Recent and recurrent polyploidy in Tragopogon (Asteraceae): cytogenetic, genomic and genetic comparisons

Soltis, Douglas E.; Soltis, Pamela S.; Pires, J. Chris; Kovařı́k, Aleš; Tate, Jennifer A.; Mavrodiev, Evgeny V.

doi:10.1111/j.1095-8312.2004.00335.x

Cited by 322 publications

(346 citation statements)

References 109 publications

(153 reference statements)

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“…Although diploids of each species are well separated according to morphological and neutral molecular marker data, hybridization frequently occurs, especially in plant families that underwent radiation events, e.g., Asteraceae [Helianthus (22), Senecio (23, 24), Tragopogon (25, 26)] and Brassicaceae [Boechera (27), Cardamine (28)]. In numerous of these study systems, hybridization is not one single event, but occurs multiple times-independently and sometimes even polytopically (24,(25)(26)(27)(28). For the A. lyrata × A. arenosa hybrid/introgression system, microsatellite marker data indicate that populations from the eastern Austrian Forealps with their strong hybrid index mark the initial hybridization event, which could have happened during Pleistocene glaciation and deglaciation cycles.…”

Section: Discussionmentioning

confidence: 99%

Arabidopsis hybrid speciation processes

Schmickl

Koch

2011

Proc. Natl. Acad. Sci. U.S.A.

103

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The genus Arabidopsis provides a unique opportunity to study fundamental biological questions in plant sciences using the diploid model species Arabidopsis thaliana and Arabidopsis lyrata. However, only a few studies have focused on introgression and hybrid speciation in Arabidopsis, although polyploidy is a common phenomenon within this genus. More recently, there is growing evidence of significant gene flow between the various Arabidopsis species. So far, we know Arabidopsis suecica and Arabidopsis kamchatica as fully stabilized allopolyploid species. Both species evolved during Pleistocene glaciation and deglaciation cycles in Fennoscandinavia and the amphi-Beringian region, respectively. These hybrid studies were conducted either on a phylogeographic scale or reconstructed experimentally in the laboratory. In our study we focus at a regional and population level. Our research area is located in the foothills of the eastern Austrian Alps, where two Arabidopsis species, Arabidopsis arenosa and A. lyrata ssp. petraea, are sympatrically distributed. Our hypothesis of genetic introgression, migration, and adaptation to the changing environment during the Pleistocene has been confirmed: We observed significant, mainly unidirectional gene flow between the two species, which has given rise to the tetraploid A. lyrata. This cytotype was able to escape from the narrow ecological niche occupied by diploid A. lyrata ssp. petraea on limestone outcrops by migrating northward into siliceous areas, leaving behind a trail of genetic differentiation.Central Europe | evolution | Brassicaceae

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Section: Discussionmentioning

confidence: 99%

Arabidopsis hybrid speciation processes

Schmickl

Koch

2011

Proc. Natl. Acad. Sci. U.S.A.

103

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“…(2n = 2x = 12) and T. porrifolius L. (2n = 2x = 12) from Europe to North America (Soltis et al, 2004). In plants from most natural populations studied in the Palouse area of the northwestern USA, there are fewer rDNA units of T. dubius origin than of T. porrifolius origin .…”

Section: Introductionmentioning

confidence: 98%

Silenced rRNA genes are activated and substitute for partially eliminated active homeologs in the recently formed allotetraploid, Tragopogon mirus (Asteraceae)

et al. 2014

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To study the relationship between uniparental rDNA (encoding 18S, 5.8S and 26S ribosomal RNA) silencing (nucleolar dominance) and rRNA gene dosage, we studied a recently emerged (within the last 80 years) allotetraploid Tragopogon mirus (2n = 24), formed from the diploid progenitors T. dubius (2n = 12, D-genome donor) and T. porrifolius (2n = 12, P-genome donor). Here, we used molecular, cytogenetic and genomic approaches to analyse rRNA gene activity in two sibling T. mirus plants (33A and 33B) with widely different rRNA gene dosages. Plant 33B had~400 rRNA genes at the D-genome locus, which is typical for T. mirus, accounting for~25% of total rDNA. We observed characteristic expression dominance of T. dubius-origin genes in all organs. Its sister plant 33A harboured a homozygous macrodeletion that reduced the number of T. dubius-origin genes to about 70 copies (~4% of total rDNA). It showed biparental rDNA expression in root, flower and callus, but not in leaf where D-genome rDNA dominance was maintained. There was upregulation of minor rDNA variants in some tissues. The RNA polymerase I promoters of reactivated T. porrifolius-origin rRNA genes showed reduced DNA methylation, mainly at symmetrical CG and CHG nucleotide motifs. We hypothesise that active, decondensed rDNA units are most likely to be deleted via recombination. The silenced homeologs could be used as a 'first reserve' to ameliorate mutational damage and contribute to evolutionary success of polyploids. Deletion and reactivation cycles may lead to bidirectional homogenisation of rRNA arrays in the long term.

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“…It arose naturally o80 years ago through allopolyploidisation, with the diploid species T. dubius and T. pratensis as parents (Ownbey, 1950;Soltis et al, 2004a). These parents are phylogenetically divergent (Mavrodiev et al, 2005;Buggs et al, 2008); therefore, homoeologues in T. miscellus can be distinguished by sequence differences (for example, Tate et al, 2006).…”

Section: Introductionmentioning

confidence: 99%

“…These parents are phylogenetically divergent (Mavrodiev et al, 2005;Buggs et al, 2008); therefore, homoeologues in T. miscellus can be distinguished by sequence differences (for example, Tate et al, 2006). The species formed repeatedly in different localities from separate populations of the diploid progenitors (reviewed in Soltis et al, 1995Soltis et al, , 2004a, giving replicated independent natural allopolyploid lines. In addition, we now have multiple, reciprocal synthetic allopolyploid lines of the species (Tate et al, in press).…”

Section: Introductionmentioning

confidence: 99%

Gene loss and silencing in Tragopogon miscellus (Asteraceae): comparison of natural and synthetic allotetraploids

et al. 2009

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Whole-genome duplication (polyploidisation) is a widespread mechanism of speciation in plants. Over time, polyploid genomes tend towards a more diploid-like state, through downsizing and loss of duplicated genes (homoeologues), but relatively little is known about the timing of gene loss during polyploid formation and stabilisation. Several studies have also shown gene transcription to be affected by polyploidisation. Here, we examine patterns of gene loss in 10 sets of homoeologues in five natural populations of the allotetraploid Tragopogon miscellus that arose within the past 80 years following independent whole-genome duplication events. We also examine 44 first-generation synthetic allopolyploids of the same species. No cases of homoeologue loss arose in the first allopolyploid generation, but after 80 years, 1.6% of homoeologues were lost in natural populations. For seven homoeologue sets we also examined transcription, finding that 3.4% of retained homoeologues had been silenced in the natural populations, but none in the synthetic plants. The homoeologue losses and silencing events found were not fixed within natural populations and did not form a predictable pattern among populations. We therefore show haphazard loss and silencing of homoeologues, occurring within decades of polyploid formation in T. miscellus, but not in the initial generation.

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Recent and recurrent polyploidy in Tragopogon (Asteraceae): cytogenetic, genomic and genetic comparisons

Cited by 322 publications

References 109 publications

Arabidopsis hybrid speciation processes

Arabidopsis hybrid speciation processes

Silenced rRNA genes are activated and substitute for partially eliminated active homeologs in the recently formed allotetraploid, Tragopogon mirus (Asteraceae)

Gene loss and silencing in Tragopogon miscellus (Asteraceae): comparison of natural and synthetic allotetraploids

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