Symbiotic bacteria of Phaeocystis globosa exhibit potential for controlling harmful algal blooms
ID:77 View Protection:ATTENDEE Updated Time:2024-12-31 16:41:35 Hits:814 Oral Presentation

Start Time:2025-01-15 14:15(Asia/Shanghai)

Duration:15min

Session:S12 Session 12-Alleviating the Impact of Emerging Harmful Algal Blooms (HABs) to Coastal Ecosystems and Seafood Safety for a Sustainable and Healthy Ocean » S12-1Alleviating the Impact of Emerging Harmful Algal Blooms (HABs) to Coastal Ecosystems and Seafood Safety for a Sustainable and Healthy Ocean

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Abstract
Phaeocystis globosa is a significant contributor to harmful algal blooms, and its hemolytic toxins pose substantial risks to marine ecosystems and aquaculture. The increasing frequency of P. globosa blooms is associated with marine eutrophication and climate change. In this study, two morphologically distinct strains of P. globosa (single-celled and encysted forms) were analyzed. The growth cycle characteristics of P. globosa were assessed using optical microscopy and flow cytometry, and the community composition of its symbiotic bacteria was determined using high-throughput 16S rRNA amplicon sequencing.
The cell cycles for the single-celled and encysted forms were found to be 50 and 17 days, respectively. During the decline phase, the unicellular P. globosa doubled in size, whereas the encysted cells remained the same. The Shannon diversity indices of symbiotic bacteria increased during the decline phase, with the strain type being the dominant factor influencing bacterial community composition. Proteobacteria were the most dominant, constituting 72.13% of the community, followed by Cyanobacteria (14.12%) and Bacteroidetes (11.88%). the abundance of Balneola (747.74%), Dinoroseobacter (210.10%), and Fabibacter (1683.96%) significantly increased in the single-celled P. globosa.  Additionally, Alteromonas increased by 123.56% in the encysted form of P. globose. Function prediction using PICRUSt2 suggested that symbiotic bacteria enhance their growth by upregulating processes such as DNA replication, purine synthesis, and glycolysis, potentially competing with P. globosa for nutrients and inhibiting the its growth. Increased bacterial activity of enzymes like COX, GSHase, and BCAT may also affect algal oxidative stress and growth. This study underscores the potential of symbiotic bacteria associated with P. globosa as a biological control mechanism for algal bloom control.
Keywords
Phaeocystis globosa, cell cycle, symbiotic bacteria, 16S rRNA, biocontrol
Speaker
Yuting Zhou
PhD Ocean University of China;College of Environmental Science and Engineering

Submission Author
Yuting Zhou Ocean University of China;College of Environmental Science and Engineering
Yu Zhen Ocean University of China
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Important Date
  • Conference Date

    Jan 13

    2025

    to

    Jan 17

    2025

  • Sep 27 2024

    Draft paper submission deadline

  • Feb 17 2025

    Registration deadline

Sponsored By
State Key Laboratory of Marine Environmental Science, Xiamen University
Organized By
State Key Laboratory of Marine Environmental Science, Xiamen University
Department of Earth Sciences, National Natural Science Foundation of China
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