TY - DATA T1 - Supplementary Material from Climatic niche evolution is faster in sympatric than allopatric lineages of the butterfly genus Pyrgus PY - 2017/04/08 AU - Camille Pitteloud AU - Nils Arrigo AU - Tomasz Suchan AU - Alicia Mastretta-Yanes AU - Roger Vila AU - Vlad Dincă AU - Juan Hernández-Roldán AU - Ernst Brockmann AU - Yannick Chittaro AU - Irena Kleckova AU - Luca Fumagalli AU - Sven Buerki AU - Loïc Pellissier AU - Nadir Alvarez UR - https://rs.figshare.com/articles/journal_contribution/Supplementary_Material_from_Climatic_niche_evolution_is_faster_in_sympatric_than_allopatric_lineages_of_the_butterfly_genus_i_Pyrgus_i_/4789627 DO - 10.6084/m9.figshare.4789627.v2 L4 - https://ndownloader.figshare.com/files/8019780 KW - climatic niche KW - macro-evolutionary processes KW - parametric biogeography KW - next-generation sequencing N2 - Understanding how speciation relates to ecological divergence has long fascinated biologists. It is assumed that ecological divergence is essential to sympatric speciation, as a mechanism to avoid competition and eventually lead to reproductive isolation, while divergence in allopatry is not necessarily associated with niche differentiation. The impact of the spatial context of divergence on the evolutionary rates of abiotic dimensions of the ecological niche has rarely been explored for an entire clade. Here, we compare the magnitude of climatic niche shifts between sympatric versus allopatric divergence of lineages in butterflies. By combining next-generation sequencing, parametric biogeography and ecological niche analyses applied to a genus-wide phylogeny of Palaearctic Pyrgus butterflies, we compare evolutionary rates along eight climatic dimensions across sister lineages that diverged in large-scale sympatry versus allopatry. In order to examine the possible effects of the spatial scale at which sympatry is defined, we considered three sets of biogeographic assignments, ranging from narrow to broad definition. Our findings suggest higher rates of niche evolution along all climatic dimensions for sister lineages that diverge in sympatry, when using a narrow delineation of biogeographic areas. This result contrasts with significantly lower rates of climatic niche evolution found in cases of allopatric speciation, despite the biogeographic regions defined here being characterized by significantly different climates. Higher rates in allopatry are retrieved when biogeographic areas are too widely defined—in such a case allopatric events may be recorded as sympatric. Our results reveal the macro-evolutionary significance of abiotic niche differentiation involved in speciation processes within biogeographic regions, and illustrate the importance of the spatial scale chosen to define areas when applying parametric biogeographic analyses. ER -