Please use this identifier to cite or link to this item: http://hdl.handle.net/10553/17589
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dc.contributor.authorMonzón Argüello, Catalinaen_US
dc.contributor.authorLópez-Jurado, Luis Felipeen_US
dc.contributor.authorRico, Ciroen_US
dc.contributor.authorHays, Graemeen_US
dc.contributor.authorLee, Patriciaen_US
dc.contributor.authorMarco, A.Sen_US
dc.contributor.authorLopez, Pablo Fernandezen_US
dc.date.accessioned2016-06-23T02:30:38Z-
dc.date.accessioned2018-03-15T14:36:41Z-
dc.date.available2016-06-23T02:30:38Z-
dc.date.available2018-03-15T14:36:41Z-
dc.date.issued2010en_US
dc.identifier.issn0305-0270en_US
dc.identifier.otherScopus-
dc.identifier.urihttp://hdl.handle.net/10553/17589-
dc.description.abstractAim  A key life-history component for many animals is the need for movement between different geographical locations at particular times. Green turtle (Chelonia mydas) hatchlings disperse from their natal location to spend an early pelagic stage in the ocean, followed by a neritic stage where small juveniles settle in coastal areas. In this study, we combined genetic and Lagrangian drifter data to investigate the connectivity between natal and foraging locations. In particular we focus on the evidence for transatlantic transport. Location  Atlantic Ocean. Methods  We used mitochondrial DNA (mtDNA) sequences (n = 1567) from foraging groups (n = 8) and nesting populations (n = 12) on both sides of the Atlantic. Genetic data were obtained for Cape Verde juvenile turtles, a foraging group not previously sampled for genetic study. Various statistical methods were used to explore spatial genetics and population genetic structure (e.g. exact tests of differentiation, Geneland and analysis of molecular variance). Many-to-many mixed stock analysis estimated the connectivity between nesting and foraging groups. Results  Our key new finding is robust evidence for connectivity between a nesting population on the South American coast (25% of the Surinam nesting population are estimated to go to Cape Verde) and a foraging group off the coast of West Africa (38% of Cape Verde juveniles are estimated to originate from Surinam), thus extending the results of previous investigations by confirming that there is substantial transatlantic dispersal in both directions. Lagrangian drifter data demonstrated that transport by drift across the Atlantic within a few years is possible. Main conclusions  Small juvenile green turtles seem capable of dispersing extensively, and can drop out of the pelagic phase on a transatlantic scale (the average distance between natal and foraging locations was 3048 km). Nevertheless, we also find support for the ‘closest-to-home’ hypothesis in that the degree of contribution from a nesting population to a foraging group is correlated with proximity. Larger-sized turtles appear to feed closer to their natal breeding grounds (the average distance was 1133 km), indicating that those that have been initially transported to far-flung foraging grounds may still be able to move nearer to home as they grow larger.en_US
dc.formatapplication/pdf-
dc.languageengen_US
dc.relation.ispartofJournal of Biogeographyen_US
dc.sourceJournal of Biogeography [ISSN 0305-0270], v. 37 (9), p. 1752-1766, (Enero 2010)en_US
dc.subject24 Ciencias de la vidaen_US
dc.subject2401 Biología animal (zoología)en_US
dc.subject240116 Herpetologíaen_US
dc.subject.otherAtlantic Oceanen_US
dc.subject.otherBuoy trajectory dataen_US
dc.subject.otherChelonia mydasen_US
dc.subject.otherForaging groundsen_US
dc.subject.otherGeographical connectivityen_US
dc.subject.otherLandscape geneticsen_US
dc.subject.otherMitochondrial DNAen_US
dc.subject.otherMixed stock analysisen_US
dc.titleEvidence from genetic and Lagrangian drifter data for transatlantic transport of small juvenile green turtlesen_US
dc.typeinfo:eu-repo/semantics/Articleen_US
dc.typeArticleen_US
dc.identifier.doi10.1111/j.1365-2699.2010.02326.xen_US
dc.identifier.scopus2-s2.0-77955631518-
dc.identifier.scopus77955631518-
dc.identifier.isi000280980600012-
dc.contributor.authorscopusid22951371200-
dc.contributor.authorscopusid6603237373-
dc.contributor.authorscopusid56269496600-
dc.contributor.authorscopusid7004971115-
dc.contributor.authorscopusid57154989200-
dc.contributor.authorscopusid7006157425-
dc.contributor.authorscopusid7406117748-
dc.identifier.absysnet627210-
dc.identifier.crisid30411-
dc.identifier.eissn1365-2699-
dc.description.lastpage1766en_US
dc.identifier.issue9-
dc.description.firstpage1752en_US
dc.relation.volume37en_US
dc.investigacionCienciasen_US
dc.rights.accessrightsinfo:eu-repo/semantics/openAccess-
dc.type2Artículoen_US
dc.contributor.daisngid2926097-
dc.contributor.daisngid1926126-
dc.contributor.daisngid317420-
dc.contributor.daisngid245191-
dc.contributor.daisngid7145253-
dc.contributor.daisngid77185-
dc.contributor.daisngid1357241-
dc.description.notas30th Annual Symposium on Sea Turtle Biology and Conservation, Goa, India, 2010. Pag 129en_US
dc.utils.revisionen_US
dc.contributor.wosstandardWOS:Monzon-Arguello, C-
dc.contributor.wosstandardWOS:Lopez-Jurado, LF-
dc.contributor.wosstandardWOS:Rico, C-
dc.contributor.wosstandardWOS:Marco, A-
dc.contributor.wosstandardWOS:Lopez, P-
dc.contributor.wosstandardWOS:Hays, GC-
dc.contributor.wosstandardWOS:Lee, PLM-
dc.date.coverdateSeptiembre 2010en_US
dc.identifier.supplement30411-
dc.identifier.ulpgces
dc.description.jcr4,273
dc.description.jcrqQ1
dc.description.scieSCIE
item.grantfulltextopen-
item.fulltextCon texto completo-
crisitem.author.deptGIR IDeTIC: División de Ingeniería Térmica e Instrumentación-
crisitem.author.deptIU para el Desarrollo Tecnológico y la Innovación-
crisitem.author.orcid0000-0001-6380-6130-
crisitem.author.orcid0000-0001-5064-0565-
crisitem.author.parentorgIU para el Desarrollo Tecnológico y la Innovación-
crisitem.author.fullNameMonzon Argüello, Catalina-
crisitem.author.fullNameLópez Jurado, Luis Felipe-
crisitem.author.fullNameSosa Marco,Adriel-
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