Metabolic activity of Planktothrix rubescens and its consequences on oxygen dynamics in laboratory experiment: A stable isotope study

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Marlene Dordoni, Jörg Tittel, Yvonne Rosenlöcher, Karsten Rinke, Johannes A. C. Barth
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Abstract

Fluctuations in dissolved oxygen (DO) contents in natural waters can become intense during cyanobacteria blooms. In a reconnaissance study, we investigated DO concentrations and stable isotope dynamics during a laboratory experiment with the cyanobacterium Planktothrix rubescens in order to obtain insights into primary production under specific conditions. This observation was extended to sub-daily timescales with alternating light and dark phases. Dissolved oxygen concentrations and its isotopes (δ18ODO) ranged from 0.02 to 0.06 mmol · L−1 and from +9.6‰ to +23.4‰. The δ18ODO proved to be more sensitive than concentration measurements in response to metabolic variation and registered earlier shifts to dominance by respiration. Oxygen (O2) contents in the headspace and its isotopes (δ18OO2) ranged from 2.62 to 3.20 mmol · L−1 and from +9.8‰ to +21.9‰. Headspace samples showed less fluctuations in concentration and isotope trends because aquatic processes were hardly able to alter signals once the gas had reached the headspace. Headspace δ18OO2 values were corrected for gas–water equilibration and were determined to be higher than the mean δ18OH2O of −8.7‰. This finding suggests that counteracting respiration was important even during the highest photosynthetic activity. Additionally, headspace analyses led to the definition of a fractionation factor for respiration (αR) of this cyanobacterium with a value of 0.980. This value confirms the one commonly used for cyanobacteria. Our findings may become important for the management of water bodies where decreases in DO are caused by cyanobacteria.

Planktothrix rubescens 的代谢活动及其对实验室实验中氧动力学的影响:稳定同位素研究
蓝藻藻华期间,自然水域中溶解氧(DO)含量的波动会变得非常剧烈。在一项勘测性研究中,我们用蓝藻 Planktothrix rubescens 进行了一次实验室实验,调查了溶解氧浓度和稳定同位素动态,以便深入了解特定条件下的初级生产情况。这一观察结果被扩展到明暗交替的亚日时间尺度。溶解氧浓度及其同位素(δ18ODO)的范围为 0.02 至 0.06 mmol - L-1 和 +9.6‰ 至 +23.4‰。事实证明,δ18ODO 对新陈代谢变化的反应比浓度测量更为敏感,并能更早地反映呼吸作用的主导作用。顶空气中的氧(O2)含量及其同位素(δ18OO2)的范围为 2.62 至 3.20 毫摩尔-升-1 和 +9.8‰ 至 +21.9‰。顶空样品在浓度和同位素趋势方面的波动较小,因为一旦气体到达顶空,水生过程几乎无法改变信号。顶空 δ18OO2 值经过气水平衡校正后,确定高于平均 δ18OH2O 值 -8.7‰。这一结果表明,即使在光合作用最旺盛的时期,呼吸作用的抵消也很重要。此外,顶空分析还确定了该蓝藻的呼吸分馏系数(αR),其值为 0.980。这一数值与蓝藻常用的数值相吻合。我们的研究结果可能对蓝藻导致溶解氧下降的水体管理具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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