Research Paper

The role of genetic structure in the adaptive divergence of populations experiencing saltwater intrusion due to relative sea-level rise

  1. K. M. Purcell1,2,*,
  2. A. Hitch1,3,
  3. S. Martin1,4,
  4. P. L. Klerks1,
  5. P. L. Leberg1

Article first published online: 1 NOV 2012

DOI: 10.1111/jeb.12016

Issue

Journal of Evolutionary Biology

Journal of Evolutionary Biology

Volume 25, Issue 12, pages 2623–2632, December 2012

Additional Information

How to Cite

Purcell, K. M., Hitch, A., Martin, S., Klerks, P. L. and Leberg, P. L. (2012), The role of genetic structure in the adaptive divergence of populations experiencing saltwater intrusion due to relative sea-level rise. Journal of Evolutionary Biology, 25: 2623–2632. doi: 10.1111/jeb.12016

Author Information

  1. 1

    Department of Biology, University of Louisiana at Lafayette, Lafayette, LA, USA

  2. 2

    Beaufort Laboratory, NOAA: Southeast Fisheries Science Center, Beaufort, NC, USA

  3. 3

    Museum of Wildlife and Fish Biology, University of California at Davis, Davis, CA, USA

  4. 4

    Apalachicola Field Laboratory, Florida Fish and Wildlife Conservation Commission, Fish and Wildlife Research Institute, Eastpoint, FL, USA

* Correspondence: Kevin M. Purcell, Beaufort Laboratory, NOAA: Southeast Fisheries Science Center, 101 Pivers Island Road, Beaufort, NC 28516-9722, USA. Tel.: +1 252 728 8761; fax: +1 252 728 8619;
e-mail: kevin@kevin-purcell.com

Publication History

  1. Issue published online: 16 NOV 2012
  2. Article first published online: 1 NOV 2012
  3. Manuscript Accepted: 7 SEP 2012
  4. Manuscript Received: 16 AUG 2011

Funded by

  • Louisiana Board of Regents
  • United States Environmental Protection Agency's Science
  • EPA's STAR program. Grant Number: R-82942001

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Keywords:

  • adaptation;
  • ecological genetics;
  • population genetics;
  • quantitative genetics

Abstract

Saltwater intrusion into estuaries creates stressful conditions for nektonic species. Previous studies have shown that Gambusia affinis populations with exposure to saline environments develop genetic adaptations for increased survival during salinity stress. Here, we evaluate the genetic structure of G. affinis populations, previously shown to have adaptations for increased salinity tolerance, and determine the impact of selection and gene flow on structure of these populations. We found that gene flow was higher between populations experiencing different salinity regimes within an estuary than between similar marsh types in different estuaries, suggesting the development of saline-tolerant phenotypes due to local adaptation. There was limited evidence of genetic structure along a salinity gradient, and only some of the genetic variation among sites was correlated with salinity. Our results suggest limited structure, combined with selection to saltwater intrusion, results in phenotypic divergence in spite of a lack of physical barriers to gene flow.

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