淡水沉积物细菌群落对盐度干扰的抵抗力及其对工业盐排放和气候变化引起的盐渍化的影响

Helen Tammert, Carmen Kivistik, Veljo Kisand, Kairi Käiro, Daniel P. R. Herlemann
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摘要

盐碱化对淡水生态系统的影响在2022年位于波兰和德国的奥得河的生态灾难中变得明显,这是由采矿活动的盐排放造成的。细菌群落如何应对由工业盐排放或气候变化驱动的事件引起的盐碱化,取决于这些复杂细菌群落的敏感性。为了研究细菌群落对脉冲盐碱化的敏感性,我们在0.2 ~ 6.0的盐度范围内进行了实验。此外,我们在波罗的海沿岸取样了类似的盐度,那里的细菌群落长期暴露在上述盐度中。为了模拟重大干扰,我们在实验中加入了氨苄西林/链霉素治疗。虽然抗生素的添加和盐度的增加对水体细菌丰富度和群落组成有显著影响,但在实验中只有抗生素对沉积物细菌群落有影响。相比之下,波罗的海沿岸的沉积物细菌群落根据盐度聚集在一起。因此,沉积物细菌群落比水中细菌更能抵抗盐度的脉冲变化,但能够适应永久变化而不损失物种丰富度。我们的研究结果表明,中度脉冲盐渍化事件,如工业盐排放或强风暴,将导致水中细菌群落的变化,对生态系统功能的影响未知。然而,沉积物细菌群落的生态系统功能可能不会受到影响,这取决于干扰的强度。长期的干扰,如海平面上升或不断的盐排放,将导致沉积物细菌群落组成的永久性变化。
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Resistance of freshwater sediment bacterial communities to salinity disturbance and the implication for industrial salt discharge and climate change-based salinization
The impact of salinization on freshwater ecosystems became apparent during the 2022 ecological disaster in the Oder River, located in Poland and Germany, which was caused by salt discharge from mining activities. How bacterial communities respond to salinization caused by industrial salt discharge, or climate change-driven events, depends on the sensitivity of these complex bacterial communities. To investigate the sensitivity of bacterial communities to pulse salinization, we performed an experiment in the salinity range from 0.2 to 6.0. In addition, we sampled similar salinities in the littoral zone of the Baltic Sea where the bacterial communities are permanently exposed to the aforementioned salinities. To simulate a major disturbance, we included an ampicillin/streptomycin treatment in the experiment. Although the addition of antibiotics and increase in salinity had a significant impact on the water bacterial richness and community composition, only antibiotics affected the sediment bacterial community in the experiment. In contrast, sediment bacterial communities from the Baltic Sea littoral zone clustered according to salinity. Hence, sediment bacterial communities are more resistant to pulse changes in salinity than water bacteria but are able to adapt to a permanent change without loss in species richness. Our results indicate that moderate pulse salinization events such as industrial salt discharge or heavy storms will cause changes in the water bacterial communities with unknown consequences for ecosystem functioning. Sediment bacterial communities, however, will probably be unaffected in their ecosystem functions depending on the disturbance strength. Long-term disturbances, such as sea level rise or constant salt discharge, will cause permanent changes in the sediment bacterial community composition.
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