Polyploidisation and geographic differentiation drive diversification in a European High Mountain Plant Group (Doronicum clusii Aggregate, Asteraceae).
PLoS One. 2015; 10(3):e0118197.Plos

Abstract

Range shifts (especially during the Pleistocene), polyploidisation and hybridization are major factors affecting high-mountain biodiversity. A good system to study their role in the European high mountains is the Doronicum clusii aggregate (Asteraceae), whose four taxa (D. clusii s.s., D. stiriacum, D. glaciale subsp. glaciale and D. glaciale subsp. calcareum) are differentiated geographically, ecologically (basiphilous versus silicicolous) and/or via their ploidy levels (diploid versus tetraploid). Here, we use DNA sequences (three plastid and one nuclear spacer) and AFLP fingerprinting data generated for 58 populations to infer phylogenetic relationships, origin of polyploids-whose ploidy level was confirmed by chromosomally calibrated DNA ploidy level estimates-and phylogeographic history. Taxonomic conclusions were informed, among others, by a Gaussian clustering method for species delimitation using dominant multilocus data. Based on molecular data we identified three lineages: (i) silicicolous diploid D. clusii s.s. in the Alps, (ii) silicicolous tetraploid D. stiriacum in the eastern Alps (outside the range of D. clusii s.s.) and the Carpathians and (iii) the basiphilous diploids D. glaciale subsp. glaciale (eastern Alps) and D. glaciale subsp. calcareum (northeastern Alps); each taxon was identified as distinct by the Gaussian clustering, but the separation of D. glaciale subsp. calcareum and D. glaciale subsp. glaciale was not stable, supporting their taxonomic treatment as subspecies. Carpathian and Alpine populations of D. stiriacum were genetically differentiated suggesting phases of vicariance, probably during the Pleistocene. The origin (autopolyploid versus allopolyploid) of D. stiriacum remained unclear. Doronicum glaciale subsp. calcareum was genetically and morphologically weakly separated from D. glaciale subsp. glaciale but exhibited significantly higher genetic diversity and rarity. This suggests that the more widespread D. glaciale subsp. glaciale originated from D. glaciale subsp. calcareum, which is restricted to a prominent Pleistocene refugium previously identified in other alpine plant species.

Links

PMC Free PDF

Authors+Show Affiliations

Pachschwöll C

Department of Botany and Biodiversity Research, University of Vienna, Rennweg 14, A-1030 Vienna, Austria.

Escobar García P

Department of Botany and Biodiversity Research, University of Vienna, Rennweg 14, A-1030 Vienna, Austria; Department of Botany, Natural History Museum, Burgring 7, A-1010 Vienna, Austria.

Winkler M

Department of Botany and Biodiversity Research, University of Vienna, Rennweg 14, A-1030 Vienna, Austria; GLORIA co-ordination, University of Natural Resources and Life Sciences Vienna, Center for Global Change and Sustainability & Austrian Academy of Sciences, Institute for Interdisciplinary Mountain Research, Silbergasse 30, A-1190 Vienna, Austria.

Schneeweiss GM

Department of Botany and Biodiversity Research, University of Vienna, Rennweg 14, A-1030 Vienna, Austria.

Schönswetter P

Institute of Botany, University of Innsbruck, Sternwartestrasse 15, A-6020 Innsbruck, Austria.

MeSH

AltitudeAsteraceaeEuropeGeographyMolecular Sequence DataPolyploidy

Pub Type(s)

Journal Article

Research Support, Non-U.S. Gov't

Language

eng

PubMed ID

25749621

Citation

Pachschwöll, Clemens, et al. "Polyploidisation and Geographic Differentiation Drive Diversification in a European High Mountain Plant Group (Doronicum Clusii Aggregate, Asteraceae)." PloS One, vol. 10, no. 3, 2015, pp. e0118197.

Pachschwöll C, Escobar García P, Winkler M, et al. Polyploidisation and geographic differentiation drive diversification in a European High Mountain Plant Group (Doronicum clusii Aggregate, Asteraceae). PLoS One. 2015;10(3):e0118197.

Pachschwöll, C., Escobar García, P., Winkler, M., Schneeweiss, G. M., & Schönswetter, P. (2015). Polyploidisation and geographic differentiation drive diversification in a European High Mountain Plant Group (Doronicum clusii Aggregate, Asteraceae). PloS One, 10(3), e0118197. https://doi.org/10.1371/journal.pone.0118197

Pachschwöll C, et al. Polyploidisation and Geographic Differentiation Drive Diversification in a European High Mountain Plant Group (Doronicum Clusii Aggregate, Asteraceae). PLoS One. 2015;10(3):e0118197. PubMed PMID: 25749621.

* Article titles in AMA citation format should be in sentence-case

TY - JOUR T1 - Polyploidisation and geographic differentiation drive diversification in a European High Mountain Plant Group (Doronicum clusii Aggregate, Asteraceae). AU - Pachschwöll,Clemens, AU - Escobar García,Pedro, AU - Winkler,Manuela, AU - Schneeweiss,Gerald M, AU - Schönswetter,Peter, Y1 - 2015/03/06/ PY - 2014/09/09/received PY - 2015/01/08/accepted PY - 2015/3/10/entrez PY - 2015/3/10/pubmed PY - 2016/2/9/medline SP - e0118197 EP - e0118197 JF - PloS one JO - PLoS One VL - 10 IS - 3 N2 - Range shifts (especially during the Pleistocene), polyploidisation and hybridization are major factors affecting high-mountain biodiversity. A good system to study their role in the European high mountains is the Doronicum clusii aggregate (Asteraceae), whose four taxa (D. clusii s.s., D. stiriacum, D. glaciale subsp. glaciale and D. glaciale subsp. calcareum) are differentiated geographically, ecologically (basiphilous versus silicicolous) and/or via their ploidy levels (diploid versus tetraploid). Here, we use DNA sequences (three plastid and one nuclear spacer) and AFLP fingerprinting data generated for 58 populations to infer phylogenetic relationships, origin of polyploids-whose ploidy level was confirmed by chromosomally calibrated DNA ploidy level estimates-and phylogeographic history. Taxonomic conclusions were informed, among others, by a Gaussian clustering method for species delimitation using dominant multilocus data. Based on molecular data we identified three lineages: (i) silicicolous diploid D. clusii s.s. in the Alps, (ii) silicicolous tetraploid D. stiriacum in the eastern Alps (outside the range of D. clusii s.s.) and the Carpathians and (iii) the basiphilous diploids D. glaciale subsp. glaciale (eastern Alps) and D. glaciale subsp. calcareum (northeastern Alps); each taxon was identified as distinct by the Gaussian clustering, but the separation of D. glaciale subsp. calcareum and D. glaciale subsp. glaciale was not stable, supporting their taxonomic treatment as subspecies. Carpathian and Alpine populations of D. stiriacum were genetically differentiated suggesting phases of vicariance, probably during the Pleistocene. The origin (autopolyploid versus allopolyploid) of D. stiriacum remained unclear. Doronicum glaciale subsp. calcareum was genetically and morphologically weakly separated from D. glaciale subsp. glaciale but exhibited significantly higher genetic diversity and rarity. This suggests that the more widespread D. glaciale subsp. glaciale originated from D. glaciale subsp. calcareum, which is restricted to a prominent Pleistocene refugium previously identified in other alpine plant species. SN - 1932-6203 UR - https://www.unboundmedicine.com/medline/citation/25749621/Polyploidisation_and_geographic_differentiation_drive_diversification_in_a_European_High_Mountain_Plant_Group__Doronicum_clusii_Aggregate_Asteraceae__ DB - PRIME DP - Unbound Medicine ER -

Tags

Polyploidisation and geographic differentiation drive diversification in a European High Mountain Plant Group (Doronicum clusii Aggregate, Asteraceae).PLoS One. 2015; 10(3):e0118197.Plos