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Population genomics reveals the underlying structure of the small pelagic European sardine and suggests low connectivity within Macaronesia    
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  • Rute da Fonseca,
  • Paula Campos,
  • Alba Rey de la Iglesia,
  • Gustavo Barroso,
  • Lucie Bergeron,
  • Manuel Nande,
  • Fernando Tuya,
  • Sami Abidli,
  • Montse Pérez,
  • Isabel Riveiro,
  • Pablo Carrera,
  • Alba Jurado-Ruzafa,
  • M Teresa G Santamaria,
  • Rui Faria,
  • Andre Machado,
  • Miguel Fonseca,
  • Elsa Froufe,
  • L Filipe C Castro
Rute da Fonseca
University of Copenhagen Faculty of Health and Medical Sciences

Corresponding Author:rfonseca@sund.ku.dk

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Paula Campos
University of Porto
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Alba Rey de la Iglesia
University of Copenhagen Faculty of Health and Medical Sciences
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Gustavo Barroso
University of California Los Angeles
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Lucie Bergeron
University of Copenhagen Department of Biology
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Manuel Nande
University of Porto
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Fernando Tuya
Universidad de Las Palmas de Gran Canaria
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Sami Abidli
Université de Tunis El Manar
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Montse Pérez
Instituto Español de Oceanografía Centro Oceanográfico de Vigo
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Isabel Riveiro
Instituto Español de Oceanografía Centro Oceanográfico de Vigo
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Pablo Carrera
Instituto Español de Oceanografía Centro Oceanográfico de Vigo
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Alba Jurado-Ruzafa
Instituto Español de Oceanografía Centro Oceanográfico de Canarias
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M Teresa G Santamaria
Instituto Español de Oceanografía Centro Oceanográfico de Canarias
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Rui Faria
University of Sheffield
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Andre Machado
University of Porto
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Miguel Fonseca
University of Porto
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Elsa Froufe
University of Porto
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L Filipe C Castro
University of Porto
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Abstract

The European sardine (Sardina pilchardus, Walbaum 1792) is indisputably a commercially important species. Previous studies using uneven sampling or a limited number of makers have presented sometimes conflicting evidence for the genetic structure of S. pilchardus populations.  Here we show that whole genome data from 108 individuals from 16 sampling areas across 5,000 Km of the species’ distribution range (from the Eastern Mediterranean to the archipelago of Azores) supports at least three genetic clusters. One includes individuals from Azores and Madeira, with evidence of substructure separating these two archipelagos in the Atlantic. Another cluster broadly corresponds to the center of the distribution including the sampling sites around Iberia, separated by the Almeria-Oran front from the third cluster that includes all of the Mediterranean samples, except those from the Alboran Sea. Individuals from the Canary Islands appear as belonging to the same ancestral group as those from the Mediterranean. This suggests at least two important geographical barriers to gene flow, even though these do not seem complete, with many individuals from around Iberia and the Mediterranean showing some patterns compatible with admixture with other genetic clusters. Genomic regions corresponding to the top outliers of genetic differentiation are located in areas of low recombination indicative that genetic architecture also has a role in shaping population structure. These regions include genes related to otolith formation, a calcium carbonate structure in the inner ear previously used to distinguish S. pilchardus populations.  Our results provide a baseline for further characterization of physical and genetic barriers that divide European sardine populations, and information for transnational stock management of this highly exploited species towards sustainable fisheries.