Phylogenetics and phylogeography of red deer mtDNA lineages during the last 50 000 years in Eurasia

Doan, Karolina; Niedziałkowska, Magdalena; Stefaniak, Krzysztof; Sykut, Maciej; Jędrzejewska, Bogumiła; Ratajczak-Skrzatek, Urszula; Piotrowska, Natalia; Ridush, Bogdan; Zachos, Frank E.; Popović, Danijela; Baca, Mateusz; Mackiewicz, Paweł; Косинцев, П. А.; Makowiecki, Daniel; Charniauski, Maxim; Боескоров, Г. Г.; Bondarev, Alexey Anatolievich; Dănilă, Gabriel; Kusak, Josip; Rannamäe, Eve; Saarma, Urmas; Arakelyan, Marine; Manaseryan, Ninna; Krasnodębski, Dariusz; Titov, Vadim; Hulva, Pavel; Bălășescu, Adrian; Trantalidou, Katerina; Dimitrijević, Vesna; Shpansky, Andrei V.; Kovalchuk, Oleksandr; Klementiev, A. М.; Foronova, Irina V.; Malikov, Dmitriy G; Juras, Anna; Nikolskiy, Pavel A.; Grigoriev, Semyon; Cheprasov, M. Yu.; Новгородов, Г. П.; Sorokin, Alexandr Dmitrievich; Wilczyński, Jarosław; Протопопов, А. В.; Lipecki, Grzegorz; Stanković, Anna

doi:10.1093/zoolinnean/zlab025

Cited by 30 publications

(33 citation statements)

References 21 publications

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“…A similar pattern has been shown for red deer (Cervus elaphus; Doan et al, 2022) and the Valais shrew (Sorex antinorii; Yannic et al, 2012). Here, the contact zone of the two chamois lineages lies around the Rhone valley in Switzerland and corresponds to the contact zone found in some alpine plant species that also underwent a range expansion after the last glaciation (Jay et al, 2012), although this appears to be located further west than that of red deer (Doan et al, 2022). However, in contrast to the red deer range expansion following the last glaciation, which was dominated by the northeastward expansion of populations from south-western refugia (Doan et al, 2022), the recolonization by chamois was likely dominated by the eastern lineage, which expanded west over large parts of the Alps.…”

Section: Discussionsupporting

confidence: 82%

“…These two lineages probably represent two sources of recolonization of the Alps after the last glaciation, originating from populations isolated from each other during that time. A similar pattern has been shown for red deer (Cervus elaphus; Doan et al, 2022) and the Valais shrew (Sorex antinorii; Yannic et al, 2012). Here, the contact zone of the two chamois lineages lies around the Rhone valley in Switzerland and corresponds to the contact zone found in some alpine plant species that also underwent a range expansion after the last glaciation (Jay et al, 2012), although this appears to be located further west than that of red deer (Doan et al, 2022).…”

Section: Discussionsupporting

confidence: 77%

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Dispersal and habitat dynamics shape the genetic structure of the Northern chamois in the Alps

Leugger

Broquet

Karger

et al. 2022

Journal of Biogeography

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Aim Understanding the drivers of species distribution ranges and population genetic structure can help predict species' responses to global change, while mitigating threats to biodiversity through effective conservation measures. Here, we combined species habitat suitability through time with process‐based models and genomic data to investigate the role of landscape features and functional connectivity in shaping the population genetic structure of Northern chamois. Location European Alps. Taxon Northern chamois (Rupicapra rupicapra). Methods Using a model that simulates dispersal and tracks the functional connectivity of populations over dynamic landscapes, we modelled the response of the chamois to climate change from the last glaciation (20,000 years ago) to the present. We reconstructed species habitat suitability and landscape connectivity over time and simulated cumulative divergence of populations as a proxy for genetic differentiation. We then compared simulated divergence with the actual population structure of 449 chamois (with >20 k SNPs) sampled across the Alps. Results We found that Alpine populations of chamois are structured into two main clades, located in the south‐western and the eastern Alps. The contact zone between the two lineages is located near the Rhone valley in Switzerland. Simulations reproduced the geographic differentiation of populations observed in the genomic data, and limited dispersal ability and landscape connectivity co‐determined the fit of the simulations to data. Main conclusions The contemporary genetic structure of the chamois across the Alps is explained by limited functional connectivity in combination with large rivers or valleys acting as dispersal barriers. The results of our analysis combining simulations with population genomics highlight how biological characteristics, habitat preference and landscapes shape population genetic structure over time and in responses to climate change. We conclude that spatial simulations could be used to improve our understanding of how landscape dynamics, shaped by geological or climatic forces, impact intra‐ and interspecific diversity.

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Section: Discussionsupporting

confidence: 82%

Section: Discussionsupporting

confidence: 77%

Dispersal and habitat dynamics shape the genetic structure of the Northern chamois in the Alps

Leugger

Broquet

Karger

et al. 2022

Journal of Biogeography

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“…Deer haplogroups introduced to selected regions are marked with an asterisk*. The distribution ranges were compiled from several sources 2 , 104 – 119 . Figure was created in CorelDRAW Graphics Suite 11 ( https://www.coreldraw.com/en/ ) based on OpenStreetMap (URL https://www.openstreetmap.org/copyright ; ODbL licence 1.0 https://opendatacommons.org/licenses/odbl/1-0/ by OSMF).…”

Section: Introductionmentioning

confidence: 99%

Phylogeny and evolution of the genus Cervus (Cervidae, Mammalia) as revealed by complete mitochondrial genomes

Mackiewicz

Matosiuk

Świsłocka

et al. 2022

Sci Rep

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Mitochondrial DNA (mtDNA) lineages are recognized as important components of intra- and interspecific biodiversity, and allow to reveal colonization routes and phylogeographic structure of many taxa. Among these is the genus Cervus that is widely distributed across the Holarctic. We obtained sequences of complete mitochondrial genomes from 13 Cervus taxa and included them in global phylogenetic analyses of 71 Cervinae mitogenomes. The well-resolved phylogenetic trees confirmed Cervus to be monophyletic. Molecular dating based on several fossil calibration points revealed that ca. 2.6 Mya two main mitochondrial lineages of Cervus separated in Central Asia, the Western (including C. hanglu and C. elaphus) and the Eastern (comprising C. albirostris, C. canadensis and C. nippon). We also observed convergent changes in the composition of some mitochondrial genes in C. hanglu of the Western lineage and representatives of the Eastern lineage. Several subspecies of C. nippon and C. hanglu have accumulated a large portion of deleterious substitutions in their mitochondrial protein-coding genes, probably due to drift in the wake of decreasing population size. In contrast to previous studies, we found that the relic haplogroup B of C. elaphus was sister to all other red deer lineages and that the Middle-Eastern haplogroup E shared a common ancestor with the Balkan haplogroup C. Comparison of the mtDNA phylogenetic tree with a published nuclear genome tree may imply ancient introgressions of mtDNA between different Cervus species as well as from the common ancestor of South Asian deer, Rusa timorensis and R. unicolor, to the Cervus clade.

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“…A genetic signal congruent with these mtDNA results has recently also been identified in the nuclear genome, haplogroup A being most widely distributed from Iberia throughout continental Europe, the British Isles, and Scandinavia. In central/eastern Europe it co-occurs with haplogroup C of southeastern Europe, occurring in the Balkans and the Carpathians respectively [2].…”

Section: Introductionmentioning

confidence: 99%

“…Although red deer has often been translocated by humans, it seems that its present-day phylogeographic pattern in Europe reflects predominantly natural processes, in response to environmental changes and natural replacement between mtDNA lineages [2]. A major body of data on extant antlers has been used here to contextualize the morphometric characteristics of the stray find from Sweden.…”

Section: Introductionmentioning

confidence: 99%

Human Impact on Antler Conformation in Western Red Deer (Cervus elaphus elaphus Linnaeus, 1758)

Bartosiewicz

2021

Heritage

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A stray find of red deer antler from Sweden with the braincase was collected due to an apparently pathological deformation, the strongly retarded right antler. Measurements of the complete left antler inspired the analysis of general antler conformation in order to place this archaeological specimen in a zoological context. This stray find and another prehistoric antler from Sweden as well as three complete prehistoric antlers from Hungary were metrically compared using measurements of over 17,000 trophies of extant red deer from Hungary. The results confirmed that the stray specimen from Sweden and prehistoric antlers from Hungary were similar in that they were stouter (smaller length measurements but greater circumferences) than their 20th century counterparts. Most of their measurements fell within the ±1 standard deviation interval of the means of extant trophies. The pathological lesion on the studied stray specimen directed attention to the role of human selection. Twentieth century record trophies show a significant increase in antler weight and “quality” as defined in the international trophy grading system. While these morphometric observations cannot be taken as a proxy for absolute dating or precise contextual identification for the stray find central to this study, its size and apparent lack of consistent human selection (pathological deformation, “archaic” antler proportions) point to possibly early origins, prior to major human influence.

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Phylogenetics and phylogeography of red deer mtDNA lineages during the last 50 000 years in Eurasia

Cited by 30 publications

References 21 publications

Dispersal and habitat dynamics shape the genetic structure of the Northern chamois in the Alps

Dispersal and habitat dynamics shape the genetic structure of the Northern chamois in the Alps

Phylogeny and evolution of the genus Cervus (Cervidae, Mammalia) as revealed by complete mitochondrial genomes

Human Impact on Antler Conformation in Western Red Deer (Cervus elaphus elaphus Linnaeus, 1758)

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