Details

Autor(en) / Beteiligte

• Qu, Tongfei
• Hou, Chengzong
• Zhao, Xinyu
• Zhong, Yi
• Guan, Chen
• Lin, Zhihao
• Tang, Xuexi
• Wang, Ying

Titel

Bacteria associated with Ulva prolifera: a vital role in green tide formation and migration

Ist Teil von

• Harmful algae, 2021-08, Vol.108, p.102104-102104, Article 102104

Ort / Verlag

Elsevier B.V

Erscheinungsjahr

2021

Link zum Volltext

Quelle

Elsevier ScienceDirect Journals

Beschreibungen/Notizen

• •Differences in community structure were obvious between seawater and epiphytic bacteria.•Bacterial community structure changed more dramatically in 35.00°N sea area.•U. prolifera-associated bacteria possibly impact the formation and outbreak of green tide.•Potentially complex interactions between BFGs and U. prolifera existed in the entire migration process. Ulva prolifera green tide in the Yellow Sea of China is a typical cross-regional marine ecological disaster. We hypothesized that the complex interactions between U. prolifera and its associated bacterial communities possibly impact the formation and outbreak of green tide. To test this hypothesis, the U. prolifera-associated bacterial community changes in the entire migration area were investigated through field sampling and high-throughput sequencing. The results showed that (1) with the green tide migration, the richness and diversity increased for U. prolifera epiphytic bacterial communities, while they decreased for seawater bacterial communities in the phycosphere. (2) The richness, diversity, and community composition of U. prolifera-associated bacteria changed more dramatically in the 35.00°N sea area. (3) Potential interactions between bacteria and U. prolifera existed during the entire long-distance migration of green tide, and six bacterial functional groups (BFGs) were defined. Growth-regulating BFG I and antibacterial and stress-resistance BFG II were the dominant communities in the early stage of the green tide migration, which have the role of regulating algal growth and synergistic protection. Heterotrophic BFG III and algicidal BFG IV were the dominant communities in the late stage of the green tide migration, and they were able to compete with algae for nutrients and inhibit algal growth. Nutritive BFG V and algae-derived nutritional type BFG VI symbiotically lived with algal host. Our study highlights the spatial and temporal complexity of U. prolifera-associated bacterial communities and provides valuable insights into the potential contribution of U. prolifera-associated bacterial communities to green tide outbreaks. [Display omitted]