Description, and 1 more Show Changes

  February 10, 2025 10:17 by jjk6146

  Publisher

  • Journal of Plankton Research

  Publisher Identifier (DOI)

  • 10.1093/plankt/fbae067

  Description

  • Blooms of toxigenic cyanobacteria pose a mounting risk to aquatic ecosystems. Relative to abiotic drivers of cyanobacteria success, biotic processes have received less attention. Mixotrophic nanoflagellates that combine heterotrophic ingestion of particulate prey with photoautotrophy are among the eukaryotes that can resist cyanotoxins. We used laboratory experiments in culture to integrate top-down (herbivory) and bottom-up (nitrogen and phosphorus limitation) controls on the growth and production of microcystin-LR, including biodegradation products, of Microcystis by Ochromonas (mixotroph) and Spumella (heterotroph). A notable reduction in the growth rate of toxic Microcystis was evident in co-culture with either Ochromonas or Spumella under P-limitation. Under P-limitation, the co-culture of toxic Microcystis with Ochromonas also led to a reduction in concentration of microcystin-LR (MC-LR and an increase in biodegradation products. Grazing rates up to 31 and 50 cell−1 day−1 on toxic Microcystis were recorded for Ochromonas and Spumella, respectively. The highest grazing rates by Ochromonas were observed on toxic Microcystis under N-limitation. Hence, it is likely that Ochromonas is an herbivore of toxic Microcystis under N-limitation and a competitor for nutrients under P-limitation. Collectively, these results suggest a role of eukaryotic nanoflagellates in decreasing the biomass and toxicity associated with cyanobacteria blooms that vary with nutrient availability.

  Publication Date

  • 2025-01-01
• Updated

  February 10, 2025 10:17 by jjk6146

• Updated Keyword Show Changes

  February 10, 2025 10:18 by jjk6146

  Keyword

  • mixtrophy
• Updated Keyword Show Changes

  February 10, 2025 10:18 by jjk6146

  Keyword

  • mixtrophy
  • mixtrophy, mixoplankton, microcystin, cyanobacteria, cyanobacteria bloom, bacterivory, freshwater
• Updated Creator Sarah Princiotta

  February 10, 2025 10:19 by jjk6146

• Updated Creator Yasawantha Hiripitiyage

  February 10, 2025 10:19 by jjk6146

• Updated Creator Devinda Hiripitiyage

  February 10, 2025 10:19 by jjk6146

• Updated Creator D A Holen

  February 10, 2025 10:19 by jjk6146

• Updated Creator Joshua J Kellogg

  February 10, 2025 10:19 by jjk6146

• Updated Creator Belinda Sturm

  February 10, 2025 10:19 by jjk6146

• Updated Creator Belinda Strum

  February 10, 2025 10:19 by jjk6146

• Updated Creator Tedd Harris

  February 10, 2025 10:19 by jjk6146

• Added JPR-2024-07.pdf

  February 10, 2025 10:25 by jjk6146

• Updated

  February 10, 2025 10:26 by jjk6146

• Updated License Show Changes

  February 10, 2025 10:28 by jjk6146

  License

  • https://creativecommons.org/licenses/by-nc-nd/4.0/
• Published

  February 10, 2025 10:28 by jjk6146

• Updated

  February 10, 2025 21:04 by [unknown user]