Nonconsumptive effects of a range‐expanding predator on juvenile lobster (<i>Homarus americanus</i>) population dynamics

McMahan, Marissa D.; Grabowski, Jonathan H.

doi:10.1002/ecs2.2867

Cited by 16 publications

(12 citation statements)

References 72 publications

(191 reference statements)

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“…This could arise due to density-dependent habitat selection if these species were declining in abundance, causing each range edge to collapse toward the range center (Blanchard et al, 2005). At the equatorward edge, competition or predation from the south could be driving edge retraction (Kordas et al, 2011); for example, the rapid contraction of the equatorward range edge of American lobster could be due to increased predation from species like black sea bass shifting up the coast (McMahan & Grabowski, 2019) or increased mortality from a temperature-related disease (Groner et al, 2018). At the poleward edge, species interactions (HilleRisLambers et al, 2013), priority effects (Fukami, 2015), dispersal limitation (Poloczanska et al, 2011), or a lack of non-thermal habitat (McHenry et al, 2019) could all inhibit northward shifts.…”

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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“…This could arise due to densitydependent habitat selection if these species were declining in abundance, causing each range edge to collapse toward the range center (Blanchard et al 2005). At the equatorward edge, competition or predation from the south could be driving edge retraction (Kordas et al 2011); for example, the rapid contraction of the equatorward range edge of American lobster could be due to increased predation from species like black sea bass shifting up the coast (McMahan and Grabowski 2019) or increased mortality from a temperaturerelated disease (Groner et al 2018). At the poleward edge, species interactions (HilleRisLambers et al 2013), priority effects (Fukami 2015), dispersal limitation (Poloczanska et al 2011), or a lack of non-thermal habitat (McHenry et al 2019) could all inhibit northward shifts.…”

Section: Discussionmentioning

confidence: 99%

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

Fredston

Pinsky

Selden

et al. 2020

Preprint

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Understanding range edges is key to addressing fundamental biogeographic questions about abiotic and biotic drivers of species distributions. Range edges are where colonization and extirpation happen, so their dynamics are also important for natural resource management and conservation. We quantified positions for 153 range edges of marine fishes and invertebrates from three US continental shelf regions using decades of survey data and a spatiotemporal model to account for changes in survey design. We analyzed whether range edges maintained their edge thermal niches-temperature extremes at the range edgeover time. Most range edges (86%) maintained either cold or warm temperature extremes; 73% maintained both. However, the substantial fraction of range edges that altered their thermal niche underscore the multiplicity of relevant drivers. This study suggests that temperate marine species largely maintained their edge thermal niches during rapid change and provides a blueprint for testing temperature tracking of species range edges.

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“…The Northwest Atlantic is one of the fastest warming regions in the ocean [23]. Centropristis striata, the most northerly-distributed grouper species (Family Serranidae) in the Northwest Atlantic [26], has seemingly responded to the warming in this region as evidenced by higher abundances in the northern extent of their historic range [27] and by expanding their geographic range to the extent that they are now commonly found in the southern Gulf of Maine during spring and summer [28][29][30] where they had only been found occasionally in the past [26]. One potential mechanism for this range expansion is that overwintering mortality is reduced as temperatures on the Northeast shelf have increased.…”

Section: Introductionmentioning

confidence: 99%

Overwintering survivorship and growth of young-of-the-year black sea bass Centropristis striata

2020

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Overwintering conditions have long been known to affect fish survival and year-class strength as well as determine the poleward range limit of many temperate fishes. Despite this known importance, mechanisms controlling overwintering mortality are poorly understood and the tolerance of marine fishes to the combined effects of winter temperature, salinity, and size is rarely quantified. In recent years, higher abundances of the temperate Serranid, black sea bass Centropristis striata, have been observed at latitudes further north than their traditional range suggesting that warming water temperatures, particularly during winter, may be facilitating the establishment of a population at more northern latitudes. To examine overwintering survival of C. striata, the combined effects of temperature, salinity and body mass were quantified in laboratory experiments. We identified 6˚C as the lower incipient lethal temperature for C. striata, below which fish cease feeding, lose weight rapidly and die within 32 days. A short cold exposure experiment indicated that temperatures below 5˚C resulted in mortality events that continued even as the temperature increased slowly to 10˚C, indicating that even short cold snaps can impact survival and recruitment in this species. Importantly, fish in lower salinity lived significantly longer than fish at higher salinity at both 3˚C and 5˚C, suggesting that osmoregulatory stress plays a role in overwintering mortality in this species. Size was not a critical factor in determining overwintering survival of young-of-the-year (YOY) C. striata. Overwintering survival of YOY C. striata can be effectively predicted as a function of temperature and salinity and their interaction with an accelerated failure model to project future range limits. Identifying temperature thresholds may be a tractable way to incorporate environmental factors into population models and stock assessment models in fishes.

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Nonconsumptive effects of a range‐expanding predator on juvenile lobster (Homarus americanus) population dynamics

Cited by 16 publications

References 72 publications

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

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

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

Overwintering survivorship and growth of young-of-the-year black sea bass Centropristis striata

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