Your search keyword '"Urmas Saarma"' showing total 5 results

1. Genetic structure in large, continuous mammal populations: the example of brown bears in northwestern Eurasia

Author

John Davison, Egle Tammeleht, Alexander P. Saveljev, Mark A. Korsten, Urmas Saarma, Jaanus Remm, Igor L. Tumanov, Ilpo Kojola, and Peep Männil

Subjects

education.field_of_study, Genetic diversity, Ecology, Demographic history, Population size, Population, Biology, Gene flow, Genetic structure, Genetics, Biological dispersal, Mammal, education, Ecology, Evolution, Behavior and Systematics

Abstract

Knowledge of population structure and genetic diversity and the spatio-temporal demographic processes affecting populations is crucial for effective wildlife preservation, yet these factors are still poorly understood for organisms with large continuous ranges. Available population genetic data reveal that widespread mammals have for the most part only been carefully studied at the local population scale, which is insufficient for understanding population processes at larger scales. Here, we provide data on population structure, genetic diversity and gene flow in a brown bear population inhabiting the large territory of northwestern Eurasia. Analysis of 17 microsatellite loci indicated significant population substructure, consisting of four genetic groups. While three genetic clusters were confined to small geographical areas-located in Estonia, southern Finland and Leningrad oblast, Russia-the fourth cluster spanned a very large area broadly falling between northern Finland and the Arkhangelsk and Kirov oblasts of Russia. Thus, the data indicate a complex pattern where a fraction of the population exhibits large-scale gene flow that is unparalleled by other wild mammals studied to date, while the remainder of the population appears to have been structured by a combination of demographic history and landscape barriers. These results based on nuclear data are generally in good agreement with evidence previously derived using mitochondrial markers, and taken together, these markers provide complementary information about female-specific and population-level processes. Moreover, this study conveys information about spatial processes occurring over multiple generations that cannot be readily gained using other approaches, e.g. telemetry.

Published

2010

2. Sudden expansion of a single brown bear maternal lineage across northern continental Eurasia after the last ice age: a general demographic model for mammals?

Author

Elena A. Lyapunova, John Davison, Simon Y. W. Ho, Igor L. Tumanov, Janis Ozolins, Urmas Saarma, Maris Roht, Alexander M. Rõkov, Egle Vulla, Peep Männil, Alexander P. Saveljev, Valentin S. Pazetnov, Malgorzata Pilot, Zanete Andersone-Lilley, Harri Valdmann, Ilpo Kojola, Alexios Giannakopoulos, Sergei V. Pazetnov, Marju Korsten, Yorgos Mertzanis, Nikolai I. Markov, Alex A. Vorobiev, Alexei V. Abramov, and Berit Pähn

Subjects

education.field_of_study, Ecology, Population, Last Glacial Maximum, Biology, biology.organism_classification, humanities, Haplogroup, Coalescent theory, Phylogeography, Holarctic, Evolutionary biology, Genetics, Cave bear, education, Molecular clock, geographic locations, Ecology, Evolution, Behavior and Systematics

Abstract

The brown bear has proved a useful model for studying Late Quaternary mammalian phylogeography. However, information is lacking from northern continental Eurasia, which constitutes a large part of the species' current distribution. We analysed mitochondrial DNA sequences (totalling 1943 bp) from 205 bears from northeast Europe and Russia in order to characterize the maternal phylogeography of bears in this region. We also estimated the formation times of the sampled brown bear lineages and those of its extinct relative, the cave bear. Four closely related haplogroups belonging to a single mitochondrial subclade were identified in northern continental Eurasia. Several haplotypes were found throughout the whole study area, while one haplogroup was restricted to Kamchatka. The haplotype network, estimated divergence times and various statistical tests indicated that bears in northern continental Eurasia recently underwent a sudden expansion, preceded by a severe bottleneck. This brown bear population was therefore most likely founded by a small number of bears that were restricted to a single refuge area during the last glacial maximum. This pattern has been described previously for other mammal species and as such may represent one general model for the phylogeography of Eurasian mammals. Bayesian divergence time estimates are presented for different brown and cave bear clades. Moreover, our results demonstrate the extent of substitution rate variation occurring throughout the phylogenetic tree, highlighting the need for appropriate calibration when estimating divergence times.

Published

2009

3. Mitogenetic structure of brown bears (Ursus arctos L.) in northeastern Europe and a new time frame for the formation of European brown bear lineages

Author

Valentin S. Pazetnov, Urmas Saarma, Harri Valdmann, Marju Kaljuste, Alexander P. Saveljev, Simon Y. W. Ho, Alexei V. Abramov, Alex A. Vorobiev, Stanislav V. Putchkovskiy, Alexander M. Rõkov, Peep Männil, Ilpo Kojola, Sergei V. Pazetnov, Oliver G. Pybus, Marju Korsten, Nikolai I. Markov, Egle Vulla, Igor L. Tumanov, and Elena A. Lyapunova

Subjects

education.field_of_study, Phylogenetic tree, biology, Pleistocene, Lineage (evolution), Population, Zoology, biology.organism_classification, Haplogroup, Phylogeography, Genetics, Ursus, education, Molecular clock, Ecology, Evolution, Behavior and Systematics

Abstract

We estimated the phylogenetic relationships of brown bear maternal haplotypes from countries of northeastern Europe (Estonia, Finland and European Russia), using sequences of mitochondrial DNA (mtDNA) control region of 231 bears. Twenty-five mtDNA haplotypes were identified. The brown bear population in northeastern Europe can be divided into three haplogroups: one with bears from all three countries, one with bears from Finland and Russia, and the third composed almost exclusively of bears from European Russia. Four haplotypes from Finland and European Russia matched exactly with haplotypes from Slovakia, suggesting the significance of the current territory of Slovakia in ancient demographic processes of brown bears. Based on the results of this study and those from the recent literature, we hypothesize that the West Carpathian Mountains have served either as one of the northernmost refuge areas or as an important movement corridor for brown bears of the Eastern lineage towards northern Europe during or after the last ice age. Bayesian analyses were performed to investigate the temporal framework of brown bear lineages in Europe. The molecular clock was calibrated using Beringian brown bear sequences derived from radiocarbon-dated ancient samples, and the estimated mutation rate was 29.8% (13.3%− − − 47.6%) per million years. The whole European population and Western and Eastern lineages formed about 175 000, 70 000 and 25 000 years before present, respectively. Our approach to estimating the time frame of brown bear evolution demonstrates the importance of using an appropriate mutation rate, and this has implications for other studies of Pleistocene populations.

Published

2006

4. Sudden expansion of a single brown bear maternal lineage across northern continental Eurasia after the last ice age: a general demographic model for mammals?

Author

Marju, Korsten, Simon Y W, Ho, John, Davison, Berit, Pähn, Egle, Vulla, Maris, Roht, Igor L, Tumanov, Ilpo, Kojola, Zanete, Andersone-Lilley, Janis, Ozolins, Malgorzata, Pilot, Yorgos, Mertzanis, Alexios, Giannakopoulos, Alex A, Vorobiev, Nikolai I, Markov, Alexander P, Saveljev, Elena A, Lyapunova, Alexei V, Abramov, Peep, Männil, Harri, Valdmann, Sergei V, Pazetnov, Valentin S, Pazetnov, Alexander M, Rõkov, and Urmas, Saarma

Subjects

Geography, Models, Genetic, Population Dynamics, Genetic Variation, Sequence Analysis, DNA, DNA, Mitochondrial, Russia, Europe, Evolution, Molecular, Genetics, Population, Haplotypes, Animals, Phylogeny, Ursidae, Demography

Abstract

The brown bear has proved a useful model for studying Late Quaternary mammalian phylogeography. However, information is lacking from northern continental Eurasia, which constitutes a large part of the species' current distribution. We analysed mitochondrial DNA sequences (totalling 1943 bp) from 205 bears from northeast Europe and Russia in order to characterize the maternal phylogeography of bears in this region. We also estimated the formation times of the sampled brown bear lineages and those of its extinct relative, the cave bear. Four closely related haplogroups belonging to a single mitochondrial subclade were identified in northern continental Eurasia. Several haplotypes were found throughout the whole study area, while one haplogroup was restricted to Kamchatka. The haplotype network, estimated divergence times and various statistical tests indicated that bears in northern continental Eurasia recently underwent a sudden expansion, preceded by a severe bottleneck. This brown bear population was therefore most likely founded by a small number of bears that were restricted to a single refuge area during the last glacial maximum. This pattern has been described previously for other mammal species and as such may represent one general model for the phylogeography of Eurasian mammals. Bayesian divergence time estimates are presented for different brown and cave bear clades. Moreover, our results demonstrate the extent of substitution rate variation occurring throughout the phylogenetic tree, highlighting the need for appropriate calibration when estimating divergence times.

Published

2009

5. Mitogenetic structure of brown bears (Ursus arctos L.) in northeastern Europe and a new time frame for the formation of European brown bear lineages

Author

Urmas, Saarma, Simon Y W, Ho, Oliver G, Pybus, Marju, Kaljuste, Igor L, Tumanov, Ilpo, Kojola, Alex A, Vorobiev, Nikolai I, Markov, Alexander P, Saveljev, Harri, Valdmann, Elena A, Lyapunova, Alexei V, Abramov, Peep, Männil, Marju, Korsten, Egle, Vulla, Sergei V, Pazetnov, Valentin S, Pazetnov, Stanislav V, Putchkovskiy, and Alexander M, Rõkov

Subjects

Base Sequence, Geography, Models, Genetic, Molecular Sequence Data, Population Dynamics, Bayes Theorem, Sequence Analysis, DNA, DNA, Mitochondrial, Russia, Evolution, Molecular, Haplotypes, Animals, Finland, Phylogeny, Ursidae, Demography

Abstract

We estimated the phylogenetic relationships of brown bear maternal haplotypes from countries of northeastern Europe (Estonia, Finland and European Russia), using sequences of mitochondrial DNA (mtDNA) control region of 231 bears. Twenty-five mtDNA haplotypes were identified. The brown bear population in northeastern Europe can be divided into three haplogroups: one with bears from all three countries, one with bears from Finland and Russia, and the third composed almost exclusively of bears from European Russia. Four haplotypes from Finland and European Russia matched exactly with haplotypes from Slovakia, suggesting the significance of the current territory of Slovakia in ancient demographic processes of brown bears. Based on the results of this study and those from the recent literature, we hypothesize that the West Carpathian Mountains have served either as one of the northernmost refuge areas or as an important movement corridor for brown bears of the Eastern lineage towards northern Europe during or after the last ice age. Bayesian analyses were performed to investigate the temporal framework of brown bear lineages in Europe. The molecular clock was calibrated using Beringian brown bear sequences derived from radiocarbon-dated ancient samples, and the estimated mutation rate was 29.8% (13.3%-47.6%) per million years. The whole European population and Western and Eastern lineages formed about 175,000, 70,000 and 25,000 years before present, respectively. Our approach to estimating the time frame of brown bear evolution demonstrates the importance of using an appropriate mutation rate, and this has implications for other studies of Pleistocene populations.

Published

2007