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Ursine bears are a mammalian subfamily that comprises six morphologically and ecologically distinct extant species. Previous phylogenetic analyses of concatenated nuclear genes could not resolve all relationships among bears, and appeared to conflict with the mitochondrial phylogeny. Evolutionary processes such as incomplete lineage sorting and introgression can cause gene tree discordance and complicate phylogenetic inferences, but are not accounted for in phylogenetic analyses of concatenated data. We generated a high-resolution data set of autosomal introns from several individuals per species and of Y-chromosomal markers. Incorporating intraspecific variability in coalescence-based phylogenetic and gene flow estimation approaches, we traced the genealogical history of individual alleles. Considerable heterogeneity among nuclear loci and discordance between nuclear and mitochondrial phylogenies were found. A species tree with divergence time estimates indicated that ursine bears diversified within less than 2 My. Consistent with a complex branching order within a clade of Asian bear species, we identified unidirectional gene flow from Asian black into sloth bears. Moreover, gene flow detected from brown into American black bears can explain the conflicting placement of the American black bear in mitochondrial and nuclear phylogenies. These results highlight that both incomplete lineage sorting and introgression are prominent evolutionary forces even on time scales up to several million years. Complex evolutionary patterns are not adequately captured by strictly bifurcating models, and can only be fully understood when analyzing multiple independently inherited loci in a coalescence framework. Phylogenetic incongruence among gene trees hence needs to be recognized as a biologically meaningful signal.
Genetic signatures of adaptation revealed from transcriptome sequencing of Arctic and red foxes
(2015)
Background: The genus Vulpes (true foxes) comprises numerous species that inhabit a wide range of habitats and climatic conditions, including one species, the Arctic fox (Vulpes lagopus) which is adapted to the arctic region. A close relative to the Arctic fox, the red fox (Vulpes vulpes), occurs in subarctic to subtropical habitats. To study the genetic basis of their adaptations to different environments, transcriptome sequences from two Arctic foxes and one red fox individual were generated and analyzed for signatures of positive selection. In addition, the data allowed for a phylogenetic analysis and divergence time estimate between the two fox species.
Results: The de novo assembly of reads resulted in more than 160,000 contigs/transcripts per individual. Approximately 17,000 homologous genes were identified using human and the non-redundant databases. Positive selection analyses revealed several genes involved in various metabolic and molecular processes such as energy metabolism, cardiac gene regulation, apoptosis and blood coagulation to be under positive selection in foxes. Branch site tests identified four genes to be under positive selection in the Arctic fox transcriptome, two of which are fat metabolism genes. In the red fox transcriptome eight genes are under positive selection, including molecular process genes, notably genes involved in ATP metabolism. Analysis of the three transcriptomes and five Sanger re-sequenced genes in additional individuals identified a lower genetic variability within Arctic foxes compared to red foxes, which is consistent with distribution range differences and demographic responses to past climatic fluctuations. A phylogenomic analysis estimated that the Arctic and red fox lineages diverged about three million years ago.
Conclusions: Transcriptome data are an economic way to generate genomic resources for evolutionary studies. Despite not representing an entire genome, this transcriptome analysis identified numerous genes that are relevant to arctic adaptation in foxes. Similar to polar bears, fat metabolism seems to play a central role in adaptation of Arctic foxes to the cold climate, as has been identified in the polar bear, another arctic specialist.
Evolutionary genetics of bears and red foxes over phylogenetic and phylogeographic time scales
(2014)
Climatic fluctuations during the Pleistocene (2.6-0.01 million years) have played an important role during evolution of many species. Cyclic range contractions and expansions had demographic consequences within species, provided environmental conditions for population divergence and speciation and enabled secondary contact and interspecific hybridization. These and other evolutionary processes have left genetic signatures in the genomes of affected organisms. Comprehensive and unbiased estimates of evolutionary processes can be obtained using genetic markers from different parts of the genome and by integrating population genetic and phylogenetic concepts.
Suitable for studies on evolutionary processes and patterns over different evolutionary time scales are bears (Ursidae) and foxes (Vulpes), which occupy a wide range of habitats and evolved during the past few millions of years. In my thesis, I therefore used bears and red foxes as study species to investigate the genetic variation within and between species and to obtain estimates of evolutionary relationships and divergence times of populations and species that I interpreted in a climatic context. Further, I investigated population genetic processes during the evolution of bears. My thesis includes three publications and one submitted manuscript, spanning different evolutionary time scales - from evolutionary relationships and processes among species (phylogenetic time scales, Publications I & II), among populations and closely related species in a geographical context (phylogeographic time scales, Publications II & III), to ongoing processes within species (population genetic time scales, Publication IV).
In Publication I (Kutschera et al. 2014, Mol Biol Evol 31(8):2004-2017), I studied bears at several nuclear markers from several individuals per species, complemented with markers from the Y chromosome. Using approaches based on a population genetic concept (coalescent theory) I obtained a species tree with divergence time estimates. Further, I studied two evolutionary processes in bears, interspecific gene flow and incomplete lineage sorting (ILS). This study contributed to the growing evidence that population genetic processes can be relevant on time scales up to several millions of years.
In Publication II (Hailer, Kutschera et al. 2012, Science 336(6079):344-347), we complemented previous mitochondrial (mt) DNA-based inference of the evolutionary history of polar and brown bears with nuclear DNA. Coalescence-based species tree analyses of multiple nuclear markers from several individuals per species placed polar bears as sister lineage to brown bears and their divergence time to about 600 thousand years ago (ka). This contrasted previous mtDNA-based inference. We explained this discrepancy between mtDNA and nuclear DNA with interspecific gene flow between polar and brown bears.
In Publication III (Kutschera et al. 2013, BMC Evol Biol 13:114), I studied range-wide phylogeographic events and their timing in red foxes. A synthesis of newly generated and published mtDNA sequences was analyzed using a coalescence-based approach with multiple fossil calibration points. Thereby, I validated the identity and geographic distribution of several red fox lineages and showed that red foxes colonized North America and Japan several times independently during the late Pleistocene (126-11 ka) and around the last glacial maximum (26.5-19 ka). In a comparison of my results from red foxes to brown bears and grey wolves, I identified similar phylogeographic patterns.
In Publication IV (Kutschera et al., submitted to Biol Conserv), I found similar levels of genetic variability in vagrant polar bears that had reached Iceland compared to established subpopulations from across the range. Based on climate projections reported by the Intergovernmental Panel on Climate Change in 2014, polar bear habitat will markedly decline and become increasingly fragmented within the next decades. Dispersal will play an important role by connecting isolated subpopulations, thereby maintaining genetic diversity levels. My results indicate that vagrants could stabilize genetic variability when immigrating into established subpopulations.
In conclusion, my thesis provided a deeper understanding of evolutionary genetic processes and patterns and their timing in bears and red foxes in a climatic context, which can have conservation implications. Further, I showed that processes like ILS and interspecific gene flow can be relevant over different time scales and are important aspects of evolutionary history. Thereby, my thesis contributed to the knowledge on the evolutionary history of several carnivore species and on evolutionary processes acting within and between closely related species.
A range-wide synthesis and timeline for phylogeographic events in the red fox (Vulpes vulpes)
(2013)
Background: Many boreo-temperate mammals have a Pleistocene fossil record throughout Eurasia and North America, but only few have a contemporary distribution that spans this large area. Examples of Holarctic-distributed carnivores are the brown bear, grey wolf, and red fox, all three ecological generalists with large dispersal capacity and a high adaptive flexibility. While the two former have been examined extensively across their ranges, no phylogeographic study of the red fox has been conducted across its entire Holarctic range. Moreover, no study included samples from central Asia, leaving a large sampling gap in the middle of the Eurasian landmass.
Results: Here we provide the first mitochondrial DNA sequence data of red foxes from central Asia (Siberia), and new sequences from several European populations. In a range-wide synthesis of 729 red fox mitochondrial control region sequences, including 677 previously published and 52 newly obtained sequences, this manuscript describes the pattern and timing of major phylogeographic events in red foxes, using a Bayesian coalescence approach with multiple fossil tip and root calibration points. In a 335 bp alignment we found in total 175 unique haplotypes. All newly sequenced individuals belonged to the previously described Holarctic lineage. Our analyses confirmed the presence of three Nearctic- and two Japan-restricted lineages that were formed since the Mid/Late Pleistocene.
Conclusions: The phylogeographic history of red foxes is highly similar to that previously described for grey wolves and brown bears, indicating that climatic fluctuations and habitat changes since the Pleistocene had similar effects on these highly mobile generalist species. All three species originally diversified in Eurasia and later colonized North America and Japan. North American lineages persisted through the last glacial maximum south of the ice sheets, meeting more recent colonizers from Beringia during postglacial expansion into the northern Nearctic. Both brown bears and red foxes colonized Japan’s northern island Hokkaido at least three times, all lineages being most closely related to different mainland lineages. Red foxes, grey wolves, and brown bears thus represent an interesting case where species that occupy similar ecological niches also exhibit similar phylogeographic histories.