The links between global climatic cycles and the diversification and migration of Arctic shorebirds = La relación entre los ciclos climáticos y la diversificación y migración de las aves limícolas árticas

In this thesis we studied how the changes in the climate determine the distribution, diversity and conservation of a very representative group of the Arctic avifauna, the shorebirds. In the first chapter we explored the changes in the ranges of the Arctic shorebirds during the Pleistocene glacial cy...

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Detalhes bibliográficos
Autor: Arcones Segovia, Ángel
Formato: tesis doctoral
Estado:Versión publicada
Fecha de publicación:2019
País:España
Recursos:CBUC, CESCA
Repositorio:TDR. Tesis Doctorales en Red
OAI Identifier:oai:www.tdx.cat:10803/668247
Acesso em linha:http://hdl.handle.net/10803/668247
Access Level:acceso abierto
Palavra-chave:Climatologia
Climatología
Climatology
Migració d'ocells
Migración de aves
Birds migration
Àrtic, Oceà
Artico, Océano
Arctic Ocean
Ciències Experimentals i Matemàtiques
574
Descrição
Resumo:In this thesis we studied how the changes in the climate determine the distribution, diversity and conservation of a very representative group of the Arctic avifauna, the shorebirds. In the first chapter we explored the changes in the ranges of the Arctic shorebirds during the Pleistocene glacial cycles, and how that shaped the current diversity of subspecies. We combined species distribution models, fossil evidence and estimation on the distribution of the tundra to compare the distribution of the breeding and wintering ranges between the present (representing an interglacial period) and the last glacial maximum (LGM) ca. 21,000 years ago. We found that the species with described subspecies predominantly experienced fragmentation of their breeding ranges during glacial cycles, especially during the glacial periods. On the other hand, most of the monotypic species maintained continuous breeding ranges during glacial and interglacial periods. This supports that the Pleistocene glacial cycles provided a mechanism for allopatric speciation that originated the current pattern of intraspecific diversity in these species. Additionally, we recovered that, despite changes in the breeding ranges, there was an overall lack of overlap with the wintering ranges and the long-distance migration between them remain uninterrupted during glacial periods. This migration likely contributed to originate and maintain the diversity between populations over multiple glacial cycles. While the first chapter provided a spatial mechanism of diversification during the glacial cycles, this needs to be confirmed by genetic data to support that the timing of this diversification falls within the Pleistocene. To better estimate divergence time within species, we performed the most comprehensive calibration of the mitochondrial molecular clock in birds to date. We included full mitochondrial genomes from 621 bird species and 25 reliable fossil calibrations and estimated the substitution rates for each of the mitochondrial genes in every lineage of the phylogenetic tree. We applied the obtained rates to molecular clock and coalescent hypothesis testing techniques in multiple Arctic shorebird species. We found that overall the diversity within the species originated during the Pleistocene, and especially during the last 900,000 years, coinciding with a period of longer and more intense glacial periods. Species with similar patterns of past and present distribution showed parallelism in their patterns of genetic diversification. Since the climate has played such a key role in the origin of the current diversity of these species, in the third chapter we explored the potential effects of the current climate change in their future distribution and conservation. We performed species distribution models to forecast their breeding ranges over three different climate change scenarios over the current century. The results show that the species' ranges will displace northwards due to the warming climate, and many species will experience severe range reduction as they are already at the northernmost part of the continents. This is especially critical in the Palearctic, while in the Nearctic the Arctic Archipelago could provide shelter for the species to expand their breeding ranges. We also estimated the potential changes in the extent of the Arctic and its ecosystems since the last interglacial and until the end of the century. Our results indicate that although the species have previously experienced extreme changes in the Arctic conditions, the current rate of change greatly exceeds those from recent events. This could lead to even more drastic range reductions and population declines than predicted and threaten all the diversity that originated during the Pleistocene. As a whole, this thesis provides an integrative perspective on the effects of the climate origin and conservation of the diversity within Arctic species. This work sheds light on the detailed spatial and temporal mechanisms that promoted the current diversity across a large group of Arctic birds, and the implications that the current climate change will have in the persistence of the Arctic biodiversity.