Eco-Evolutionary Processes Generating Diversity Among Bottlenose Dolphin, , Populations off Baja California, Mexico

Overview

Journal Evol Biol

Specialty Biology

Date 2018 May 15

PMID 29755152

Citations 2

Authors

Iris Segura-Garcia

Liliana Rojo-Arreola

Axayacatl Rocha-Olivares

Gisela Heckel

Juan Pablo Gallo-Reynoso

Rus Hoelzel

Affiliations

Soon will be listed here.

Abstract

For highly mobile species that nevertheless show fine-scale patterns of population genetic structure, the relevant evolutionary mechanisms determining structure remain poorly understood. The bottlenose dolphin () is one such species, exhibiting complex patterns of genetic structure associated with local habitat dependence in various geographic regions. Here we studied bottlenose dolphin populations in the Gulf of California and Pacific Ocean off Baja California where habitat is highly structured to test associations between ecology, habitat dependence and genetic differentiation. We investigated population structure at a fine geographic scale using both stable isotope analysis (to assess feeding ecology) and molecular genetic markers (to assess population structure). Our results show that there are at least two factors affecting population structure for both genetics and feeding ecology (as indicated by stable isotope profiles). On the one hand there is a signal for the differentiation of individuals by ecotype, one foraging more offshore than the other. At the same time, there is differentiation between the Gulf of California and the west coast of Baja California, meaning that for example, nearshore ecotypes were both genetically and isotopically differentiated either side of the peninsula. We discuss these data in the context of similar studies showing fine-scale population structure for delphinid species in coastal waters, and consider possible evolutionary mechanisms.

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