Determining physiological responses of mussels (Mytilus edulis) to hypoxia by combining multiple sensor techniques.

IF 2.5 3区环境科学与生态学 Q2 BIODIVERSITY CONSERVATION

Conservation Physiology Pub Date : 2025-04-11 eCollection Date: 2025-01-01 DOI:10.1093/conphys/coaf023

Emily Adria Peterson, Marinus Cornelis Keur, Michael Yeboah, Thomas van de Grootevheen, Luke Moth, Pauline Kamermans, Tinka Murk, Myron A Peck, Edwin Foekema

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引用次数: 0

Abstract

Intertidal bivalves survive longer without oxygen when aerially exposed during low tide than when submerged in hypoxic water. To understand this, we combined three biosensors to continuously monitor responses of individual blue mussels (Mytilus edulis) to aerial exposure in simulated low-tide conditions and during aqueous hypoxia. A valve sensor, heart rate monitor, and an in-shell oxygen microsensor simultaneously recorded behavioural and physiological responses. During aerial exposure, which often occurs in the intertidal, all individuals immediately closed their valves, rapidly depleted in-shell oxygen, and decreased their heart rate. This suggested a shift to anaerobic metabolism and reduced activity as mechanisms to save energy and survive in-shell anoxia during 'low-tide' conditions. At the onset of exposure to hypoxic (<1 mg O₂/L) water, however, all mussels fully opened their valves, with 75% of the individuals increasing valve activity for at least 1 hour (the duration of our measurements), possibly in an attempt to collect more oxygen by increasing filtration activity. Only 25% of the mussels closed their valves after about 40 minutes of aqueous hypoxia, shifting to the energy efficient strategy used during aerial exposure. As the valves of most individuals remained open during hypoxia, a mussel does not appear to need to close its valve to begin the transition to anaerobic metabolism. Interindividual variation in responses was much lower after exposure to air compared to aqueous hypoxia when the heart rate of most mussels either steadily declined or became highly erratic. Differences in energy expenditure during these different types of exposures likely explains why most mussels, at least from the population we studied, can survive longer during exposure to air compared to aqueous hypoxia, a situation that could occur under situations of elevated temperature in waters with high nutrient loads.

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结合多种传感器技术测定贻贝（Mytilus edulis）对缺氧的生理反应。

潮间带双壳类在低潮时暴露在空中，在没有氧气的情况下比淹没在缺氧水中存活的时间更长。为了了解这一点，我们结合了三个生物传感器，连续监测蓝贻贝（Mytilus edulis）个体在模拟低潮条件和水缺氧条件下对空气暴露的反应。一个阀门传感器、心率监测器和一个壳内氧气微传感器同时记录了行为和生理反应。在潮间带经常发生的空气暴露中，所有个体立即关闭阀门，迅速耗尽壳内氧气，并降低心率。这表明，在“低潮”条件下，向无氧代谢和活性降低的转变是节省能量和在壳缺氧中生存的机制。然而，在暴露于低氧（2/L）水中时，所有贻贝都完全打开了阀门，75%的贻贝在至少1小时（我们测量的持续时间）内增加了阀门的活动，可能是为了通过增加过滤活性来收集更多的氧气。在大约40分钟的水中缺氧后，只有25%的贻贝关闭了阀门，转向了在空中暴露时使用的节能策略。由于大多数个体的瓣膜在缺氧时保持打开状态，贻贝似乎不需要关闭它的瓣膜来开始向无氧代谢的过渡。与水缺氧相比，暴露在空气中后，大多数贻贝的心率要么稳定下降，要么变得高度不稳定，个体间的反应差异要小得多。在这些不同类型的暴露中，能量消耗的差异可能解释了为什么大多数贻贝，至少从我们研究的种群中，在暴露于空气中比在水中缺氧时存活的时间更长，这种情况可能发生在水温升高、营养负荷高的情况下。

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

Conservation Physiology Environmental Science-Management, Monitoring, Policy and Law

CiteScore

5.10

自引率

3.70%

发文量

审稿时长

11 weeks

期刊介绍： Conservation Physiology is an online only, fully open access journal published on behalf of the Society for Experimental Biology. Biodiversity across the globe faces a growing number of threats associated with human activities. Conservation Physiology will publish research on all taxa (microbes, plants and animals) focused on understanding and predicting how organisms, populations, ecosystems and natural resources respond to environmental change and stressors. Physiology is considered in the broadest possible terms to include functional and mechanistic responses at all scales. We also welcome research towards developing and refining strategies to rebuild populations, restore ecosystems, inform conservation policy, and manage living resources. We define conservation physiology broadly and encourage potential authors to contact the editorial team if they have any questions regarding the remit of the journal.