Climate change impacts to foraging seascapes for a highly migratory top predator.

IF 3.4 1区生物学 Q2 ECOLOGY

Movement Ecology Pub Date : 2025-05-09 DOI:10.1186/s40462-025-00558-1

Barbara Muhling, Stephanie Snyder, Elliott L Hazen, Rebecca Whitlock, Jong-Yeon Park, Charles A Stock, Barbara A Block

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引用次数: 0

Abstract

Background: Climate change is impacting the distribution and movement of mobile marine organisms globally. Statistical species distribution models are commonly used to explain past patterns and anticipate future shifts. However, purely correlative models can fail under novel environmental conditions, or omit key mechanistic processes driving species habitat use.

Methods: Here, we used a unique combination of laboratory measurements, field observations, and environmental predictors to investigate spatial variability in energetic seascapes for juvenile North Pacific albacore tuna (Thunnus alalunga). This species undertakes some of the longest migrations of any finfish, but their susceptibility to climate-driven habitat changes is poorly understood. We first built a framework based on Generalized Additive Models to understand mechanisms of energy gain and loss in albacore, and how these are linked to ocean conditions. We then applied the framework to projections from an ensemble of earth system models to quantify changes in thermal and foraging habitats between historical (1971-2000) and future (2071-2100) time periods.

Results: We show how albacore move seasonally between feeding grounds in the California Current System and the offshore North Pacific, foraging most successfully in spring and summer. The thermal corridors used for migration largely coincide with minimum metabolic costs of movement. Future warming may result in loss of favorable thermal habitat in the sub-tropics and a reduction in total habitat area, but allow increased access to productive and energetically favorable sub-arctic ecosystems. Importantly, while thermal considerations suggest a loss in habitat area, forage considerations suggest that these losses may be offset by more energetically favorable conditions in the habitat that remains. In addition, the energetic favorability of coastal foraging areas may increase in future, with decreasing suitability of offshore foraging grounds. Our results clearly show the importance of moving beyond temperature when considering climate change impacts on marine species and their movement ecology.

Conclusions: Considering energetic seascapes adds essential mechanistic underpinning to projections of habitat gain and loss, particularly for highly migratory animals. Overall, improved understanding of mechanisms driving migration behavior, physiological constraints, and behavioral plasticity is required to better anticipate how climate change will impact pelagic marine ecosystems.

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气候变化对高度迁徙的顶级捕食者觅食海景的影响。

背景：气候变化正在影响全球海洋生物的分布和运动。统计物种分布模型通常用于解释过去的模式和预测未来的变化。然而，纯粹相关的模型在新的环境条件下可能失效，或者忽略了驱动物种栖息地利用的关键机制过程。方法：采用实验室测量、野外观测和环境预测相结合的方法，研究了北太平洋长鳍金枪鱼幼鱼活力海景的空间变异性。该物种在所有鱼类中迁徙时间最长，但它们对气候驱动的栖息地变化的敏感性尚不清楚。我们首先建立了一个基于广义可加模型的框架，以了解长鳍金枪鱼的能量增益和损失机制，以及这些机制与海洋条件的关系。然后，我们将该框架应用于一系列地球系统模型的预测，以量化历史时期（1971-2000年）和未来时期（2071-2100年）热生境和觅食生境的变化。结果：我们展示了长鳍金枪鱼如何在加利福尼亚洋流系统的觅食地和北太平洋近海之间季节性移动，在春季和夏季觅食最成功。用于迁徙的热走廊在很大程度上与迁徙的最低代谢成本一致。未来的变暖可能导致亚热带有利的热生境的丧失和生境总面积的减少，但可以增加获得生产性和能量有利的亚北极生态系统的机会。重要的是，虽然热因素表明栖息地面积的损失，但饲料方面的考虑表明，这些损失可能被栖息地中剩余的更有利的能量条件所抵消。此外，随着近海觅食地适宜性的降低，未来沿海觅食区的能量有利度可能会增加。我们的研究结果清楚地表明，在考虑气候变化对海洋物种及其运动生态学的影响时，超越温度的重要性。结论：考虑充满活力的海景为预测栖息地的增减增加了必要的机制基础，特别是对于高度迁徙的动物。总的来说，为了更好地预测气候变化将如何影响远洋海洋生态系统，需要更好地理解驱动迁移行为的机制、生理约束和行为可塑性。

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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来源期刊

Movement Ecology Agricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics

CiteScore

6.60

自引率

4.90%

发文量

审稿时长

23 weeks

期刊介绍： Movement Ecology is an open-access interdisciplinary journal publishing novel insights from empirical and theoretical approaches into the ecology of movement of the whole organism - either animals, plants or microorganisms - as the central theme. We welcome manuscripts on any taxa and any movement phenomena (e.g. foraging, dispersal and seasonal migration) addressing important research questions on the patterns, mechanisms, causes and consequences of organismal movement. Manuscripts will be rigorously peer-reviewed to ensure novelty and high quality.