微咸水域微囊藻毒性特征及其对后生浮游动物的胁迫作用

doi:10.3969/j.issn.1000-5641.2026.03.010

摘要/Abstract

摘要：

淡水有害蓝藻迁移至河口微咸水域会对当地生态系统造成威胁, 其产生的不同赋存形式的藻毒素也会对浮游动物造成不同的影响. 为探讨微囊藻在微咸水域中藻毒素变化及其不同赋存形式对浮游动物的生态效应, 本研究在近岸微咸水域开展原位围隔实验, 分析微囊藻的存活及藻毒素赋存形式的变化, 进一步探究颗粒态和溶解态藻毒素对后生浮游动物丰度和群落组成的影响. 结果显示, 微囊藻在盐度4‰条件下能够存活, 藻毒素主要以颗粒态 (胞内) 形式存在. 实验围隔中, 颗粒态藻毒素先增加后降低, 溶解态藻毒素占比例仅3%~8%, 并呈逐渐降低趋势. 低盐度 (≤7‰) 会促进颗粒态藻毒素的合成, 当盐度升至10‰时, 藻细胞生长和胞内毒素合成受到明显抑制, 藻毒素释放量显著提高. 不同类群后生浮游动物种类对藻毒素的敏感度和耐受性存在差异, 其中颗粒态藻毒素对浮游动物起效较慢但毒性持续时间更长, 浮游动物丰度后期显著低于初始值, 群落组成中桡足类占比较大; 溶解态藻毒素处理组则在短期内引起大量浮游动物死亡, 但后期丰度显著高于初始值, 轮虫逐渐演变为优势类群. 结果表明, 微咸水域中微囊藻毒素的存在形式直接影响了后生浮游动物的丰度和群落组成, 对水体生态系统产生影响. 本研究为评估微咸水域微囊藻毒素的生态风险及制定水域管理策略提供了重要的科学依据.

关键词: 有害蓝藻水华, 微咸水域, 微囊藻毒素, 浮游动物, 生态风险

Abstract:

The migration of freshwater harmful cyanobacteria into estuarine brackish waters poses a significant threat to local ecosystems. The different forms in which these cyanobacteria produce algal toxins, such as microcystins (MCs), can exert varying impacts on zooplankton communities. This study aimed to investigate the predominant forms of MCs produced by Microcystis in brackish waters and their subsequent effects on the survival and community composition of metazoan zooplankton. An in situ mesocosm experiment was conducted in a nearshore brackish wetland. Rectangular mesocosms (1.5 m depth, 150 L volume) were established in the open water area, filled with ambient wetland water filtered through a No. 25 plankton net, and inoculated with Microcystis colonies collected from Dianshan Lake to achieve an initial chlorophyll a concentration of 60 μg/L. The experiment included three replicate mesocosms and ran for 14 days. Data were processed using Microsoft Excel and statistically analyzed with SPSS 23.0. One-way analysis of variance (ANOVA) and t-tests were used to determine statistical significance. The survival of Microcystis and changes in microcystin forms (particulate vs. dissolved) were analyzed, alongside the effects of these toxin fractions on zooplankton abundance and community structure. The results demonstrated that Microcystis survived at a salinity of 4‰, with MCs predominantly existing in the intracellular (particulate) form. Within the mesocosms, intracellular microcystin concentrations initially increased and subsequently decreased, while the proportion of extracellular (dissolved) microcystins remained low (3%~8%) and presented a decreasing trend. Low salinity (≤7‰) appeared to promote intracellular microcystin synthesis. Conversely, both algal growth and intracellular microcystin synthesis were significantly inhibited when salinity was increased to 10‰, accompanied by a significant increase in microcystin release. Differential sensitivity and tolerance to MCs were observed among metazoan zooplankton groups. Particulate MCs were associated with slower-acting but longer-lasting toxicity, resulting in final zooplankton abundance significantly lower than initial levels, with copepods becoming proportionally more dominant in the community structure. In contrast, conditions favoring dissolved MCs led to substantial acute mortality, followed by a recovery phase where final abundance significantly exceeded initial levels, and rotifers emerged as the dominant group. These findings indicate that the partitioning of Microcystis toxins in brackish environments directly influences zooplankton abundance and community composition, thereby impacting the aquatic ecosystem. This research provides a crucial scientific basis for assessing the ecological risks of Microcystis toxins in brackish waters and for informing the development of effective water management strategies.

Key words: harmful cyanobacterial blooms, brackish waters, microcystins, zooplankton, ecological risk

中图分类号:

X171
X826

姜欣然, 陈雪初, 黄莹莹, 由文辉, 李心露. 微咸水域微囊藻毒性特征及其对后生浮游动物的胁迫作用[J]. 华东师范大学学报（自然科学版）, 2026, 2026(3): 124-133, 184.

Xinran JIANG, Xuechu CHEN, Yingying HUANG, Wenhui YOU, Xinlu LI. Characteristics of Microcystis in brackish water and its effects on Metazoan Zooplankton[J]. J* E* C* N* U* N* S*, 2026, 2026(3): 124-133, 184.

图/表 6

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组别	死亡率/%
组别	24 h	48 h	72 h	96 h
空白组	6.67	10.50	26.67	33.33
颗粒态微囊藻毒素组(30.5$ \mu \mathrm{g}/\mathrm{L} $)	10.00	53.30	90.00	96.67
溶解态微囊藻毒素组(30.5$ \mu \mathrm{g}/\mathrm{L} $)	26.67	60.00	72.56	90.33

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