Pollutant Exposure Shapes Mitochondrial Bioenergetics in a Wild Seabird.

IF 6.3

Environment & Health Pub Date : 2025-12-22 eCollection Date: 2026-04-17 DOI:10.1021/envhealth.5c00297

Guadalupe Lopez-Nava, Lucie Michel, Giacomo Dell'Omo, Petra Quillfeldt, Paco Bustamante, Stefania Casagrande

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引用次数: 0

Abstract

Laboratory studies show that mercury (Hg) and per- and polyfluoroalkyl substances (PFAS) can impair mitochondrial bioenergetics, which is a vital process for cellular energy production. However, their effects on wild, free-living organisms remain unexplored. Using red blood cells, we investigated how foraging habits, inferred from stable isotopes, and contaminant exposure were associated with mitochondrial bioenergetics in breeding Scopoli's shearwaters (Calonectris diomedea), a top marine predator in the Mediterranean Sea. We found higher concentrations of Hg, but not of total PFAS, in older individuals and in males compared to females. Our results also indicate dietary pollutant exposure: Hg, but not total PFAS, was higher in birds with a higher trophic position and in those foraging closer to shores. Additionally, higher Hg concentration was linked to higher mitochondrial proton leakage (LEAK), reflecting reduced efficiency to couple oxygen consumption to energy production. In contrast, specific PFAS were negatively associated with LEAK, suggesting a potential impairment in the regulation of mitochondrial membrane potential through proton conductance, a key mechanism protecting cells from oxidative stress. Our study highlights how foraging ecology shapes pollutant exposure and its consequences for mitochondria bioenergetics in an apex predator of conservation interest.

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污染暴露会影响野生海鸟的线粒体生物能量。

实验室研究表明，汞（Hg）以及全氟烷基和多氟烷基物质（PFAS）可损害线粒体生物能量学，而线粒体生物能量学是细胞能量产生的一个重要过程。然而，它们对野生的、自由生活的生物的影响仍未被探索。利用红细胞，我们研究了从稳定同位素推断的觅食习惯和污染物暴露如何与地中海顶级海洋捕食者东Scopoli's shearwaters （Calonectris diomedea）繁殖过程中的线粒体生物能量学相关。与女性相比，我们在老年人和男性中发现了更高的汞浓度，但没有发现总PFAS。我们的研究结果还表明，饮食污染物暴露：在营养地位较高的鸟类和靠近海岸觅食的鸟类中，汞含量较高，但不是总PFAS。此外，较高的汞浓度与较高的线粒体质子泄漏（LEAK）有关，反映了将氧气消耗与能量生产相结合的效率降低。相比之下，特异性PFAS与LEAK呈负相关，表明通过质子电导调节线粒体膜电位可能存在损伤，而质子电导是保护细胞免受氧化应激的关键机制。我们的研究强调了觅食生态如何塑造污染物暴露及其对保护利益的顶级捕食者线粒体生物能量学的影响。

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

Environment & Health 环境科学、健康科学-

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期刊介绍： Environment & Health a peer-reviewed open access journal is committed to exploring the relationship between the environment and human health.As a premier journal for multidisciplinary research Environment & Health reports the health consequences for individuals and communities of changing and hazardous environmental factors. In supporting the UN Sustainable Development Goals the journal aims to help formulate policies to create a healthier world.Topics of interest include but are not limited to:Air water and soil pollutionExposomicsEnvironmental epidemiologyInnovative analytical methodology and instrumentation (multi-omics non-target analysis effect-directed analysis high-throughput screening etc.)Environmental toxicology (endocrine disrupting effect neurotoxicity alternative toxicology computational toxicology epigenetic toxicology etc.)Environmental microbiology pathogen and environmental transmission mechanisms of diseasesEnvironmental modeling bioinformatics and artificial intelligenceEmerging contaminants (including plastics engineered nanomaterials etc.)Climate change and related health effectHealth impacts of energy evolution and carbon neutralizationFood and drinking water safetyOccupational exposure and medicineInnovations in environmental technologies for better healthPolicies and international relations concerned with environmental health