Complex patterns of population genetic structure of moose, Alces alces, after recent spatial expansion in Poland revealed by sex-linked markers

Świsłocka, Magdalena; Czajkowska, Magdalena; Duda, Norbert; Danyłow, Jan; Owadowska-Cornil, Edyta; Ratkiewicz, Mirosław

doi:10.1007/s13364-013-0148-7

Cited by 21 publications

(16 citation statements)

References 46 publications

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“…5 First-generation migrants amongst six moose groups indicated by analyses of microsatellite DNA (see Niedziałkowska et al 2016), as calculated in GENECLASS result of the different evolutionary demographic history of this moose group compared to individuals from other surrounding study sites and the location of this deme on the western edge of moose range in Europe, was reported earlier by Świsłocka et al (2008, 2013, 2015) and Niedziałkowska et al (2014Niedziałkowska et al ( , 2016. Although there are no significant topographic barriers for moose in this region, and there is a high level of admixture in this deme (Świsłocka et al 2008, 2013Niedziałkowska et al 2016, this study), the emigration rate is much higher than the immigration rate to this local population (Świsłocka et al 2015). This could be explained by higher densities of moose in the Biebrza River Valley than in the surrounding areas (Wawrzyniak et al 2010).…”

Section: Discussionmentioning

confidence: 55%

Diverse rates of gene flow and long-distance migration in two moose Alces alces subpopulations in Europe

Niedziałkowska

Jędrzejewska

Danyłow³

et al. 2016

Mamm Res

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We assessed migration rates and gene flow amongst 16 local demes and six larger groups of moose identified by a previous microsatellite study across the entire European range of the species. The most important barrier to gene flow, the Baltic Sea along with the mountainous region in northern Fennoscandia, separates two genetically distinct moose subpopulations-the Scandinavian and the continental subpopulations-that originate from different glacial refugia. Our results showed that moose effectively migrated over long distances, but statistically significant gene flow was shorter in the Scandinavian (300-400 km) compared to the continental subpopulation (400-500 km). The admixture rates in local demes were markedly lower in the Scandinavian, than in the continental part of the moose range. Weaker gene flow amongst local demes in Scandinavia resulted from the major barrier of the Scandinavian Mountains. In the generally panmixed continental subpopulation of moose, two demes-one in NE Poland and another in the Kirov Oblast, Russia showed slightly hampered gene exchange with neighbouring demes, whereas one deme, in Arkhangelsk region, NE part of European Russia, appeared to have very high gene flow into other demes. Different evolutionary and demographic histories, population densities and land topography (large rivers) could have contributed to the low level barriers to gene flow in the continental subpopulation of moose.

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Section: Discussionmentioning

confidence: 55%

Diverse rates of gene flow and long-distance migration in two moose Alces alces subpopulations in Europe

Niedziałkowska

Jędrzejewska

Danyłow³

et al. 2016

Mamm Res

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“…tcs 1.21 (Clement et al ., ) was used to draw a haplotype network, combining our data with all published sequence information (at the same mtDNA region) on Palaearctic moose (Hundertmark et al ., ; Hassanin et al ., ; Świsłocka et al ., ; Kholodova et al ., ; Niedziałkowska et al ., ). We used dnasp 5.0 (Librado & Rozas, ) to calculate p ‐distances between the two mtDNA clades detected in our data (see ) and estimated the time of divergence by applying divergence rates of 62.8% (domestic cattle, Bos taurus ; Bradley et al ., ) and 78.5% per million years (bison, Bison bonasus ; Burzyńska et al ., ).…”

Section: Methodsmentioning

confidence: 99%

“…Despite consisting of large populations with more or less continuous distributions, contemporary European moose populations are genetically structured. This differentiation has been variously explained with ancient and/or more recent events (Charlier et al ., ; Haanes et al ., ; Świsłocka et al ., ). Moreover, significant spatial genetic structure has been detected within the Finnish moose population (Kangas et al ., ; Niedziałkowska et al ., ), although the exact location(s) of subpopulation boundaries and the levels of admixture remain unclear.…”

Section: Introductionmentioning

confidence: 99%

Evidence of post‐glacial secondary contact and subsequent anthropogenic influence on the genetic composition of Fennoscandian moose (Alces alces)

Kangas

Kvist

Холодова

et al. 2015

Journal of Biogeography

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Aim To determine whether a contemporary population of the moose (Alces alces), a large northern ungulate, retains genetic signatures of post-glacial recolonization and/or the effects of anthropogenic factors. We focused on investigating spatial genetic structure and the distribution of genetic diversity of this species to clarify its still obscure history.Location Eastern Fennoscandia, Northern Europe.Methods In total, 574 Finnish and Russian Karelian moose were genotyped at 16 microsatellite loci, and the mitochondrial control region was sequenced from 224 individuals. Spatially explicit Bayesian clustering, multivariate and spatial autocorrelation methods were applied alongside traditional F-statistics to study the effects of landscape on genetic structure. The demographic history of our study populations was explored with coalescent analysis and Bayesian skyline plots.Results A major mitochondrial divergence of moose was discovered between northern parts of Finland and the rest of the studied area. Landscape genetic analyses on the microsatellite data identified three genetic clusters connected by clines, with coalescent analysis indicating the division to be of ancient origin. Additionally, recent population bottlenecks were detected using Bayesian skyline plots. Main conclusionsOur results indicate a post-glacial secondary contact between two distinct moose mitochondrial lineages that diverged during the Pleistocene, whereas admixture of three diverged genetic subpopulations was detected using microsatellites. The emergence of these subpopulations was estimated to have occurred after the post-glacial recolonization of Fennoscandia. The observed genetic bottlenecks coincide with recorded historical population declines in the 18th century. We conclude that the contemporary genetic composition of the moose population in eastern Fennoscandia has been affected by both ancient and recent factors.

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“…Kang et al, 2013;Swislocka et al, 2013). In some systems, it is clear that such structuring has arisen quickly and relatively recently (Gislason et al, 1999;Garduño-Paz et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

Divergent functional traits in three sympatric Arctic charr Salvelinus alpinus morphs are not coupled with the age of the lineage divergence

et al. 2016

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Three genetically discrete morphs of Arctic charr in Loch Rannoch, Scotland originated from a recent divergence within the lake (in situ) (piscivore and benthivore morphs) and from secondary contact of two older lineages (ex situ; a planktivore-piscivore/ benthivore divergence). To test if the expression of traits with strong functional roles was linked to the age of the divergence, fin and gill anatomy, and dentition were quantified and compared across morphs. Five additional working hypotheses suggesting a rank order of trait expression amongst morphs were also tested. The planktivorous morph had more rays in the dorsal and pectoral fins, longer gill rakers (but not more) as well as a smaller gill cavity than the other two morphs.The piscivorous morph had more palatine teeth and longer teeth on the mandible, pre-maxillary and glossohyal bones, and a larger buccal cavity. These differences indicate a differential response to selection in these functional anatomical features most likely related to morph foraging specialisms. Notably, between-morph divergences in the expression of these traits were not simply linked to the length of divergence between morphs and have arisen equally quickly in the recent (in situ) divergence as they have in older, ex situ divergences.

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Complex patterns of population genetic structure of moose, Alces alces, after recent spatial expansion in Poland revealed by sex-linked markers

Cited by 21 publications

References 46 publications

Diverse rates of gene flow and long-distance migration in two moose Alces alces subpopulations in Europe

Diverse rates of gene flow and long-distance migration in two moose Alces alces subpopulations in Europe

Evidence of post‐glacial secondary contact and subsequent anthropogenic influence on the genetic composition of Fennoscandian moose (Alces alces)

Divergent functional traits in three sympatric Arctic charr Salvelinus alpinus morphs are not coupled with the age of the lineage divergence

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