Open AccessHigh level of novelty under the hood of convergent evolution
Author(s) -
Steven M. Van Belleghem,
Angelo Alberto Ruggieri,
Carolina Concha,
Luca Livraghi,
Laura Hebberecht,
Edgardo Santiago Rivera,
James G. Ogilvie,
Joseph J. Hanly,
Ian A. Warren,
Silvia Planas,
Yadira Ortiz-Ruiz,
Robert D. Reed,
James J. Lewis,
Chris D. Jiggins,
Brian A. Counterman,
W. Owen McMillan,
Riccardo Papa
Publication year - 2023
Publication title -
science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 12.556
H-Index - 1186
eISSN - 1095-9203
pISSN - 0036-8075
DOI - 10.1126/science.ade0004
Subject(s) - convergent evolution , biology , evolutionary biology , lineage (genetic) , chromatin , mimicry , enhancer , novelty , gene , convergence (economics) , phenotype , genetics , computational biology , phylogenetics , gene expression , ecology , philosophy , theology , economics , economic growth
Little is known about the extent to which species use homologous regulatory architectures to achieve phenotypic convergence. By characterizing chromatin accessibility and gene expression in developing wing tissues, we compared the regulatory architecture of convergence between a pair of mimetic butterfly species. Although a handful of color pattern genes are known to be involved in their convergence, our data suggest that different mutational paths underlie the integration of these genes into wing pattern development. This is supported by a large fraction of accessible chromatin being exclusive to each species, including the de novo lineage-specific evolution of a modular optix enhancer. These findings may be explained by a high level of developmental drift and evolutionary contingency that occurs during the independent evolution of mimicry.
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