Your search keyword '"Dalén, Love"' showing total 3 results

1. Contrasting genomic consequences of anthropogenic reintroduction and natural recolonization in high-arctic wild reindeer.

Author

Burnett HA, Bieker VC, Le Moullec M, Peeters B, Rosvold J, Pedersen ÅØ, Dalén L, Loe LE, Jensen H, Hansen BB, and Martin MD

Abstract

Anthropogenic reintroduction can supplement natural recolonization in reestablishing a species' distribution and abundance. However, both reintroductions and recolonizations can give rise to founder effects that reduce genetic diversity and increase inbreeding, potentially causing the accumulation of genetic load and reduced fitness. Most current populations of the endemic high-arctic Svalbard reindeer ( Rangifer tarandus platyrhynchus ) originate from recent reintroductions or recolonizations following regional extirpations due to past overharvesting. We investigated and compared the genomic consequences of these two paths to reestablishment using whole-genome shotgun sequencing of 100 Svalbard reindeer across their range. We found little admixture between reintroduced and natural populations. Two reintroduced populations, each founded by 12 individuals around four decades (i.e. 8 reindeer generations) ago, formed two distinct genetic clusters. Compared to the source population, these populations showed only small decreases in genome-wide heterozygosity and increases in inbreeding and lengths of runs of homozygosity. In contrast, the two naturally recolonized populations without admixture possessed much lower heterozygosity, higher inbreeding and longer runs of homozygosity, possibly caused by serial population founder effects and/or fewer or more genetically related founders than in the reintroduction events. Naturally recolonized populations can thus be more vulnerable to the accumulation of genetic load than reintroduced populations. This suggests that in some organisms even small-scale reintroduction programs based on genetically diverse source populations can be more effective than natural recolonization in establishing genetically diverse populations. These findings warrant particular attention in the conservation and management of populations and species threatened by habitat fragmentation and loss., Competing Interests: The authors declare no conflicts of interest., (© 2023 The Authors. Evolutionary Applications published by John Wiley & Sons Ltd.)

Published

2023

2. Range shifts or extinction? Ancient DNA and distribution modelling reveal past and future responses to climate warming in cold-adapted birds.

Author

Lagerholm VK, Sandoval-Castellanos E, Vaniscotte A, Potapova OR, Tomek T, Bochenski ZM, Shepherd P, Barton N, Van Dyck MC, Miller R, Höglund J, Yoccoz NG, Dalén L, and Stewart JR

Subjects

Adaptation, Physiological, Animals, Climate, Cold Temperature, Ecosystem, Europe, Birds genetics, Climate Change, DNA, Ancient

Abstract

Global warming is predicted to cause substantial habitat rearrangements, with the most severe effects expected to occur in high-latitude biomes. However, one major uncertainty is whether species will be able to shift their ranges to keep pace with climate-driven environmental changes. Many recent studies on mammals have shown that past range contractions have been associated with local extinctions rather than survival by habitat tracking. Here, we have used an interdisciplinary approach that combines ancient DNA techniques, coalescent simulations and species distribution modelling, to investigate how two common cold-adapted bird species, willow and rock ptarmigan (Lagopus lagopus and Lagopus muta), respond to long-term climate warming. Contrary to previous findings in mammals, we demonstrate a genetic continuity in Europe over the last 20 millennia. Results from back-casted species distribution models suggest that this continuity may have been facilitated by uninterrupted habitat availability and potentially also the greater dispersal ability of birds. However, our predictions show that in the near future, some isolated regions will have little suitable habitat left, implying a future decrease in local populations at a scale unprecedented since the last glacial maximum., (© 2016 John Wiley & Sons Ltd.)

Published

2017

3. Synchronous genetic turnovers across Western Eurasia in Late Pleistocene collared lemmings.

Author

Palkopoulou E, Baca M, Abramson NI, Sablin M, Socha P, Nadachowski A, Prost S, Germonpré M, Kosintsev P, Smirnov NG, Vartanyan S, Ponomarev D, Nyström J, Nikolskiy P, Jass CN, Litvinov YN, Kalthoff DC, Grigoriev S, Fadeeva T, Douka A, Higham TF, Ersmark E, Pitulko V, Pavlova E, Stewart JR, Węgleński P, Stankovic A, and Dalén L

Subjects

Animals, Arctic Regions, DNA, Ancient analysis, DNA, Mitochondrial analysis, Europe, Fossils, Grassland, North America, Phylogeny, Population Dynamics, Russia, Sequence Analysis, DNA, Tundra, Arvicolinae genetics, Extinction, Biological, Genetic Variation

Abstract

Recent palaeogenetic studies indicate a highly dynamic history in collared lemmings (Dicrostonyx spp.), with several demographical changes linked to climatic fluctuations that took place during the last glaciation. At the western range margin of D. torquatus, these changes were characterized by a series of local extinctions and recolonizations. However, it is unclear whether this pattern represents a local phenomenon, possibly driven by ecological edge effects, or a global phenomenon that took place across large geographical scales. To address this, we explored the palaeogenetic history of the collared lemming using a next-generation sequencing approach for pooled mitochondrial DNA amplicons. Sequences were obtained from over 300 fossil remains sampled across Eurasia and two sites in North America. We identified five mitochondrial lineages of D. torquatus that succeeded each other through time across Europe and western Russia, indicating a history of repeated population extinctions and recolonizations, most likely from eastern Russia, during the last 50 000 years. The observation of repeated extinctions across such a vast geographical range indicates large-scale changes in the steppe-tundra environment in western Eurasia during the last glaciation. All Holocene samples, from across the species' entire range, belonged to only one of the five mitochondrial lineages. Thus, extant D. torquatus populations only harbour a small fraction of the total genetic diversity that existed across different stages of the Late Pleistocene. In North American samples, haplotypes belonging to both D. groenlandicus and D. richardsoni were recovered from a Late Pleistocene site in south-western Canada. This suggests that D. groenlandicus had a more southern and D. richardsoni a more northern glacial distribution than previously thought. This study provides significant insights into the population dynamics of a small mammal at a large geographical scale and reveals a rather complex demographical history, which could have had bottom-up effects in the Late Pleistocene steppe-tundra ecosystem., (© 2016 John Wiley & Sons Ltd.)

Published

2016