Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae)

Polyploidization has occurred many times during the evolution of angiosperms. Allopolyploidization is believed to be the process behind many of these genome duplications, and has resulted in a genetically diverse angiosperm flora. I have investigated the patterns of allopolyploidization in the tribe...

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Bibliographic Details
Main Author: Töpel, Mats
Format: Doctoral or Postdoctoral Thesis
Language:English
Published: 2010
Subjects:
Potentilla
Ivesia
Horkelia
allopolyploidization
TGGE
Beringia
Arctic
Climate change
Online Access:http://hdl.handle.net/2077/22321
id ftunivgoeteborg:oai:gupea.ub.gu.se:2077/22321
record_format openpolar
institution Open Polar
collection University of Gothenburg: GUPEA (Gothenburg University Publications Electronic Archive)
op_collection_id ftunivgoeteborg
language English
topic Potentilla
Ivesia
Horkelia
allopolyploidization
TGGE
Beringia
spellingShingle Potentilla
Ivesia
Horkelia
allopolyploidization
TGGE
Beringia
Töpel, Mats
Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae)
topic_facet Potentilla
Ivesia
Horkelia
allopolyploidization
TGGE
Beringia
description Polyploidization has occurred many times during the evolution of angiosperms. Allopolyploidization is believed to be the process behind many of these genome duplications, and has resulted in a genetically diverse angiosperm flora. I have investigated the patterns of allopolyploidization in the tribe Potentilleae (Rosaceae), where many species have been proposed to have an allopolyploid origin. I have assessed the extent of allopolyploization in the group, with special emphasis on genus Potentilla, by comparing a topology based on nuclear data to one based on plastid data. This led to the identification of several incongruences that supports the notion of a reticulated evolution of the group. However, this has to be confirmed as not all incongruences identified with this method have to be the result of hybridization. Instead, further phylogenetic inference of relationships among the proposed allopolyploid species has to utilise low-copy nuclear genes. For future prospects, I have therefore evaluated Temperature Gradient Gel Electrophoresis (TGGE) for separating paralogues of low-copy nuclear genes. The method was found to require fewer PCR and sequencing reactions, compared to bacterial subcloning, a method routinely used to separate heterogeneous DNA samples. TGGE was therefore found it to be an efficient and applicable method for separating gene copies for phylogenetic investigations of allopolyploid species. The work presented in this thesis has also provided new insights into the evolution of Potentilleae. The phylogenetic analysis show that the ivesioid Potentilleae, a morphologically aberrant and diverse group comprising the three North American genera Ivesia, Horkelia and Horkeliella, form a well-supported clade nested within the Potentilla clade. Furthermore, a dated phylogeny of the family Rosaceae finds this clade to have originated approximately 25 Ma, a time when climate change is believed to have reshaped the flora of western North America. The analysis using phyloclimatic modeling of the evolution of the group reveals a close connection to climate change. The results indicate Great Basin as the area of origin and a westward range expansion to Sierra Nevada during Miocene. Several lineages were found to have crossed the mountain range after a Mediterranean type of climate had established in California. The analysis of microsatellite and AFLP data propose that climate change also have influenced the genetic diversity in Arctic populations. Geographical patterns of this diversity corroborate the hypothesis that Beringia served as a refugium for plants during the Wisconsinan glaciation. Evidence of additional refugia on Banks, Prince Patrick and Melville Islands was also found and further supported by geological data on ice expansion at the last glacial maximum. From the results of the investigations conducted during my thesis work I therefore conclude that allopolyploidization and climate change have had a great influence on the evolution of Potentilleae.
format Doctoral or Postdoctoral Thesis
author Töpel, Mats
author_facet Töpel, Mats
author_sort Töpel, Mats
title Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae)
title_short Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae)
title_full Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae)
title_fullStr Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae)
title_full_unstemmed Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae)
title_sort phylogenetic and phyloclimatic inference of the evolution of potentilleae (rosaseae)
publishDate 2010
url http://hdl.handle.net/2077/22321
geographic Arctic
geographic_facet Arctic
genre Arctic
Climate change
Beringia
genre_facet Arctic
Climate change
Beringia
op_relation 1. Töpel M, Lundberg M, Eriksson T, Eriksen B. Molecular data indicate several putative hybridization events in the genus Potentilla (Rosaceae). Manuscript.
2. Lundberg M, Töpel M, Eriksen B, Nylander JA, Eriksson T. (2009) Allopolyploidy in Fragariinae (Rosaceae): comparing four DNA sequence regions, with comments on classification. Mol Phyl Evol. 51(2). 269-280.::doi::10.1016/j.ympev.2009.02.020
3. Eriksen B, Töpel M, (2006) Molecular phylogeography and hybridization in members of the circumpolar Potentilla sect. Niveae (Rosaceae). Am J Bot. 93. 460-469.
4. Töpel M, Antonelli A, Yesson C, Eriksen B. Phyloclimatic modeling of the evolution of the ivesioid Potentilleae (Rosaceae). Manuscript.
5. Töpel M, Brosché S, Scheen AC. Temperature Gradient Gel Electrophoresis (TGGE): an alternative to cloning for separation of low- copy gene paralogues. Manuscript.
_version_ 1766349766673825792
spelling ftunivgoeteborg:oai:gupea.ub.gu.se:2077/22321 2023-05-15T15:19:34+02:00 Phylogenetic and phyloclimatic inference of the evolution of Potentilleae (Rosaseae) Töpel, Mats 2010-05-20T12:14:17Z http://hdl.handle.net/2077/22321 eng eng 1. Töpel M, Lundberg M, Eriksson T, Eriksen B. Molecular data indicate several putative hybridization events in the genus Potentilla (Rosaceae). Manuscript. 2. Lundberg M, Töpel M, Eriksen B, Nylander JA, Eriksson T. (2009) Allopolyploidy in Fragariinae (Rosaceae): comparing four DNA sequence regions, with comments on classification. Mol Phyl Evol. 51(2). 269-280.::doi::10.1016/j.ympev.2009.02.020 3. Eriksen B, Töpel M, (2006) Molecular phylogeography and hybridization in members of the circumpolar Potentilla sect. Niveae (Rosaceae). Am J Bot. 93. 460-469. 4. Töpel M, Antonelli A, Yesson C, Eriksen B. Phyloclimatic modeling of the evolution of the ivesioid Potentilleae (Rosaceae). Manuscript. 5. Töpel M, Brosché S, Scheen AC. Temperature Gradient Gel Electrophoresis (TGGE): an alternative to cloning for separation of low- copy gene paralogues. Manuscript. Potentilla Ivesia Horkelia allopolyploidization TGGE Beringia Doctoral thesis 2010 ftunivgoeteborg 2019-06-21T08:33:30Z Polyploidization has occurred many times during the evolution of angiosperms. Allopolyploidization is believed to be the process behind many of these genome duplications, and has resulted in a genetically diverse angiosperm flora. I have investigated the patterns of allopolyploidization in the tribe Potentilleae (Rosaceae), where many species have been proposed to have an allopolyploid origin. I have assessed the extent of allopolyploization in the group, with special emphasis on genus Potentilla, by comparing a topology based on nuclear data to one based on plastid data. This led to the identification of several incongruences that supports the notion of a reticulated evolution of the group. However, this has to be confirmed as not all incongruences identified with this method have to be the result of hybridization. Instead, further phylogenetic inference of relationships among the proposed allopolyploid species has to utilise low-copy nuclear genes. For future prospects, I have therefore evaluated Temperature Gradient Gel Electrophoresis (TGGE) for separating paralogues of low-copy nuclear genes. The method was found to require fewer PCR and sequencing reactions, compared to bacterial subcloning, a method routinely used to separate heterogeneous DNA samples. TGGE was therefore found it to be an efficient and applicable method for separating gene copies for phylogenetic investigations of allopolyploid species. The work presented in this thesis has also provided new insights into the evolution of Potentilleae. The phylogenetic analysis show that the ivesioid Potentilleae, a morphologically aberrant and diverse group comprising the three North American genera Ivesia, Horkelia and Horkeliella, form a well-supported clade nested within the Potentilla clade. Furthermore, a dated phylogeny of the family Rosaceae finds this clade to have originated approximately 25 Ma, a time when climate change is believed to have reshaped the flora of western North America. The analysis using phyloclimatic modeling of the evolution of the group reveals a close connection to climate change. The results indicate Great Basin as the area of origin and a westward range expansion to Sierra Nevada during Miocene. Several lineages were found to have crossed the mountain range after a Mediterranean type of climate had established in California. The analysis of microsatellite and AFLP data propose that climate change also have influenced the genetic diversity in Arctic populations. Geographical patterns of this diversity corroborate the hypothesis that Beringia served as a refugium for plants during the Wisconsinan glaciation. Evidence of additional refugia on Banks, Prince Patrick and Melville Islands was also found and further supported by geological data on ice expansion at the last glacial maximum. From the results of the investigations conducted during my thesis work I therefore conclude that allopolyploidization and climate change have had a great influence on the evolution of Potentilleae. Doctoral or Postdoctoral Thesis Arctic Climate change Beringia University of Gothenburg: GUPEA (Gothenburg University Publications Electronic Archive) Arctic

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