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Ancient DNA sequences point to a large loss of mitochondrial genetic diversity in the saiga antelope (Saiga tatarica) since the Pleistocene.

https://arctichealth.org/en/permalink/ahliterature100381
Source
Mol Ecol. 2010 Nov;19(22):4863-75
Publication Type
Article
Date
Nov-2010
Author
Paula F Campos
Tommy Kristensen
Ludovic Orlando
Andrei Sher
Marina V Kholodova
Anders Götherström
Michael Hofreiter
Dorothée G Drucker
Pavel Kosintsev
Alexei Tikhonov
Gennady F Baryshnikov
Eske Willerslev
M Thomas P Gilbert
Author Affiliation
Centre for GeoGenetics, Natural History Museum of Denmark, University of Copenhagen, Øster Voldgade 5-7, 1350 Copenhagen, Denmark.
Source
Mol Ecol. 2010 Nov;19(22):4863-75
Date
Nov-2010
Language
English
Publication Type
Article
Abstract
Prior to the Holocene, the range of the saiga antelope (Saiga tatarica) spanned from France to the Northwest Territories of Canada. Although its distribution subsequently contracted to the steppes of Central Asia, historical records indicate that it remained extremely abundant until the end of the Soviet Union, after which its populations were reduced by over 95%. We have analysed the mitochondrial control region sequence variation of 27 ancient and 38 modern specimens, to assay how the species' genetic diversity has changed since the Pleistocene. Phylogenetic analyses reveal the existence of two well-supported, and clearly distinct, clades of saiga. The first, spanning a time range from >49,500 (14) C ybp to the present, comprises all the modern specimens and ancient samples from the Northern Urals, Middle Urals and Northeast Yakutia. The second clade is exclusive to the Northern Urals and includes samples dating from between 40,400 to 10,250 (14) C ybp. Current genetic diversity is much lower than that present during the Pleistocene, an observation that data modelling using serial coalescent indicates cannot be explained by genetic drift in a population of constant size. Approximate Bayesian Computation analyses show the observed data is more compatible with a drastic population size reduction (c. 66-77%) following either a demographic bottleneck in the course of the Holocene or late Pleistocene, or a geographic fragmentation (followed by local extinction of one subpopulation) at the Holocene/Pleistocene transition.
PubMed ID
20874761 View in PubMed
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Colonizing the High Arctic: Mitochondrial DNA Reveals Common Origin of Eurasian Archipelagic Reindeer (Rangifer tarandus).

https://arctichealth.org/en/permalink/ahliterature277845
Source
PLoS One. 2016;11(11):e0165237
Publication Type
Article
Date
2016
Author
Kjersti S Kvie
Jan Heggenes
David G Anderson
Marina V Kholodova
Taras Sipko
Ivan Mizin
Knut H Røed
Source
PLoS One. 2016;11(11):e0165237
Date
2016
Language
English
Publication Type
Article
Abstract
In light of current debates on global climate change it has become important to know more on how large, roaming species have responded to environmental change in the past. Using the highly variable mitochondrial control region, we revisit theories of Rangifer colonization and propose that the High Arctic archipelagos of Svalbard, Franz Josef Land, and Novaia Zemlia were colonized by reindeer from the Eurasian mainland after the last glacial maximum. Comparing mtDNA control region sequences from the three Arctic archipelagos showed a strong genetic connection between the populations, supporting a common origin in the past. A genetic connection between the three archipelagos and two Russian mainland populations was also found, suggesting colonization of the Eurasian high Arctic archipelagos from the Eurasian mainland. The age of the Franz Josef Land material (>2000 years before present) implies that Arctic indigenous reindeer colonized the Eurasian Arctic archipelagos through natural dispersal, before humans approached this region.
PubMed ID
27880778 View in PubMed
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