Vertical distribution of picocyanobacteria in deep lakes: the influence of inorganic turbidity

IF 2 3区环境科学与生态学 Q3 ENVIRONMENTAL SCIENCES

Aquatic Sciences Pub Date : 2024-03-05 DOI:10.1007/s00027-024-01057-y

Luca Schenone, Beatriz Modenutti, Esteban Balseiro

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Abstract

Picocyanobacteria (Pcy) represent the dominant photosynthetic fraction in aquatic systems, contributing significantly to global primary production and playing a key role in global biogeochemical cycles. Based on a 20-year dataset of in situ observations in four deep Andean North-Patagonian lakes, we analyzed and presented a simple model to understand how the input of inorganic particles affects light penetration and influences the vertical distribution of freshwater Pcy during summer stratification. The analyzed temporal series includes two important events (volcanic eruption and glacial recession) that substantially affected lake turbidity. Thus, our mechanistic model was constructed as a function of changes in the light extinction coefficient (Kd_PAR) and the mean irradiance of the mixing layer (I_m). Our modeling approach using Bayesian inference and a continuous nonmonotonic function successfully predicted changes in Pcy vertical distribution. The model was successful in fitting data for different minerogenic particles (volcanic ash and glacial clay) and in predicting changes under sharp increases in turbidity (volcanic eruptions), as well as in more gradual changes (glacial recession). Pcy maximum abundance increased with transparency (lower Kd_PAR values), and the amplitude of the vertical profile increased with higher I_m values. Using our model, we achieved a full prediction of Pcy vertical distribution under different scenarios of lake transparency and lake thermal structures.

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深湖中的微囊藻垂直分布：无机浊度的影响

微囊藻（Pcy）是水生系统中最主要的光合部分，对全球初级生产有重大贡献，并在全球生物地球化学循环中发挥着关键作用。基于对四个安第斯北-巴塔哥尼亚深层湖泊长达 20 年的现场观测数据集，我们分析并提出了一个简单的模型，以了解无机颗粒的输入如何影响光的穿透，以及如何影响淡水 Pcy 在夏季分层过程中的垂直分布。分析的时间序列包括两个对湖泊浊度有重大影响的重要事件（火山爆发和冰川退缩）。因此，我们构建的机理模型是光消光系数（KdPAR）和混合层平均辐照度（Im）变化的函数。我们的建模方法采用贝叶斯推理和连续非单调函数，成功地预测了 Pcy 垂直分布的变化。该模型成功地拟合了不同成矿颗粒（火山灰和冰川粘土）的数据，并预测了浊度急剧增加（火山爆发）和较渐进变化（冰川退缩）时的变化。Pcy 的最大丰度随透明度的增加而增加（KdPAR 值降低），垂直剖面的振幅随 Im 值的增加而增加。利用我们的模型，我们可以全面预测湖泊透明度和湖泊热结构不同情况下的 Pcy 垂直分布。

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来源期刊

Aquatic Sciences 环境科学-海洋与淡水生物学

CiteScore

3.90

自引率

4.20%

发文量

审稿时长

1 months

期刊介绍： Aquatic Sciences – Research Across Boundaries publishes original research, overviews, and reviews dealing with aquatic systems (both freshwater and marine systems) and their boundaries, including the impact of human activities on these systems. The coverage ranges from molecular-level mechanistic studies to investigations at the whole ecosystem scale. Aquatic Sciences publishes articles presenting research across disciplinary and environmental boundaries, including studies examining interactions among geological, microbial, biological, chemical, physical, hydrological, and societal processes, as well as studies assessing land-water, air-water, benthic-pelagic, river-ocean, lentic-lotic, and groundwater-surface water interactions.