湍流混合对光合特性的选择制约着浅层富营养化湖泊中蓝藻藻华的形成

Huaming Wu, Xingqiang Wu, Lorenzo Rovelli, Andreas Lorke
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摘要

预测蓝藻与环境之间复杂的相互作用对于了解有害藻华的形成至关重要。以往有关这些相互作用的大多数研究都将蓝藻细胞的特定特性(如生长率、死亡率和光合能力(Pmax))视为整个种群的代表,并假定这些特性在时空上保持不变。尽管在种群水平上,这些性状的改变可能是由种内竞争驱动的,但人们对这些性状及其可塑性如何随环境条件而变化并影响水华形成知之甚少。在此,我们验证了一个假设,即蓝藻(微囊藻属)种内 Pmax 的变化在其种群动态中起着重要作用。我们将一维水动力学模型与基于性状的浮游植物模型相结合,模拟了在一系列典型的浅富营养化湖泊动态条件下,物理驱动因素(湍流和浊度)对微囊藻种群 Pmax 的影响。我们的研究结果表明,湍流是 Pmax 变化的方向性选择驱动因素。根据代表风驱动混合的日周期性湍流强度的不同,种群平均表型要么向低 Pmax(允许种群在上层捕获更多光照)转变,要么向高 Pmax(提高光利用效率)转变。此外,我们还观察到,与较低的多样性相比,高Pmax的种内多样性可加速表面浮渣的形成,最多可达四倍以上。这项研究深入揭示了蓝藻种群对湍流的响应机制,并强调了蓝藻藻华形成过程中种内差异的重要性。亮点
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Selection of photosynthetic traits by turbulent mixing governs formation of cyanobacterial blooms in shallow eutrophic lakes
Prediction of the complex cyanobacteria-environment interactions is vital for understanding harmful bloom formation. Most previous studies on these interactions considered specific properties of cyanobacterial cells as representative for the entire population (e.g., growth rate, mortality, and photosynthetic capacity (Pmax)), and assumed that they remained spatiotemporally unchanged. Although, at the population level, the alteration of such traits can be driven by intraspecific competition, little is known about how traits and their plasticity change in response to environmental conditions and affect the bloom formation. Here we test the hypothesis that intraspecific variations in Pmax of cyanobacteria (Microcystis spp.) play an important role in its population dynamics. We coupled a one-dimensional hydrodynamic model with a trait-based phytoplankton model to simulate the effects of physical drivers (turbulence and turbidity) on the Pmax of Microcystis populations for a range of dynamic conditions typical for shallow eutrophic lakes. Our results revealed that turbulence acts as a directional selective driver for changes in Pmax. Depending on the intensity of daily-periodic turbulence, representing wind-driven mixing, a shift in population-averaged phenotypes occurred toward either low Pmax, allowing the population to capture additional light in the upper layers, or high Pmax, enhancing the efficiency of light utilization. Moreover, we observed that a high intraspecific diversity in Pmax accelerated the formation of surface scum by up to more than four times compared to a lower diversity. This study offers insights into mechanisms by which cyanobacteria populations respond to turbulence and underscores the significance of intraspecific variations in cyanobacterial bloom formation. Highlights
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