Population genetic signatures of a climate change driven marine range extension

Shifts in species distribution, or ‘range shifts’, are one of the most commonly documented responses to ocean warming, with important consequences for the function and structure of ecosystems, and for socio-economic activities. Understanding the genetic signatures of range shifts can help build our...

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Veröffentlicht in:	Scientific reports 2018-06, Vol.8 (1), p.9558-12, Article 9558
Hauptverfasser:	Ramos, Jorge E., Pecl, Gretta T., Moltschaniwskyj, Natalie A., Semmens, Jayson M., Souza, Carla A., Strugnell, Jan M.
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Sprache:	eng
Schlagworte:	38/23 38/77 631/208 704/158/1745 704/158/2165 704/829/826 Climate change Gene flow Genetic diversity Genetic structure Geographical distribution Humanities and Social Sciences Marine ecosystems multidisciplinary Ocean warming Octopus tetricus Population Population genetics Population number Range extension Science Science (multidisciplinary) Structure-function relationships
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description	Shifts in species distribution, or ‘range shifts’, are one of the most commonly documented responses to ocean warming, with important consequences for the function and structure of ecosystems, and for socio-economic activities. Understanding the genetic signatures of range shifts can help build our knowledge of the capacity of species to establish and persist in colonised areas. Here, seven microsatellite loci were used to examine the population connectivity, genetic structure and diversity of Octopus tetricus , which has extended its distribution several hundred kilometres polewards associated with the southwards extension of the warm East Australian Current along south-eastern Australia. The historical distribution and the range extension zones had significant genetic differences but levels of genetic diversity were comparable. The population in the range extension zone was sub-structured, contained relatively high levels of self-recruitment and was sourced by migrants from along the entire geographic distribution. Genetic bottlenecks and changes in population size were detected throughout the range extension axis. Persistent gene flow from throughout the historical zone and moderate genetic diversity may buffer the genetic bottlenecks and favour the range extension of O. tetricus . These characteristics may aid adaptation, establishment, and long-term persistence of the population in the range extension zone.
doi_str_mv	10.1038/s41598-018-27351-y
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subjects	38/23 38/77 631/208 704/158/1745 704/158/2165 704/829/826 Climate change Gene flow Genetic diversity Genetic structure Geographical distribution Humanities and Social Sciences Marine ecosystems multidisciplinary Ocean warming Octopus tetricus Population Population genetics Population number Range extension Science Science (multidisciplinary) Structure-function relationships
title	Population genetic signatures of a climate change driven marine range extension
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