Evidence of local adaptation in a waterfall-climbing Hawaiian goby fish derived from coupled biophysical modeling of larval dispersal and post-settlement selection

Kristine N. Moody, Johanna L.K. Wren, Donald R. Kobayashi, Michael J. Blum, Margaret B. Ptacek, Richard W. Blob, Robert J. Toonen, Heiko L. Schoenfuss, Michael J. Childress

Research output: Contribution to journalArticlepeer-review

11 Scopus citations

Abstract

Background: Local adaptation of marine and diadromous species is thought to be a product of larval dispersal, settlement mortality, and differential reproductive success, particularly in heterogeneous post-settlement habitats. We evaluated this premise with an oceanographic passive larval dispersal model coupled with individual-based models of post-settlement selection and reproduction to infer conditions that underlie local adaptation in Sicyopterus stimpsoni, an amphidromous Hawaiian goby known for its ability to climb waterfalls. Results: Our model results demonstrated that larval dispersal is spatio-temporally asymmetric, with more larvae dispersed from the southeast (the Big Island) to northwest (Kaua'i) along the archipelago, reflecting prevailing conditions such as El Niño/La Niña oscillations. Yet connectivity is nonetheless sufficient to result in homogenous populations across the archipelago. We also found, however, that ontogenetic shifts in habitat can give rise to adaptive morphological divergence when the strength of predation-driven post-settlement selection crosses a critical threshold. Notably, our simulations showed that larval dispersal is not the only factor determining the likelihood of morphological divergence. We found adaptive potential and evolutionary trajectories of S. stimpsoni were greater on islands with stronger environmental gradients and greater variance in larval cohort morphology due to fluctuating immigration. Conclusions: Contrary to expectation, these findings indicate that immigration can act in concert with selection to favor local adaptation and divergence in species with marine larval dispersal. Further development of model simulations, parameterized to reflect additional empirical estimates of abiotic and biotic factors, will help advance our understanding of the proximate and ultimate mechanisms driving adaptive evolution, population resilience, and speciation in marine-associated species.

Original languageEnglish
Article number88
JournalBMC Evolutionary Biology
Volume19
Issue number1
DOIs
StatePublished - Apr 11 2019
Externally publishedYes

Funding

Funding was provided through National Science Foundation Doctoral Dissertation Improvement Grant (DEB-1310962) to Kristine N. Moody, the Department of Defense Strategic Environmental Research and Development Program awards RC-1646 and RC-2447 to Michael J. Blum, NSF grant IOS-0817794 to Richard W. Blob and Margaret B. Ptacek, NSF grant IOS-0817911 to Heiko L. Schoenfuss and Matthew L. Julius, NSF grant OCE-1260169 to Robert J. Toonen, and National Oceanic and Atmospheric Administration sponsored by the University of Hawaii Sea Grant College Program (UNIHI_-SEAGRANT R/EL-43 and R/IR-32 under Project R/SS-13), SOEST, under Institutional Grant No. NA14OAR4170071 from NOAA Office of SeaGrant, Department of Commerce, to Robert J. Toonen. The funding bodies had no role in the design of the study and collection, analysis, and interpretation of data or in writing the manuscript.

FundersFunder number
National Science FoundationIOS-0817911, IOS-0817794, OCE-1260169, DEB-1310962
National Oceanic and Atmospheric AdministrationR/SS-13, UNIHI_-SEAGRANT R/EL-43
Strategic Environmental Research and Development ProgramRC-2447, RC-1646

    Keywords

    • Hawai'i
    • individual-based models
    • larval transport
    • morphology
    • oceanography

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