Ecological drivers of movement for two sympatric marine predators in the California current large marine ecosystem.

IF 3.4 1区生物学 Q2 ECOLOGY

Movement Ecology Pub Date : 2025-03-18 DOI:10.1186/s40462-025-00542-9

Ladd M Irvine, Barbara A Lagerquist, Gregory S Schorr, Erin A Falcone, Bruce R Mate, Daniel M Palacios

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引用次数: 0

Abstract

Background: An animal's movement reflects behavioral decisions made to address ecological needs; specifically, that movement will become less directional in regions with high prey availability, indicating foraging behavior. In the marine realm, animal behavior occurs below the sea surface and is difficult to observe. We used an extensive satellite tagging dataset to explore how physical and biological habitat characteristics influence blue (Balaenoptera musculus) and fin (B. physalus) whale movement and foraging behavior in the California Current Ecosystem across four known bioregions.

Methods: We fitted movement models to 14 years of blue whale satellite tracking data and 13 years of fin whale data to characterize their movement persistence, with higher move persistence values representing more directional movement and lower move persistence values representing less directional movement. Models were evaluated against a range of physical and biological environmental predictors to identify significant correlates of low move persistence (i.e., presumed intensified foraging behavior). We then used data from a subset of sensor-equipped tags that monitored vertical behavior (e.g., dive and feeding), in addition to movement, to test the relationship between vertical behavior and movement persistence.

Results: Low move persistence was strongly correlated with shallower water depth and sea surface height for both species, with additional effects of chlorophyll-a concentration, vorticity and marine nekton biomass for blue whales. Data from sensor-equipped tags additionally showed that low move persistence occurred when whales made more numerous feeding dives. Temporal patterns of bioregion occupancy coincided with seasonal peaks in productivity. Most blue whale low-move-persistence movements occurred in the northern, nearshore bioregion with a late-season peak in productivity and were evenly distributed across all bioregions for fin whales.

Conclusions: We demonstrated that low move persistence is indicative of increased feeding behavior for both blue and fin whales. The environmental drivers of low move persistence were similar to those previously identified for survey-based species distribution models, linking environmental metrics to subsurface behavior. Occupancy and movement behavior patterns across bioregions indicate both species moved to exploit seasonal and spatial variability in productivity, with blue whales especially focusing on the bioregion of highest productivity during late summer and fall.

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加州当前大型海洋生态系统中两种同域海洋捕食者运动的生态驱动因素。

背景：动物的运动反映了为了满足生态需求而做出的行为决定；具体来说，在猎物可用性高的地区，这种运动将变得不那么定向，这表明了觅食行为。在海洋领域，动物的行为发生在海面以下，很难观察到。我们使用广泛的卫星标记数据集来探索物理和生物栖息地特征如何影响加州洋流生态系统中四个已知生物区域的蓝鲸（Balaenoptera musculus）和鳍鲸（B. physalus）的运动和觅食行为。方法：采用14年蓝鲸卫星跟踪数据和13年长须鲸数据拟合运动模型来表征它们的运动持续性，运动持续性值越高代表方向性运动越多，运动持续性值越低代表方向性运动越少。根据一系列物理和生物环境预测因子对模型进行评估，以确定低移动持久性（即假定的强化觅食行为）的重要相关性。然后，我们使用配备传感器的标签子集的数据来监测垂直行为（例如，潜水和进食），以及运动，以测试垂直行为和运动持久性之间的关系。结果：蓝鲸的低移动持久性与较浅的水深和海面高度密切相关，并受叶绿素-a浓度、涡度和海洋浮游生物生物量的影响。来自配备传感器的标签的数据还显示，当鲸鱼进行更多的觅食潜水时，低移动持久性就会发生。生物区域占用的时间格局与生产力的季节高峰一致。大多数蓝鲸的低迁移持久性运动发生在北部近岸生物区，其生产力在季节后期达到高峰，并且均匀分布在所有长须鲸生物区。结论：我们证明了低移动持久性表明蓝鲸和长须鲸的摄食行为增加。低迁移持久性的环境驱动因素与之前基于调查的物种分布模型相似，将环境指标与地下行为联系起来。跨生物区域的占用和移动行为模式表明，这两个物种都在利用生产力的季节和空间变化，蓝鲸特别关注夏末和秋季生产力最高的生物区域。

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.