Integrating multi-level approaches to assess blue mussel (Mytilus spp.) responses to short-term temperature and salinity changes.

IF 3.2 3区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Marine environmental research Pub Date : 2025-10-01 Epub Date: 2025-08-07 DOI:10.1016/j.marenvres.2025.107436

Colleen Guinle, Ridho Wiranda Gurning, Clément Baratange, Bruno Cognie, Aurélie Mossion, Gaëtane Wielgosz-Collin, Samuel Bertrand, Grégory Montiel, Laurence Poirier, Paul Déléris, Aurore Zalouk-Vergnoux

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引用次数: 0

Abstract

Climate change is exacerbating temperature and salinity variations in marine ecosystems, thereby challenging the physiological resilience of bivalves like blue mussels (Mytilus spp.). Despite comprehensive studies on these organisms' physiological and molecular responses to such environmental stress, our understanding of tissue-specific adaptations and the role of lipid metabolism is limited. This study investigated the short-term effects of warming (+3.5 °C and +6.0 °C) and reduced salinity (-6 and -12 PSU) on Mytilus spp. using an integrative approach that included physiological indicators, lipidomic, biochemical, and molecular analyses across several tissues. The mussel clearance rate increased under thermal stress and decreased under hyposaline stress. Both stressors resulted in a lower condition index, suggesting energy depletion and specific metabolic changes. Lipidomic analysis revealed significant fatty acid and lipid composition alterations, indicating membrane remodelling to maintain cellular integrity. Gene expression analyses demonstrated distinct responses across tissues: the gills activated protective mechanisms (i.e., up-regulation of heat shock protein-encoding genes (hsp)) in response to both stressors, whereas the digestive gland prioritised energy conservation and damage mitigation (i.e., down-regulation of hsp, metabolic, and apoptotic marker genes). These divergent responses indicate that mussels use tissue-specific strategies to balance stress resistance and metabolic trade-offs. Despite demonstrating notable physiological plasticity, our findings highlight the significant metabolic costs associated with environmental stress adaptation. This study provides new insights into the complex, multi-level strategies that Mytilus spp. employ to maintain homeostasis in the face of multiple stressors, with implications for predicting their resilience under future climate conditions.

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综合多层次方法评估蓝贻贝（Mytilus spp.）对短期温度和盐度变化的反应。

气候变化加剧了海洋生态系统的温度和盐度变化，从而挑战了蓝贻贝（Mytilus spp.）等双壳类动物的生理恢复能力。尽管对这些生物对这种环境胁迫的生理和分子反应进行了全面的研究，但我们对组织特异性适应和脂质代谢作用的了解有限。本研究采用综合方法研究了增温（+3.5°C和+6.0°C）和降低盐度（-6和-12 PSU）对贻贝的短期影响，包括生理指标、脂质组学、生化和分子分析。热胁迫下贻贝清除率升高，低盐胁迫下贻贝清除率降低。两种应激源均导致较低的状态指数，提示能量消耗和特定代谢变化。脂质组学分析显示显著的脂肪酸和脂质组成改变，表明膜重塑以维持细胞完整性。基因表达分析显示了不同组织的不同反应：鳃激活保护机制（即上调热休克蛋白编码基因（hsp））以应对这两种应激源，而消化腺优先考虑能量保存和损伤减轻（即下调热休克蛋白编码基因、代谢和凋亡标记基因）。这些不同的反应表明贻贝使用组织特异性策略来平衡抗逆性和代谢权衡。尽管表现出显著的生理可塑性，我们的研究结果强调了与环境应激适应相关的显著代谢成本。该研究为贻贝在面对多种压力源时维持体内平衡所采用的复杂、多层次策略提供了新的见解，并对预测其在未来气候条件下的适应能力具有重要意义。

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来源期刊

Marine environmental research 环境科学-毒理学

CiteScore

5.90

自引率

3.00%

发文量

217

审稿时长

46 days

期刊介绍： Marine Environmental Research publishes original research papers on chemical, physical, and biological interactions in the oceans and coastal waters. The journal serves as a forum for new information on biology, chemistry, and toxicology and syntheses that advance understanding of marine environmental processes. Submission of multidisciplinary studies is encouraged. Studies that utilize experimental approaches to clarify the roles of anthropogenic and natural causes of changes in marine ecosystems are especially welcome, as are those studies that represent new developments of a theoretical or conceptual aspect of marine science. All papers published in this journal are reviewed by qualified peers prior to acceptance and publication. Examples of topics considered to be appropriate for the journal include, but are not limited to, the following: – The extent, persistence, and consequences of change and the recovery from such change in natural marine systems – The biochemical, physiological, and ecological consequences of contaminants to marine organisms and ecosystems – The biogeochemistry of naturally occurring and anthropogenic substances – Models that describe and predict the above processes – Monitoring studies, to the extent that their results provide new information on functional processes – Methodological papers describing improved quantitative techniques for the marine sciences.