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  • A grazing-driven positive nutrient feedback loop and active sexual reproduction underpin widespread Noctiluca green tides
Title: A grazing-driven positive nutrient feedback loop and active sexual reproduction underpin widespread Noctiluca green tides
Abstract The mixoplankton green Noctiluca scintillans (gNoctiluca) is known to form extensive green tides in tropical coastal ecosystems prone to eutrophication. In the Arabian Sea, their recent appearance and annual recurrence have upended an ecosystem that was once exclusively dominated by diatoms. Despite evidence of strong links to eutrophication, hypoxia and warming, the mechanisms underlying outbreaks of this mixoplanktonic dinoflagellate remain uncertain. Here we have used eco-physiological measurements and transcriptomic profiling to ascribe gNoctiluca’s explosive growth during bloom formation to the form of sexual reproduction that produces numerous gametes. Rapid growth of gNoctiluca coincided with active ammonium and phosphate release from gNoctiluca cells, which exhibited high transcriptional activity of phagocytosis and metabolism generating ammonium. This grazing-driven nutrient flow ostensibly promotes the growth of phytoplankton as prey and offers positive support successively for bloom formation and maintenance. We also provide the first evidence that the host gNoctiluca cell could be manipulating growth of its endosymbiont population in order to exploit their photosynthetic products and meet critical energy needs. These findings illuminate gNoctiluca’s little known nutritional and reproductive strategies that facilitate its ability to form intense and expansive gNoctiluca blooms to the detriment of regional water, food and the socio-economic security in several tropical countries.  more » « less
Award ID(s):
2019983
PAR ID:
10511942
Author(s) / Creator(s):
; ; ; ; ; ; ;
Corporate Creator(s):
Publisher / Repository:
ISME COMMUNICATION
Date Published:
Journal Name:
ISME Communications
Edition / Version:
1
Volume:
2
Issue:
1
ISSN:
2730-6151
Page Range / eLocation ID:
10
Subject(s) / Keyword(s):
Arabian Sea Sea of Oman Mixotrophs Noctiluca Climate Change
Format(s):
Medium: X Size: 3MB Other: pdf
Size(s):
3MB
Sponsoring Org:
National Science Foundation
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