Structural Variations Increase the Upper Limit of Colony Size of<i>Microcystis</i>: Implications from Laboratory Cultures and Field Investigations

Feng, Ganyu; Zhu, Wei; Xue, Zhaohui; Siyuan, HU; Wang, Ruochen; Zhao, Shuai; Chen, Huaimin

doi:10.1111/jpy.13054

Cited by 10 publications

(1 citation statement)

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“…Then, these factors affect the buoyancy of the colony, where Eh represents the Zeta potential of the colony ( Fang et al, 2014 ). Additionally, influencing factors (nutrient limits and turbulent shear) can induce structural changes within the colonies, enabling to acquire survival strategies ( Feng et al, 2020 ). This study further elucidates that EPS influences the SSA, hydrophobicity, and surface free energy, thereby affecting the formation of Microcystis bloom colonies and the efficiency of algal cell collection.…”

Section: Discussionmentioning

confidence: 99%

The extracellular polysaccharide determine the physico-chemical surface properties of Microcystis

Yang,

Wu,

et al. 2023

Front. Microbiol.

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Microcystis possesses the capacity to form colonies and blooms in lakes and reservoirs worldwide, causing significant ecological challenges in aquatic ecosystems. However, little is known about the determining factors of physico-chemical surface properties that govern the competitive advantage of Microcystis. Here, The physico-chemical surface properties of Microcystis wesenbergii and Microcystis aeruginosa, including specific surface area (SSA), hydrophobicity, zeta potential, and functional groups were investigated. Additionally, the extracellular polysaccharide (EPS) were analyzed. Laboratory-cultured Microcystis exhibited hydrophilic, a negative zeta potential and negatively charged. Furthermore, no significant relationship was shown between these properties and the cultivation stage. Microcystis wesenbergii exhibited low free energy of cohesion, high surface free energy, high growth rate, and high EPS content during the logarithmic phase. On the other hand, M. aeruginosa displayed lower free energy of cohesion, high surface free energy, high EPS content, and high growth rate during the stationary phase. These characteristics contribute to their respective competitive advantage. Furthermore, the relationship between EPS and surface properties was investigated. The polysaccharide component of EPS primarily influenced the SSA and total surface energy of Microcystis. Likewise, the protein component of EPS influenced hydrophobicity and surface tension. The polysaccharide composition, including glucuronic acid, xylose, and fructose, mainly influenced surface properties. Additionally, hydrophilic groups such as O–H and P–O–P played a crucial role in determining hydrophobicity in Microcystis. This study elucidates that EPS influenced the SSA, hydrophobicity, and surface free energy of Microcystis cells, which in turn impact the formation of Microcystis blooms and the collection.

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Section: Discussionmentioning

confidence: 99%