Coexistence of and Blooms in a Tropical Urban Reservoir and Their Links with Microbiomes

Overview

Journal Environ Sci Technol

Publisher American Chemical Society

Specialty Environmental Health

Date 2023 Jan 18

PMID 36653016

Authors

Shu Harn Te

Jerome Wai Kit Kok

Rong Luo

Luhua You

Nur Hanisah Sukarji

Kwan Chien Goh

Zhi Yang Sim

Dong Zhang

Yiliang He

Karina Yew-Hoong Gin

Affiliations

Soon will be listed here.

Abstract

Bacteria play a crucial role in driving ecological processes in aquatic ecosystems. Studies have shown that bacteria-cyanobacteria interactions contributed significantly to phytoplankton dynamics. However, information on the contribution of bacterial communities to blooms remains scarce. Here, we tracked changes in the bacterial community during the development of a cyanobacterial bloom in an equatorial estuarine reservoir. Two forms of blooms were observed simultaneously corresponding to the lotic and lentic characteristics of the sampling sites where significant spatial variabilities in physicochemical water quality, cyanobacterial biomass, secondary metabolites, and cyanobacterial/bacterial compositions were detected. dominated the upstream sites during peak periods and were succeeded by when the bloom subsided. For the main body of the reservoir, a mixed bloom featuring coccoid and filamentous cyanobacteria (, , , , , and ) was observed. Concentrations of the picocyanobacteria remained high throughout the study, and their positive correlations with cylindrospermopsin and anatoxin-a suggested that they could produce cyanotoxins, which pose more damaging impacts than previously supposed. Succession of different cyanobacteria ( and ) following changes in nutrient composition and ionic strength was demonstrated. The microbiomes associated with blooms were unique to the dominant cyanobacteria. Generic and specialized bloom biomarkers for the and downstream mixed blooms were also identified. Microscillaceae, Chthoniobacteraceae, and were the major heterotrophic bacteria associated with bloom, whereas Phycisphaeraceae and Methylacidiphilaceae were the most prominent groups for the bloom. Collectively, bacterial community can be greatly deviated by the geological condition, monsoon season, cyanobacterial density, and dominant cyanobacteria.

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