The short-term effect of nitrogen on freshwater cyanobacteria and cyanotoxins

Frontiers in Water Pub Date : 2024-07-22 DOI:10.3389/frwa.2024.1432183

K. Le, J. Maldonado, Thanh-Luan Nguyen, Eyerusalem Goitom, Hana Trigui, Ndèye Adiara Ndiaye, Yves Terrat, B. J. Shapiro, Barry Husk, A. Zamyadi, Sébastien Sauvé, Michèle Prévost, Sarah Dorner

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Abstract

Toxic cyanobacterial blooms are a worldwide concern. Nutrients are among the numerous factors that trigger cyanobacterial blooms and the production of cyanotoxins. This study aimed to assess the effect of nitrogen on cyanobacteria and cyanotoxins through a short-term mesocosm experiment. To achieve this, mesocosms were installed in situ in two lakes (the Missisquoi Bay of Lake Champlain and Petit-Lac-St-François) and received 700 μg/L of ammonium or 500 μg/L of nitrate. A shift to Microcystis in the mesocosms with nitrogen addition was observed 2 days after the addition in Missisquoi Bay, where nitrogen was more limited than Petit-Lac-St-François based on nutrient ratios. There was a significant increase of extracellular ΣMCs and MC-LR in mesocosms with the addition of ammonium or nitrate after 48 h compared to control mesocosms. Intracellular and extracellular microcystin concentrations were associated with Microcystis. Microcystis presence was associated with ammonium 48 h after N was added at both sites. Therefore, toxin production following sudden nitrogen addition can occur on short time scales relevant to drinking water treatment plant operations. This information will help treatment plant operators better anticipate the arrival of potentially higher concentrations of cyanotoxins.

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氮对淡水蓝藻和蓝藻毒素的短期影响

有毒蓝藻藻华是一个全球关注的问题。营养物质是引发蓝藻藻华和产生蓝藻毒素的众多因素之一。本研究旨在通过短期中观模拟实验评估氮对蓝藻和蓝藻毒素的影响。为此，在两个湖泊（Champlain 湖的 Missisquoi 海湾和 Petit-Lac-St-François 湖泊）中就地安装了中观模拟器，并接收 700 μg/L 的铵或 500 μg/L 的硝酸盐。在密西西比湾，根据养分比，氮的限制比小湖-圣弗朗索瓦湾更多，在添加氮2 天后，观察到中样池中的微囊藻发生了转变。与对照介箱相比，添加铵或硝酸盐的介箱在 48 小时后细胞外 ΣMC 和 MC-LR 明显增加。细胞内和细胞外微囊藻毒素浓度与微囊藻有关。在两个地点添加铵 48 小时后，微囊藻的存在与铵有关。因此，在饮用水处理厂运行的短时间内，突然加氮后会产生毒素。这些信息将有助于处理厂操作人员更好地预测可能出现的高浓度蓝藻毒素。

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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Frontiers in Water

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