蓝藻单体细胞与群体颗粒生长繁殖差异OA
Growth and reproduction vary between individual cells and particle aggregates of cyanobacteria
该研究对比分析了蓝藻单体细胞与群体颗粒的生长特性与代谢差异.研究结果表明,群体颗粒在营养胁迫下维持较高的叶绿素 a 含量(胁迫下群体颗粒降幅 47.82%远低于单体细胞 85.22%)和光化学效率,表现出更强的环境适应性与抗逆能力.蓝藻受到生存刺激时会调整代谢组分,不耐受刺激时会释放大量蛋白类物质.而单体细胞易受刺激出现胞内泄漏型释放,群体颗粒维持生存和避免胞内泄漏的抵抗力更强.研究发现,蓝藻群体通过增强环境缓冲能力与代谢可塑性,显著提升了其在胁迫条件下的生存优势,是自然水体中蓝藻水华形成与维持竞争优势的重要机制.
[Objective]Cyanobacteria grown in the laboratory or cultivated commercially present a uniformly dispersed state of cells without particle aggregation.This growth pattern differs significantly from the suspended particle-like growth characteristic of cyanobacterial populations in natural blooms.Such particles are highly likely to engage in cooperation,environmental adaptation,and metabolic regulation by aggregating.This study aimed to systematically compare the growth characteristics and metabolic responses of individual cyanobacterial cells and particles to identify the key role of population morphology in environmental adaptation and in the formation and maintenance of blooms.[Methods]This study used a laboratory-scale,controlled culture system to treat individual cells or particles with different nutritional stresses.The responses were systematically evaluated by monitoring key physiological indicators,including morphological characteristics,dynamic changes in chlorophyll a content,photochemical efficiency(Fv/Fm),and metabolic release characteristics.[Results]The results showed that individual cells were mainly 3-7 μm in diameter,while the particles were primarily between 200-650 μm.Compared with individual cells,the particles exhibited stronger stress tolerance.Under nutritional adversity,biomass decrease was much lower in particles than in individual cells(47.82%vs.85.22%decline in chlorophyll a),while maintaining photochemical efficiency at a higher level.Population structure effectively delayed cell death.Second,metabolic response patterns differed markedly between the two types.When environmental nutritional composition changed,cyanobacterial particles switched metabolic mechanisms by increasing the production and secretion of humic-and fulvic-like compounds to adopt survival strategies.Under nutritional limitation,although the release of organic compounds by cyanobacterial particles and individual cells was enhanced,organic matter increased relatively meagerly in particles.In contrast,individual cells were more prone to loss of structural integrity under adversity,leading to leakage of intracellular components,which had a significantly greater proportion of protein-like material than organic compounds.From a physiological and metabolic correlation perspective,these results suggest that population morphology involves the construction of a localized microenvironment that effectively buffers the direct impacts of external stress.[Conclusions]Cyanobacteria can significantly enhance their environmental stress buffering capacity and metabolic plasticity by forming particle aggregates.Such a mechanism is key for maintaining physiological function and improving resistance under adverse conditions,such as nutritional stress.It enables cyanobacterial populations to demonstrate a significant advantage in inter-and intraspecific competition in natural water bodies,providing a crucial theoretical and experimental basis for the formation and long-term maintenance of cyanobacterial blooms.
孙凤;张朝阳;吴磊;闫文卓;邓鑫;丛海兵
扬州大学 环境科学与工程学院,江苏 扬州 225000扬州大学 环境科学与工程学院,江苏 扬州 225000扬州大学 环境科学与工程学院,江苏 扬州 225000扬州大学 环境科学与工程学院,江苏 扬州 225000扬州大学 环境科学与工程学院,江苏 扬州 225000扬州大学 环境科学与工程学院,江苏 扬州 225000
资源环境
蓝藻聚集形态生长特性有机代谢
cyanobacteriaaggregation formgrowth characteristicsorganic metabolism
《实验技术与管理》 2026 (4)
122-129,8
国家重点研发计划子课题资助项目(2022YFC3203602)江苏省水利科技项目(2025031)国家自然科学基金资助项目(51708480)扬州大学教学改革项目(YZUJX2020—D20)
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