TY - JOUR
T1 - Biogeography in the deep
T2 - hierarchical population genomic structure of two beaked whale species
AU - Onoufriou, Aubrie B.
AU - Gaggiotti, Oscar E.
AU - de Soto, Natacha Aguilar
AU - McCarthy, Morgan L.
AU - Morin, Phillip A.
AU - Rosso, Massimiliano
AU - Dalebout, Merel
AU - Davison, Nicholas
AU - Baird, Robin W.
AU - Baker, C. Scott
AU - Berrow, Simon
AU - Brownlow, Andrew
AU - Burns, Daniel
AU - Caurant, Florence
AU - Claridge, Diane
AU - Constantine, Rochelle
AU - Demaret, Fabien
AU - Dreyer, Sascha
AU - Ðuras, Martina
AU - Durban, John
AU - Frantzis, Alexandros
AU - Freitas, Luis
AU - Genty, Gabrielle
AU - Galov, Ana
AU - Hansen, Sabine S.
AU - Kitchener, Andrew C.
AU - Martin, Vidal
AU - Mignucci-Giannoni, Antonio A.
AU - Montano, Valeria
AU - Moulins, Aurelie
AU - Olavarría, Carlos
AU - Michael Poole, M.
AU - Suárez, Cristel Reyes
AU - Rogan, Emer
AU - Ryan, Conor
AU - Schiavi, Agustina
AU - Tepsich, Paola
AU - Urban, Jorge
AU - West, Kristi
AU - Olsen, Morten Tange
AU - Carroll, Emma L.
N1 - Funding: Funding for this research was provided by the Office of Naval Research, Award numbers N000141613017 and N000142112712. ABO was supported by a partial studentship from the University of St Andrews, School of Biology; OEG by the Marine Alliance for Science and Technology for Scotland (Scottish Funding Council grant HR09011); ELC by a Rutherford Discovery Fellowship from the Royal Society of New Zealand Te Aparangi; NAS by a Ramon y Cajal Fellowship from the Spanish Ministry of Innovation; MLM by the European Union’s Horizon 2020 Research and Innovation Programme (Marie Skłodowska-Curie grant 801199); CR by the Marine Institute (Cetaceans on the Frontier) and the Irish Research Council; and MTO by the Hartmann Foundation.
PY - 2022/12/1
Y1 - 2022/12/1
N2 - The deep sea is the largest ecosystem on Earth, yet little is known
about the processes driving patterns of genetic diversity in its
inhabitants. Here, we investigated the macro- and microevolutionary
processes shaping genomic population structure and diversity in two
poorly understood, globally distributed, deep-sea predators: Cuvier’s
beaked whale (Ziphius cavirostris) and Blainville’s beaked whale (Mesoplodon densirostris).
We used double-digest restriction associated DNA (ddRAD) and whole
mitochondrial genome (mitogenome) sequencing to characterise genetic
patterns using phylogenetic trees, cluster analysis,
isolation-by-distance, genetic diversity and differentiation statistics.
Single nucleotide polymorphisms (SNPs; Blainville’s n = 43 samples, SNPs=13988; Cuvier’s n = 123, SNPs= 30479) and mitogenomes (Blainville’s n = 27; Cuvier’s n = 35)
revealed substantial hierarchical structure at a global scale. Both
species display significant genetic structure between the Atlantic,
Indo-Pacific and in Cuvier’s, the Mediterranean Sea. Within major ocean
basins, clear differentiation is found between genetic clusters on the
east and west sides of the North Atlantic, and some distinct patterns of
structure in the Indo-Pacific and Southern Hemisphere. We infer that
macroevolutionary processes shaping patterns of genetic diversity
include biogeographical barriers, highlighting the importance of such
barriers even to highly mobile, deep-diving taxa. The barriers likely
differ between the species due to their thermal tolerances and
evolutionary histories. On a microevolutionary scale, it seems likely
that the balance between resident populations displaying site fidelity,
and transient individuals facilitating gene flow, shapes patterns of
connectivity and genetic drift in beaked whales. Based on these results,
we propose management units to facilitate improved conservation
measures for these elusive species.
AB - The deep sea is the largest ecosystem on Earth, yet little is known
about the processes driving patterns of genetic diversity in its
inhabitants. Here, we investigated the macro- and microevolutionary
processes shaping genomic population structure and diversity in two
poorly understood, globally distributed, deep-sea predators: Cuvier’s
beaked whale (Ziphius cavirostris) and Blainville’s beaked whale (Mesoplodon densirostris).
We used double-digest restriction associated DNA (ddRAD) and whole
mitochondrial genome (mitogenome) sequencing to characterise genetic
patterns using phylogenetic trees, cluster analysis,
isolation-by-distance, genetic diversity and differentiation statistics.
Single nucleotide polymorphisms (SNPs; Blainville’s n = 43 samples, SNPs=13988; Cuvier’s n = 123, SNPs= 30479) and mitogenomes (Blainville’s n = 27; Cuvier’s n = 35)
revealed substantial hierarchical structure at a global scale. Both
species display significant genetic structure between the Atlantic,
Indo-Pacific and in Cuvier’s, the Mediterranean Sea. Within major ocean
basins, clear differentiation is found between genetic clusters on the
east and west sides of the North Atlantic, and some distinct patterns of
structure in the Indo-Pacific and Southern Hemisphere. We infer that
macroevolutionary processes shaping patterns of genetic diversity
include biogeographical barriers, highlighting the importance of such
barriers even to highly mobile, deep-diving taxa. The barriers likely
differ between the species due to their thermal tolerances and
evolutionary histories. On a microevolutionary scale, it seems likely
that the balance between resident populations displaying site fidelity,
and transient individuals facilitating gene flow, shapes patterns of
connectivity and genetic drift in beaked whales. Based on these results,
we propose management units to facilitate improved conservation
measures for these elusive species.
KW - DdRAD sequencing
KW - Mitogenome sequencing
KW - Phylogenomics
KW - Ziphius cavirostris
KW - Mesoplodon densirostris
KW - Ziphiidae
U2 - 10.1016/j.gecco.2022.e02308
DO - 10.1016/j.gecco.2022.e02308
M3 - Article
SN - 2351-9894
VL - 40
JO - Global Ecology and Conservation
JF - Global Ecology and Conservation
M1 - e02308
ER -