Pushed waves, trailing edges, and extreme events: Eco-evolutionary dynamics of a geographic range shift in the owl limpet, Lottia gigantea
Pushed waves, trailing edges, and extreme events: Eco-evolutionary dynamics of a geographic range shift in the owl limpet, Lottia gigantea
As climatic variation re-shapes global biodiversity, understanding eco-evolutionary feedbacks during species range shifts is of increasing importance. Theory on range expansions distinguishes between two different forms: “pulled” and “pushed” waves. Pulled waves occur when the source of the expansion comes from low-density peripheral populations, while pushed waves occur when recruitment to the expanding edge is supplied by high-density populations closer to the species' core. How extreme events shape pushed/pulled wave expansion events, as well as trailing-edge declines/contractions, remains largely unexplored. We examined eco-evolutionary responses of a marine invertebrate (the owl limpet, Lottia gigantea) that increased in abundance during the 2014–2016 marine heatwaves near the poleward edge of its geographic range in the northeastern Pacific. We used whole-genome sequencing from 19 populations across >11 degrees of latitude to characterize genomic variation, gene flow, and demographic histories across the species' range. We estimated present-day dispersal potential and past climatic stability to identify how contemporary and historical seascape features shape genomic characteristics. Consistent with expectations of a pushed wave, we found little genomic differentiation between core and leading-edge populations, and higher genomic diversity at range edges. A large and well-mixed population in the northern edge of the species' range is likely a result of ocean current anomalies increasing larval settlement and high-dispersal potential across biogeographic boundaries. Trailing-edge populations have higher differentiation from core populations, possibly driven by local selection and limited gene flow, as well as high genomic diversity likely as a result of climatic stability during the Last Glacial Maximum. Our findings suggest that extreme events can drive poleward range expansions that carry the adaptive potential of core populations, while also cautioning that trailing-edge extirpations may threaten unique evolutionary variation. This work highlights the importance of understanding how both trailing and leading edges respond to global change and extreme events.
demographic history, eco-evolutionary, gene flow, genomic variation, larval simulation, population assignment, species distribution models
Nielson, Erica S.
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Walkes, Samuel
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Sones, Jacqueline L.
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Fenberg, Phillip B.
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Paz-Garcia, David A.
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Cameron, Brenda B.
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Grosberg, Richard K.
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Sanford, Eric
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Bay, Rachael A.
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23 July 2024
Nielson, Erica S.
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Walkes, Samuel
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Sones, Jacqueline L.
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Fenberg, Phillip B.
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Paz-Garcia, David A.
755124bb-873e-43ca-a9a1-8cb2b505e6ea
Cameron, Brenda B.
66788f9e-2f4a-463b-9e6c-49c234265e5d
Grosberg, Richard K.
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Sanford, Eric
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Bay, Rachael A.
f23e5d00-ca42-463e-9bc0-f27ea9b9f4ba
Nielson, Erica S., Walkes, Samuel, Sones, Jacqueline L., Fenberg, Phillip B., Paz-Garcia, David A., Cameron, Brenda B., Grosberg, Richard K., Sanford, Eric and Bay, Rachael A.
(2024)
Pushed waves, trailing edges, and extreme events: Eco-evolutionary dynamics of a geographic range shift in the owl limpet, Lottia gigantea.
Global Change Biology, 30 (7), [e17414].
(doi:10.1111/gcb.17414).
Abstract
As climatic variation re-shapes global biodiversity, understanding eco-evolutionary feedbacks during species range shifts is of increasing importance. Theory on range expansions distinguishes between two different forms: “pulled” and “pushed” waves. Pulled waves occur when the source of the expansion comes from low-density peripheral populations, while pushed waves occur when recruitment to the expanding edge is supplied by high-density populations closer to the species' core. How extreme events shape pushed/pulled wave expansion events, as well as trailing-edge declines/contractions, remains largely unexplored. We examined eco-evolutionary responses of a marine invertebrate (the owl limpet, Lottia gigantea) that increased in abundance during the 2014–2016 marine heatwaves near the poleward edge of its geographic range in the northeastern Pacific. We used whole-genome sequencing from 19 populations across >11 degrees of latitude to characterize genomic variation, gene flow, and demographic histories across the species' range. We estimated present-day dispersal potential and past climatic stability to identify how contemporary and historical seascape features shape genomic characteristics. Consistent with expectations of a pushed wave, we found little genomic differentiation between core and leading-edge populations, and higher genomic diversity at range edges. A large and well-mixed population in the northern edge of the species' range is likely a result of ocean current anomalies increasing larval settlement and high-dispersal potential across biogeographic boundaries. Trailing-edge populations have higher differentiation from core populations, possibly driven by local selection and limited gene flow, as well as high genomic diversity likely as a result of climatic stability during the Last Glacial Maximum. Our findings suggest that extreme events can drive poleward range expansions that carry the adaptive potential of core populations, while also cautioning that trailing-edge extirpations may threaten unique evolutionary variation. This work highlights the importance of understanding how both trailing and leading edges respond to global change and extreme events.
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Nielson et al_2024
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Accepted/In Press date: 21 June 2024
e-pub ahead of print date: 23 July 2024
Published date: 23 July 2024
Keywords:
demographic history, eco-evolutionary, gene flow, genomic variation, larval simulation, population assignment, species distribution models
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Local EPrints ID: 492761
URI: http://eprints.soton.ac.uk/id/eprint/492761
ISSN: 1354-1013
PURE UUID: ef51b2ac-067e-41d0-b25b-c1dc4ed36af3
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Date deposited: 13 Aug 2024 16:56
Last modified: 17 Aug 2024 01:46
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Contributors
Author:
Erica S. Nielson
Author:
Samuel Walkes
Author:
Jacqueline L. Sones
Author:
David A. Paz-Garcia
Author:
Brenda B. Cameron
Author:
Richard K. Grosberg
Author:
Eric Sanford
Author:
Rachael A. Bay
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