Highlighting convergent evolution in morphological traits in response to climatic gradient in African tropical tree species: The case of genus Guibourtia Benn

• Published in: Ecology and evolution Vol. 9; no. 23; pp. 13114 - 13126
• Main Authors: Tosso, Félicien, Doucet, Jean‐Louis, Daïnou, Kasso, Fayolle, Adeline, Hambuckers, Alain, Doumenge, Charles, Agbazahou, Honoré, Stoffelen, Piet, Hardy, Olivier J.
• Format: Journal Article Web Resource
• Language: English
• Published: England John Wiley & Sons, Inc 01.12.2019; Wiley; John Wiley and Sons Inc
• Subjects: Adaptation; Biological evolution; Convergence; Correlation; Divergence; Ecological niches; Environmental conditions; Environmental sciences & ecology; Environmental testing; Evolution; Evolutionary ecology; Flowers & plants; Forests; Guibourtia; Inertia; Life sciences; Macroevolution; Morphology; Niche comparison; Niches; Original Research; Phenotypic adaptation; Phylogenetic Independent Contrast; Phylogenetic signal; Phylogenetics; Phylogeny; Quantitative genetics; Rainforests; Relative humidity; Sciences de l’environnement & écologie; Sciences du vivant; Soil conditions; Solar radiation; Speciation; Species; Taxonomy; Trees; Tropical plants; Woodlands; Belgium; Guibourtia; niche comparison; Phylogenetic Independent Contrast; taxonomy; phenotypic adaptation; evolutionary ecology; phylogenetic signal; speciation
• ISSN: 2045-7758; 2045-7758
• DOI: 10.1002/ece3.5740

Adaptive evolution is a major driver of organism diversification, but the links between phenotypic traits and environmental niche remain little documented in tropical trees. Moreover, trait‐niche relationships are complex because a correlation between the traits and environmental niches displayed by a sample of species may result from (a) convergent evolution if different environmental conditions have selected different sets of traits, and/or (b) phylogenetic inertia if niche and morphological differences between species are simply function of their phylogenetic divergence, in which case the trait‐niche correlation does not imply any direct causal link. Here, we aim to assess the respective roles of phylogenetic inertia and convergent evolution in shaping the differences of botanical traits and environmental niches among congeneric African tree species that evolved in different biomes. This issue was addressed with the tree genus Guibourtia Benn. (Leguminosae and Detarioideae), which contains 13 African species occupying various forest habitat types, from rain forest to dry woodlands, with different climate and soil conditions. To this end, we combined morphological data with ecological niche modelling and used a highly resolved plastid phylogeny of the 13 African Guibourtia species. First, we demonstrated phylogenetic signals in both morphological traits (Mantel test between phylogenetic and morphological distances between species: r = .24, p = .031) and environmental niches (Mantel test between phylogenetic and niche distances between species: r = .23, p = .025). Second, we found a significant correlation between morphology and niche, at least between some of their respective dimensions (Mantel's r = .32, p = .013), even after accounting for phylogenetic inertia (Phylogenetic Independent Contrast: r = .69, p = .018). This correlation occurred between some leaflet and flower traits and solar radiation, relative humidity, precipitations, and temperature range. Our results demonstrate the convergent evolution of some morphological traits in response to climatic factors in congeneric tree species and highlight the action of selective forces, along with neutral ones, in shaping the divergence between congeneric tropical plants. Here, we aim to assess the respective roles of phylogenetic inertia and convergent evolution in shaping the differences of botanical traits and environmental niches among congeneric African tree species that evolved in different biomes. Our results demonstrate for the first time the convergent evolution of some morphological traits in response to climatic factors in congeneric tree species and highlight the action of selective forces, along with neutral ones, in shaping the divergence between congeneric tropical plants.