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Gene flow simulations demonstrate resistance of long-lived species to genetic erosion from habitat fragmentation

Publication ,  Journal Article
Fuller, MR; Doyle, MW
Published in: Conservation Genetics
December 1, 2018

Habitat fragmentation restricts the movement of individuals across a landscape. In terrestrial and aquatic systems, barriers to movement can modify population and community dynamics at local or regional scales. This study contrasted life history traits related to lifespan with habitat fragmentation to determine impacts on species population genetic structure in the Neuse River Basin, USA. For this, we simulated gene flow among evenly-spaced populations in a river network and tracked individual and population genetics for 200 years. The modeled scenarios represent a full cross between five life history strategies and four riverscapes representing varying degrees of fragmentation. The five life history strategies include species (based on freshwater mussels) with average lifespans ranging from 10 to 50 years and age at maturity from 2 to 6 years. The movement landscapes included a (1) panmictic, (2) stepping-stone landscape allowing movement to only neighboring populations during each dispersal event, (3) partially-fragmented landscape divided by dams currently in the network, and (4) fully-fragmented landscape. Results suggest species with shorter lifespans have higher population genetic structure in fragmented landscapes than species with longer lifespans. Furthermore, species with shorter lifespans in highly fragmented landscapes may be harboring genetic degradation or decline as allele fixation and loss. Although anthropogenic fragmentation of many river systems is only 100–200 years old, the simulation indicates that species can respond genetically in that period of time. Additionally, the time frame of the simulation suggests that genetic impacts of habitat fragmentation in some species present in the Neuse River Basin may not yet be manifesting and restoration activities could be successful.

Duke Scholars

Published In

Conservation Genetics

DOI

EISSN

1572-9737

ISSN

1566-0621

Publication Date

December 1, 2018

Volume

19

Issue

6

Start / End Page

1439 / 1448

Related Subject Headings

  • Evolutionary Biology
  • 41 Environmental sciences
  • 31 Biological sciences
  • 06 Biological Sciences
  • 05 Environmental Sciences
 

Citation

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ICMJE
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Fuller, M. R., & Doyle, M. W. (2018). Gene flow simulations demonstrate resistance of long-lived species to genetic erosion from habitat fragmentation. Conservation Genetics, 19(6), 1439–1448. https://doi.org/10.1007/s10592-018-1112-5
Fuller, M. R., and M. W. Doyle. “Gene flow simulations demonstrate resistance of long-lived species to genetic erosion from habitat fragmentation.” Conservation Genetics 19, no. 6 (December 1, 2018): 1439–48. https://doi.org/10.1007/s10592-018-1112-5.
Fuller, M. R., and M. W. Doyle. “Gene flow simulations demonstrate resistance of long-lived species to genetic erosion from habitat fragmentation.” Conservation Genetics, vol. 19, no. 6, Dec. 2018, pp. 1439–48. Scopus, doi:10.1007/s10592-018-1112-5.
Fuller MR, Doyle MW. Gene flow simulations demonstrate resistance of long-lived species to genetic erosion from habitat fragmentation. Conservation Genetics. 2018 Dec 1;19(6):1439–1448.
Journal cover image

Published In

Conservation Genetics

DOI

EISSN

1572-9737

ISSN

1566-0621

Publication Date

December 1, 2018

Volume

19

Issue

6

Start / End Page

1439 / 1448

Related Subject Headings

  • Evolutionary Biology
  • 41 Environmental sciences
  • 31 Biological sciences
  • 06 Biological Sciences
  • 05 Environmental Sciences