Repeat proliferation and partial endoreplication jointly shape the patterns of genome size evolution in orchids

Although the evolutionary drivers of genome size change are known, the general patterns and mechanisms of plant genome size evolution are yet to be established. Here we aim to assess the relative importance of proliferation of repetitive DNA, chromosomal variation (including polyploidy), and the type of endoreplication for genome size evolution of the Pleurothallidinae, the most species-rich orchid lineage. Phylogenetic relationships between 341 Pleurothallidinae representatives were refined using a target enrichment hybrid capture combined with high-throughput sequencing approach. Genome size and the type of endoreplication were assessed using flow cytometry supplemented with karyological analysis and low-coverage Illumina sequencing for repeatome analysis on a subset of samples. Data were analyzed using phylogeny-based models. Genome size diversity (0.2–5.1 Gbp) was mostly independent of profound chromosome count variation (2n = 12–90) but tightly linked with the overall content of repetitive DNA elements. Species with partial endoreplication (PE) had significantly greater genome sizes, and genomic repeat content was tightly correlated with the size of the non-endoreplicated part of the genome. In PE species, repetitive DNA is preferentially accumulated in the non-endoreplicated parts of their genomes. Our results demonstrate that proliferation of repetitive DNA elements and PE together shape the patterns of genome size diversity in orchids.     

An updated phylogeny,biogeography, and PhyloCode-based classification of Cornaceae based on three sets of genomic data

Premise

A major goal of systematic biology is to uncover the evolutionary history of organisms and translate that knowledge into stable classification systems. Here, we integrate three sets of genome-wide data to resolve phylogenetic relationships in Cornaceae (containing only Cornus s.l.), reconstruct the biogeographic history of the clade, and provide a revised classification using the PhyloCode to stabilize names for this taxonomically controversial group.

Methods

We conducted phylogenetic analyses using 312 single-copy nuclear genes and 70 plastid genes from Angiosperms353 Hyb-Seq, plus numerous loci from RAD-Seq. We integrated fossils using morphological data and produced a dated phylogeny for biogeographical analysis.

Results

A well-resolved, strongly supported, comprehensive phylogeny was obtained. Biogeographic analyses support an origin and rapid diversification of Cornus into four morphologically distinct major clades in the Northern Hemisphere (with an eastern Asian ancestor) during the late Cretaceous. Dispersal into Africa from eastern Asia likely occurred along the Tethys Seaway during the Paleogene, whereas dispersal into South America likely occurred during the Neogene. Diversification within the northern hemisphere likely involved repeated independent colonization of new areas during the Paleogene and Neogene along the Bering Land Bridge, the North Atlantic Land Bridge, and the Tethys Seaway. Thirteen strongly supported clades were named following rules of the PhyloCode.

Conclusions

Our study provides an example of integrating genomic and morphological data to produce a robust, explicit species phylogeny that includes fossil taxa, which we translate into an updated classification scheme using the PhyloCode to stabilize names.     

Hybridization and genome duplication for early evolutionary success in the Asian Palmate group of Araliaceae

The phenomenal advances in sequencing techniques and analytical development during the last decade have provided a unique opportunity to unravel the evolutionary history of lineages under complex patterns of evolution. This is the case of the largest clade of the ginseng family (Araliaceae), the Asian Palmate group (AsPG), where the large internal polytomies and genome incongruences detected in previous studies pointed to a scenario of radiation with hybridization events between genera for the early evolution of the group. In this study, we aim to obtain well-resolved nuclear and plastid phylogenies of the AsPG using Hyb-Seq to evaluate the radiation hypothesis and assess the role of hybridization in the early evolution of the group. We performed concatenated- and coalescent-based phylogenetic analyses from the 936 targeted nuclear loci and 261 plastid loci obtained for 72 species representing 20 genera of the AsPG and the main clades of Araliaceae. The impact of hybridization and incomplete lineage sorting (ILS) was assessed with SNaQ, and genome duplications were evaluated with ChromEvol. Our nuclear and plastid phylogenies are compatible with a scenario of early radiation in the AsPG. Also, the identification of extensive signals of hybridization and ILS behind the genome incongruences supports hybridization as a major driving force during the early radiation. We hypothesize a whole-genome duplication event at the origin of the AsPG, followed by a radiation that led to extensive ILS, which, alongside the early inter-genera hybridization, is obscuring the phylogenetic signal in the early evolution of this major clade.