North Pacific warming shifts the juvenile range of a marine apex predator

Tanaka, Kisei R.; Houtan, Kyle S. Van; Mailander, Eric; Dias, Beatriz S.; Galginaitis, Carol; O’Sullivan, John B.; Lowe, Christopher G.

doi:10.1038/s41598-021-82424-9

Cited by 48 publications

(44 citation statements)

References 64 publications

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“…Sessile invertebrates are particularly vulnerable to dispersal limitation if prevailing currents do not align with local climate velocities, as in the Northeast (Fuchs et al, 2020;Molinos et al, 2017). On the West Coast, threshold responses to nonlinear temperature change may also structure species distributions; El Niño events sometimes cause the transport of anomalously warm water up the coastline, facilitating transient poleward range extensions of species-some of which have persisted after these warm events ended (Leising et al, 2015;Tanaka et al, 2021;Zacherl et al, 2003). The Eastern Bering Sea system's high degree of edge thermal niche tracking may be partly due to sea ice causing fairly stable winter temperatures there (Stabeno et al, 2001).…”

Section: Discussionmentioning

confidence: 99%

Range edges of North American marine species are tracking temperature over decades

Fredston

Pinsky

Selden

et al. 2021

Global Change Biology

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Human-caused global climate change now affects, directly or indirectly, all biomes and levels of biological organization (Scheffers et al., 2016). One of the most profound effects has been changes in the spatial distributions of species that align with shifting climates-up mountains, deeper in the oceans, and generally toward the poles (Parmesan & Yohe, 2003; Pecl et al., 2017).A strong correlation between regional climate change and shifting species ranges has been documented in many taxa (Chen et al., 2011;Pinsky et al., 2013). However, individualistic responses and "ecological surprises" are also common (La Sorte & Jetz, 2012;Poloczanska et al., 2011;Zhu et al., 2012), underscoring the need to consider the interplay of climatic constraints and non-climate processes in determining the edges of species ranges (Sexton et al., 2009; Urban et al., 2016).

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Section: Discussionmentioning

confidence: 99%

Range edges of North American marine species are tracking temperature over decades

Fredston

Pinsky

Selden

et al. 2021

Global Change Biology

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“…Oceanographic conditions are expected to become more extreme with climate change, leading to shifts in the distributions and migratory pathways of sea turtles, sea birds, marine mammals, and pelagic fishes (Hazen et al, 2012b). If a thermal corridor across the Eastern Pacific Barrier were to open more frequently in a warming ocean, it may result in an increase in the relative abundance of loggerheads and other highly migratory marine megafauna shifting from the Central North Pacific to foraging grounds along the eastern Pacific coast (e.g., Pacific bluefin tuna (Kitagawa et al, 2007), white sharks (Tanaka et al, 2021), and northern elephant seals (Abrahms et al, 2018). Finally, a change in the distribution of protected species can pose increased conservation challenges.…”

Section: Discussionmentioning

confidence: 99%

Dynamic Thermal Corridor May Connect Endangered Loggerhead Sea Turtles Across the Pacific Ocean

et al. 2021

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The North Pacific Loggerhead sea turtle (Caretta caretta) undergoes one of the greatest of all animal migrations, nesting exclusively in Japan and re-emerging several years later along important foraging grounds in the eastern North Pacific. Yet the mechanisms that connect these disparate habitats during what is known as the “lost years” have remained poorly understood. Here, we develop a new hypothesis regarding a possible physical mechanism for habitat connectivity – an intermittent “thermal corridor” – using remotely sensed oceanography and 6 juvenile loggerhead sea turtles that formed part of a 15 year tracking dataset of 231 individuals (1997–2013). While 97% of individuals remained in the Central North Pacific, these 6 turtles (about 3%), continued an eastward trajectory during periods associated with anomalously warm ocean conditions. These few individuals provided a unique opportunity to examine previously unknown recruitment pathways. To support this hypothesis, we employed an independently derived data set using novel stable isotope analyses of bone growth layers and assessed annual recruitment over the same time period (n = 33, 1997–2012). We suggest evidence of a thermal corridor that may allow for pulsed recruitment of loggerheads to the North American coast as a function of ocean conditions. Our findings offer, for the first time, the opportunity to explore the development of a dynamic ocean corridor for this protected species, illuminating a longstanding mystery in sea turtle ecology.

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“…For coastally restricted species such as C. amblyrhynchos and S. tudes, public databases provide validated empirical observations in novel marine regions. Subjectively censoring such data sources falsely assumes that species ranges are either fixed or already perfectly understood [24]. For widespread pelagic species such as I. oxyrinchus and I. paucus , most extra-range observations are adjacent the ERM, perhaps reflecting more recent poleward expansions from ocean warming [24,25].…”

mentioning

confidence: 99%

“…Subjectively censoring such data sources falsely assumes that species ranges are either fixed or already perfectly understood [24]. For widespread pelagic species such as I. oxyrinchus and I. paucus , most extra-range observations are adjacent the ERM, perhaps reflecting more recent poleward expansions from ocean warming [24,25]. Figure 1 c crops our SDM output for I. paucus with its corresponding ERM, emphasizing the structure of habitat preferences the SDM provides that is missing from the comparatively flat ERM.…”

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confidence: 99%