Interactive effects of bismuth exposure (water and diet) and temperature on snail fatty acid composition, antioxidant enzymes and lipid peroxidation

Mariem Fadhlaoui, Nolan J. T. Pearce, Isabelle Lavoie, Claude Fortin
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Abstract

Despite the growing prevalence of Bismuth (Bi), very little research has been carried to assess its potential toxic effects on aquatic organisms. This study aimed to address this gap by investigating the interactive effects of Bi exposure and elevated temperature on freshwater snails of the genus Lymnaea, specifically on their fatty acid (FA) profiles, oxidative stress markers (superoxide dismutase (SOD), catalase (CAT), glutathione peroxidase (GPx), glutathione S-transferase (GST)) and lipid peroxidation (malondialdehyde (MDA) content). Bismuth exposure was introduced through two distinct routes: i) food via Bi-exposed biofilm (grown under 2 μM Bi), and ii) water (2 μM Bi). Exposed snails were maintained at two temperatures, 19°C and 25°C, over a duration of 14 days. Bismuth bioaccumulation occurred in Bi-exposed biofilm concurrently with a pronounced increase in polyunsaturated fatty acids (PUFA), likely as a protective mechanism to preserve cell structure and integrity. Bismuth bioaccumulation also occurred in snails with their FA composition largely reflecting the composition of their dietary source highlighting the direct link between diet and snail FA profiles. Additionally, the antioxidant enzymes studied exhibited diverse responses under Bi exposure and thermal stress, suggesting the induction of oxidative stress in snails. SOD activity increased at 25°C, suggesting a thermal stress. CAT activity remained high under all conditions, unaffected by temperature or Bi exposure. GPx levels increased in snails fed with Bi-laden biofilm, particularly at 19°C. GST activity showed great variability with a significant three-way interaction. The observed elevation in MDA levels among Bi-exposed snails suggested a potential deficiency in their antioxidant enzyme systems, leading to an increased susceptibility to lipid peroxidation. This research highlights the complex interaction between Bi contamination, temperature, and the physiological responses of aquatic organisms, and reveals the need for future research into the environmental impact of Bi in aquatic ecosystems. We further highlight the importance of food for Bi transfer to higher consumers and the importance of considering dietborne exposures in ecotoxicological studies.
铋暴露(水和食物)与温度对蜗牛脂肪酸组成、抗氧化酶和脂质过氧化的交互影响
尽管铋(Bi)越来越普遍,但很少有研究评估其对水生生物的潜在毒性影响。本研究旨在通过调查铋暴露和温度升高对淡水蜗牛属(Lymnaea)的交互影响,特别是对其脂肪酸(FA)概况、氧化应激标记(超氧化物歧化酶(SOD)、过氧化氢酶(CAT)、谷胱甘肽过氧化物酶(GPx)、谷胱甘肽 S-转移酶(GST))和脂质过氧化(丙二醛(MDA)含量)的交互影响,来弥补这一空白。铋暴露通过两种不同的途径进行:i)通过铋暴露生物膜(在 2 μM Bi 下生长)的食物;ii)水(2 μM Bi)。暴露蜗牛在 19°C 和 25°C 两种温度下维持 14 天。在 Bi 暴露的生物膜中,铋的生物累积与多不饱和脂肪酸(PUFA)的明显增加同时发生,这可能是一种保护细胞结构和完整性的保护机制。铋在蜗牛体内也发生了生物累积,其脂肪酸组成在很大程度上反映了其食物来源的组成,这突出表明了食物与蜗牛脂肪酸组成之间的直接联系。此外,所研究的抗氧化酶在生物暴露和热应力下表现出不同的反应,表明蜗牛体内存在氧化应激。25°C 时 SOD 活性增加,表明存在热应力。CAT 活性在所有条件下都保持较高水平,不受温度或 Bi 暴露的影响。用含 Bi- 的生物膜喂养的蜗牛体内 GPx 含量增加,尤其是在 19°C 时。GST 活性的变化很大,三者之间存在显著的交互作用。在暴露于 Bi 的蜗牛中观察到的 MDA 水平升高表明,它们的抗氧化酶系统可能存在缺陷,从而导致对脂质过氧化反应的敏感性增加。这项研究强调了 Bi 污染、温度和水生生物生理反应之间复杂的相互作用,并揭示了未来研究 Bi 对水生生态系统环境影响的必要性。我们进一步强调了食物将 Bi 转移给高等消费者的重要性,以及在生态毒理学研究中考虑食物传播暴露的重要性。
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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