Physiological responses of two scleractinian coral species to elevated exposure of suspended particle matter
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摘要: 近岸的珊瑚礁普遍受到高悬浮物的长期胁迫,但对造礁珊瑚的悬浮物耐受阈值目前了解不多,阻碍了我们对近岸造礁珊瑚群落的保护和管理。本研究以造礁珊瑚群落分布北缘——东山海域造礁珊瑚的优势种——标准盘星珊瑚(Dipsastraea speciosa)和锯齿刺星珊瑚(Cyphastrea sp.)为研究对象,采用自主设计开发的悬浮物浓度模拟控制系统,设置了4个悬浮物浓度(0 mg L−1,35 mg L−1,50 mg L−1,100 mg L−1),以珊瑚表观形态特征以及光合生理参数为指标,研究了它们对持续28天的高悬浮物暴露的生理响应。结果表明,在实验起始阶段,悬浮物处理组的刺星珊瑚和标准盘星珊瑚均呈现水螅体收缩现象,但随着时间的增加,所有处理组的两种珊瑚水螅体逐渐恢复至正常状态,且没有观察到珊瑚白化或死亡。此外,两种造礁珊瑚均表现出较强的光合生理可塑性。随着悬浮物浓度的增加,两种珊瑚的实际光量子产量(ΦPSII)也增加,并在100 mg L−1达到最大值,表明这两种珊瑚在高悬浮物浓度下可以通过增强光合作用效率来抵消光照的不足。与此同时,两种珊瑚的最大光量子产量(Fv/Fm)、叶绿素含量和虫黄藻密度在高悬浮物暴露下均维持相对稳定,表明两种珊瑚的光合性能在悬浮物胁迫下依旧保持健康状态,表明东山这两种造礁珊瑚对悬浮物的耐受阈值可能超过100 mg L−1,有着较强的高悬浮物耐受性。本研究是国内首个实现室内长期高悬浮物控制的实验,研究结果可以为我国造礁珊瑚群落的保护和管理提供基础数据支撑。Abstract: Nearshore coral reefs are frequently subjected to prolonged exposure to high levels of suspended particulate matter (SPM). However, the tolerance threshold of scleractinian corals to SPM remains inadequatedly understood, complicating the protection and management of nearshore scleractinian coral communities. In this study, we investigated the physiological responses of Dipsastraea speciosa and Cyphastrea sp., the dominant species of scleractinian corals in the Dongshan waters, which represent the northern distribution limit of scleractinian coral communities, under varying SPM concentrations (0 mg/L, 35 mg/L, 50 mg/L and 100 mg/L). A SPM-controlled simulated system was employed by injecting SPM into experimental tanks to regulate its concentration over a 28-day period. Morphological characteristics and a series of photosynthetic physiological parameters were used as indicators. The results indicated that the polyps of both coral species exposed to three groups of SPM treatments exhibited shrinkageduring the initial stages of the experiment, but quickly recovered over time. No individual of coral bleaching or mortality were observed. Additionally, both coral species demonstrated significant photosynthetic physiological plasticity, evidenced by rising ΦPSII values with SPM concentration increased, reaching a maximum at 100 mg/L. This suggests that the two coral species can mitigate light shading by enhancing their photosynthetic efficiency in response to high SPM concentrations. Furthermore, Fv/Fm ratios, chlorophyll content, and zooxanthella density for both coral species remained relatively stable under high SPM exposure, indicating that their photosynthetic performance remained healthy despite elevated SPM levels. This implies that the tolerance threshold of these two scleractinian corals to SPM may exceed 100 mg/L. This study is the first experiment in China to successfully maintain high SPM levels over an extended period, and the findings provide essential data for the protection and management of scleractinian coral communities in China.
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图 1 基于实验水体浊度调控的悬浮物控制模拟系统
Fig. 1 SPM-controlled simulated system based on the turbidity of experimental tanks
图 2 东山湾水域水体浊度的变化(
2020.01 –2023.01 )Fig. 2 Long-term variation of the turbidity from Jan 2020 to Jan 2023 in the Dongshan Bay
图 3 实验初期悬浮物浓度的实时记录数据
Fig. 3 The real-time data at the beginning of the experiment for the concentration of suspended particle matter in the experimental tanks
图 4 悬浮物暴露对两种珊瑚表观形态特征的影响
Fig. 4 Effect of SPM exposure on the morphological traits of two species of corals
图 5 悬浮物暴露对两种珊瑚光量子参数的影响
Fig. 5 Effect of SPM exposure on the Fv/Fm and ΦPSII on two species of corals
图 6 悬浮物暴露对虫黄藻密度和叶绿素含量的影响
Fig. 6 Effect of SPM exposure on the zooxanthellae density and chlorophyll content
表 1 实验系统中平均悬浮物浓度
Tab. 1 Mean SPM concentration in the experimetnal tanks
系统设置
浓度0 mg L−1 35 mg L−1 50 mg L−1 100 mg L−1 实际平均
浓度4.6 ±
0.5 mg L−134.3 ±
0.7 mg L153.4 ±
2.5 mg L−1103.7 ±
4.5 mg L−1
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