4 research outputs found
The symmetry spectrum in a hybridising, tropical group of rhododendrons
Many diverse plant clades possess bilaterally symmetrical flowers and specialised pollination syndromes, suggesting that these traits may promote diversification. We examined the evolution of diverse floral morphologies in a species‐rich tropical radiation of Rhododendron. We used restriction‐site associated DNA sequencing on 114 taxa from Rhododendron sect. Schistanthe to reconstruct phylogenetic relationships and examine hybridisation. We then captured and quantified floral variation using geometric morphometric analyses, which we interpreted in a phylogenetic context. We uncovered phylogenetic conflict and uncertainty caused by introgression within and between clades. Morphometric analyses revealed flower symmetry to be a morphological continuum without clear transitions between radial and bilateral symmetry. Tropical Rhododendron species that began diversifying into New Guinea c. 6 million years ago expanded into novel floral morphological space. Our results showed that the evolution of tropical Rhododendron is characterised by recent speciation, recurrent hybridisation and the origin of floral novelty. Floral variation evolved via changes to multiple components of the corolla that are only recognised in geometric morphometrics with both front and side views of flowers
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Phylogenetic insights into the correlates of dioecy in meadow-rues (Thalictrum, Ranunculaceae)
Numerous studies have examined the evolution of sexual systems in angiosperms, but few explore the
interaction between these and the evolution of pollination mode. Wind pollination is often associated
with unisexual flowers, but which evolved first and played a causative role in the evolution of the other
is unclear. Thalictrum, meadow-rues (Ranunculaceae), provides a unique opportunity to study the evolution
of these traits because it contains insect and wind pollination and four sexual systems. We used a
phylogenetic approach to reconstruct ancestral states for sexual system, pollination mode, and geographic
distribution in Thalictrum, and tested for correlations to uncover the factors involved in the evolution
of unisexuality and wind pollination. Our results show that dioecy, andro- and gynomonoecy
evolved at least twice from hermaphroditism. Wind pollination, unisexual flowers, and New World distribution
were all significantly correlated. Wind pollination may have evolved early in the genus, followed
by multiple losses and gains, and likely preceded the origin of unisexual flowers in several
cases; we found no evidence for unisexual flowers evolving prior to wind pollination. Given a broad scale
study showing the evolution of dioecy before wind pollination, our results from a finer scale analysis
highlight that different evolutionary pathways are likely to occur throughout angiosperms.Keywords: ITS, Thalictrum, Dioecy, rpl16, Monoecy, Wind pollinationKeywords: ITS, Thalictrum, Dioecy, rpl16, Monoecy, Wind pollinatio
Gene Duplication and Differential Expression of Flower Symmetry Genes in Rhododendron (Ericaceae)
Bilaterally symmetric flowers have evolved over a hundred times in angiosperms, yet orthologs of the transcription factors CYCLOIDEA (CYC), RADIALIS (RAD), and DIVARICATA (DIV) are repeatedly implicated in floral symmetry changes. We examined these candidate genes to elucidate the genetic underpinnings of floral symmetry changes in florally diverse Rhododendron, reconstructing gene trees and comparing gene expression across floral organs in representative species with radial and bilateral flower symmetries. Radially symmetric R. taxifolium Merr. and bilaterally symmetric R. beyerinckianum Koord. had four and five CYC orthologs, respectively, from shared tandem duplications. CYC orthologs were expressed in the longer dorsal petals and stamens and highly expressed in R. beyerinckianum pistils, whereas they were either ubiquitously expressed, lost from the genome, or weakly expressed in R. taxifolium. Both species had two RAD and DIV orthologs uniformly expressed across all floral organs. Differences in gene structure and expression of Rhododendron RAD compared to other asterids suggest that these genes may not be regulated by CYC orthologs. Our evidence supports CYC orthologs as the primary regulators of differential organ growth in Rhododendron flowers, while also suggesting certain deviations from the typical asterid gene regulatory network for flower symmetry