48 research outputs found
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 cladeThis study was financed in
part by the Spanish Ministry of Economy, Industry, and
Competitiveness (CGL2017‐87198‐P), the Spanish Ministry of
Science and Innovation (PID2019‐106840GA‐C22), the Laboratories of Analytical Biology of the Smithsonian Institution,
and the Smithsonian Institution DNA Barcode Network. A.
Gallego‐Narbón was supported by the program “Contratos
predoctorales para Formación de Personal Investigador FPI‐
UAM” of Universidad Autónoma de Madrid (FPI‐UAM 2018)
and the Smithsonian Institution Fellowship Program (SIFP
Nuevos datos sobre la presencia de Coronopus navasii (Brassicaceae) en el Sistema Ibérico
New data concerning the presence of Coronopus navasii (Brassicaceae) in the Iberian System. Information on two new localities of Coronopus navasii Pau found in the Iberian System is provided. The conservation status of the species in this geographical area is discussed in the light of the last field work
Evaluation of tropical–temperate transitions: an example of climatic characterization in the Asian Palmate group of Araliaceae
Premise: There has been a great increase in using climatic data in phylogenetic studies over the past decades. However, compiling the high-quality spatial data needed to perform accurate climatic reconstructions is time-consuming and can result in poor geographical coverage. Therefore, researchers often resort to qualitative approximations. Our aim was to evaluate the climatic characterization of the genera of the Asian Palmate Group (AsPG) of Araliaceae as an exemplar lineage of plants showing tropical–temperate transitions. Methods: We compiled a curated worldwide spatial database of the AsPG genera and created five raster layers representing bioclimatic regionalizations of the world. Then, we crossed the database with the layers to climatically characterize the AsPG genera. Results: We found large disagreement in the climatic characterization of genera among regionalizations and little support for the climatic nature of the tropical–temperate distribution of the AsPG. Both results are attributed to the complexity of delimiting tropical, subtropical, and temperate climates in the world and to the distribution of the study group in regions with transitional climatic conditions. Conclusions: The complexity in the climatic classification of this example of the tropical–temperate transitions calls for a general climatic revision of other tropical–temperate lineages. In fact, we argue that, to properly evaluate tropical–temperate transitions across the tree of life, we cannot ignore the complexity of distribution rangesThis study was supported by the Spanish Ministry of
Economy, Industry and Competitiveness (CGL2017‐87198‐
P) and the Spanish Ministry of Science an Innovation
(PID2019‐106840GA‐C22). M.C.d.l.I. was supported by the
Youth Employment Initiative of European Social Fund and
Community of Madrid (PEJ‐2017‐AI‐AMB‐6636 and
CAM2020PEJD‐2019‐11 PRE/AMB‐15871
Repeated asynchronous evolution of single-species endemics of ivies (Hedera L.) in Macaronesian archipelagos
Aim: Evolutionary studies of oceanic island endemics are usually focused on lineages that have experienced in situ radiation, while those that speciated once on the island or archipelago but have not further diversified (single-species endemics) remain understudied. The Macaronesian archipelagos, in the Atlantic Ocean, are home to significant numbers of single-species endemics. The genus Hedera L. (12 species) includes three single-species endemics from three Macaronesian archipelagos with putatively independent origins. Here, we tested the role of phylogenetic niche conservatism in their evolution. To that end, we (1) reconstructed the spatio-temporal origin of Macaronesian ivies using phylogenomics, and (2) assessed the role of climatic niche during their colonization and speciation. Location: Azores, Canary Islands, Madeira, western Mediterranean. Taxon: Hedera spp. Methods: We used 166 samples representing all Hedera species to generate genotyping-by-sequencing (GBS) libraries and performed time-calibrated phylogenomic and biogeographic analyses. Climatic preferences and climatic niche evolution were assessed using a geo-referenced database of the western ivy species (2,297 records). Results: Independent and asynchronous colonization and speciation were estimated for the three Macaronesian ivies, resulting in different degrees of phylogenetic and climatic niche differentiation: H. canariensis displayed an early divergence (7.5–12 Ma) and high phylogenetic and niche isolation; H. azorica had intermediate phylogenetic isolation and niche divergence from its closest relative H. helix (4.4–6.8 Ma) and H. maderensis was embedded within the climatically similar H. iberica (2.8–4.6 Ma). A strong phylogenetic signal was suggested for climatic niche in the western clade of Hedera, where the three Macaronesian ivies are placed. Main Conclusions: The three Macaronesian ivies represent the evolutionary stages leading to the emergence of single-species island endemics. Climatic niche conservatism appears to be involved in the evolution of single-species endemics, first by facilitating island colonization, and then by limiting in situ diversificationSpanish Ministry of Economy, Industry
and Competitiveness, Grant/Award
Number: CGL2017-87198-P and PID2019-
106840GA-C22; Universidad Autónoma
de Madrid, Grant/Award Number: FPIUAM 201
Innovaciones y mejoras en el proyecto tutoría entre compañeros. Curso 2015-2016
Memoria ID-0137. Ayudas de la Universidad de Salamanca para la innovación docente, curso 2015-2016