TY - JOUR
T1 - Resilience of genetic diversity in forest trees over the Quaternary
AU - On behalf of the GenTree Consortium
AU - Milesi, Pascal
AU - Kastally, Chedly
AU - Dauphin, Benjamin
AU - Cervantes, Sandra
AU - Bagnoli, Francesca
AU - Budde, Katharina B.
AU - Cavers, Stephen
AU - Fady, Bruno
AU - Faivre-Rampant, Patricia
AU - González-Martínez, Santiago C.
AU - Grivet, Delphine
AU - Gugerli, Felix
AU - Jorge, Véronique
AU - Lesur Kupin, Isabelle
AU - Ojeda, Dario I.
AU - Olsson, Sanna
AU - Opgenoorth, Lars
AU - Pinosio, Sara
AU - Plomion, Christophe
AU - Rellstab, Christian
AU - Rogier, Odile
AU - Scalabrin, Simone
AU - Scotti, Ivan
AU - Vendramin, Giovanni G.
AU - Westergren, Marjana
AU - Lascoux, Martin
AU - Pyhäjärvi, Tanja
N1 - Publisher Copyright:
© The Author(s) 2024.
PY - 2024/12
Y1 - 2024/12
N2 - The effect of past environmental changes on the demography and genetic diversity of natural populations remains a contentious issue and has rarely been investigated across multiple, phylogenetically distant species. Here, we perform comparative population genomic analyses and demographic inferences for seven widely distributed and ecologically contrasting European forest tree species based on concerted sampling of 164 populations across their natural ranges. For all seven species, the effective population size, Ne, increased or remained stable over many glacial cycles and up to 15 million years in the most extreme cases. Surprisingly, the drastic environmental changes associated with the Pleistocene glacial cycles have had little impact on the level of genetic diversity of dominant forest tree species, despite major shifts in their geographic ranges. Based on their trajectories of Ne over time, the seven tree species can be divided into three major groups, highlighting the importance of life history and range size in determining synchronous variation in genetic diversity over time. Altogether, our results indicate that forest trees have been able to retain their evolutionary potential over very long periods of time despite strong environmental changes.
AB - The effect of past environmental changes on the demography and genetic diversity of natural populations remains a contentious issue and has rarely been investigated across multiple, phylogenetically distant species. Here, we perform comparative population genomic analyses and demographic inferences for seven widely distributed and ecologically contrasting European forest tree species based on concerted sampling of 164 populations across their natural ranges. For all seven species, the effective population size, Ne, increased or remained stable over many glacial cycles and up to 15 million years in the most extreme cases. Surprisingly, the drastic environmental changes associated with the Pleistocene glacial cycles have had little impact on the level of genetic diversity of dominant forest tree species, despite major shifts in their geographic ranges. Based on their trajectories of Ne over time, the seven tree species can be divided into three major groups, highlighting the importance of life history and range size in determining synchronous variation in genetic diversity over time. Altogether, our results indicate that forest trees have been able to retain their evolutionary potential over very long periods of time despite strong environmental changes.
KW - 11831 Plant biology
KW - 4112 Forestry
U2 - 10.1038/s41467-024-52612-y
DO - 10.1038/s41467-024-52612-y
M3 - Article
C2 - 39402024
AN - SCOPUS:85206281614
SN - 2041-1723
VL - 15
JO - Nature Communications
JF - Nature Communications
IS - 1
M1 - 8538
ER -