Your search keyword '"FABRE, PIERRE"' showing total 2 results

1. Digging for the spiny rat and hutia phylogeny using a gene capture approach, with the description of a new mammal subfamily.

Author

Courcelle, Maxime, Tilak, Marie-Ka, Leite, Yuri L.R., Douzery, Emmanuel J.P., and Fabre, Pierre-Henri

Subjects

*PHYLOGENY, *NUCLEAR DNA, *MOLECULAR evolution, *MOLECULAR phylogeny, *MAMMALS, *SPECIES diversity

Abstract

• 500 nuclear DNA exons with a wide range of evolutionary properties were captured. • Variety in molecular markers evolutionary properties improves phylogenetic analyses. • We provide the first fully supported genus-level phylogeny of Echimyidae rodents. • We define a new subfamily within Echimyidae for the enigmatic Carterodon sulcidens. Next generation sequencing (NGS) and genomic database mining allow biologists to gather and select large molecular datasets well suited to address phylogenomics and molecular evolution questions. Here we applied this approach to a mammal family, the Echimyidae, for which generic relationships have been difficult to recover and often referred to as a star phylogeny. These South-American spiny rats represent a family of caviomorph rodents exhibiting a striking diversity of species and life history traits. Using a NGS exon capture protocol, we isolated and sequenced ca. 500 nuclear DNA exons for 35 species belonging to all major echimyid and capromyid clades. Exons were carefully selected to encompass as much diversity as possible in terms of rate of evolution, heterogeneity in the distribution of site-variation and nucleotide composition. Supermatrix inferences and coalescence-based approaches were subsequently applied to infer this family's phylogeny. The inferred topologies were the same for both approaches, and support was maximal for each node, entirely resolving the ambiguous relationships of previous analyses. Fast-evolving nuclear exons tended to yield more reliable phylogenies, as slower-evolving sequences were not informative enough to disentangle the short branches of the Echimyidae radiation. Based on this resolved phylogeny and on molecular and morphological evidence, we confirm the rank of the Caribbean hutias – formerly placed in the Capromyidae family – as Capromyinae, a clade nested within Echimyidae. We also name and define Carterodontinae, a new subfamily of Echimyidae, comprising the extant monotypic genus Carterodon from Brazil, which is the closest living relative of West Indies Capromyinae. [ABSTRACT FROM AUTHOR]

Published

2019

2. Diversification dynamics in the Neotropics through time, clades, and biogeographic regions.

Author

Meseguer AS, Michel A, Fabre PH, Pérez Escobar OA, Chomicki G, Riina R, Antonelli A, Antoine PO, Delsuc F, and Condamine FL

Subjects

Phylogeny, Brazil, Genetic Speciation, Biodiversity, Plants genetics

Abstract

The origins and evolution of the outstanding Neotropical biodiversity are a matter of intense debate. A comprehensive understanding is hindered by the lack of deep-time comparative data across wide phylogenetic and ecological contexts. Here, we quantify the prevailing diversification trajectories and drivers of Neotropical diversification in a sample of 150 phylogenies (12,512 species) of seed plants and tetrapods, and assess their variation across Neotropical regions and taxa. Analyses indicate that Neotropical diversity has mostly expanded through time (70% of the clades), while scenarios of saturated and declining diversity account for 21% and 9% of Neotropical diversity, respectively. Five biogeographic areas are identified as distinctive units of long-term Neotropical evolution, including Pan-Amazonia, the Dry Diagonal, and Bahama-Antilles. Diversification dynamics do not differ across these areas, suggesting no geographic structure in long-term Neotropical diversification. In contrast, diversification dynamics differ across taxa: plant diversity mostly expanded through time (88%), while a substantial fraction (43%) of tetrapod diversity accumulated at a slower pace or declined towards the present. These opposite evolutionary patterns may reflect different capacities for plants and tetrapods to cope with past climate changes., Competing Interests: AM, AM, PF, OP, GC, RR, AA, PA, FD, FC No competing interests declared, (© 2022, Meseguer et al.)

Published

2022