González-Rojas, M. F. et al. Chemical signals act as the main reproductive barrier between sister and mimetic Heliconius butterflies. Proceedings of the Royal Society B: Biological Sciences 287, 20200587 (2020).

Concha, C. et al. Interplay between Developmental Flexibility and Determinism in the Evolution of Mimetic Heliconius Wing Patterns. Current Biology 29, 3996-4009.e4 (2019).

Darragh, K. et al. Male sex pheromone components in Heliconius butterflies released by the androconia affect female choice. PeerJ 5, e3953 (2017).

Mann, F. et al. The Scent Chemistry of Heliconius Wing Androconia. J Chem Ecol 1–15 (2017) http://doi.org/10.1007/s10886-017-0867-3.

Nadeau, N. J. et al. The gene cortex controls mimicry and crypsis in butterflies and moths. Nature 534, 106–110 (2016).

Wallbank, R. W. R. et al. Evolutionary novelty in a butterfly wing pattern through enhancer shuffling. PLoS Biol 14, e1002353 (2016).

Sánchez, A. P. et al. An introgressed wing pattern acts as a mating cue. Evolution 69, 1619–1629 (2015).

Pardo-Diaz, C., Salazar, C. & Jiggins, C. D. Towards the identification of the loci of adaptive evolution. Methods Ecol Evol 6, 445–464 (2015).

Pardo-Diaz, C. & Jiggins, C. D. Neighboring genes shaping a single adaptive mimetic trait. Evolution & Development 16, 3–12 (2014).

Pardo-Diaz, C. et al. Adaptive Introgression across Species Boundaries in Heliconius Butterflies. PLoS Genet 8, e1002752 (2012).

Reed, R. D. et al. optix Drives the Repeated Convergent Evolution of Butterfly Wing Pattern Mimicry. Science 333, 1137–1141 (2011).

Salazar, C. et al. Genetic Evidence for Hybrid Trait Speciation in Heliconius Butterflies. PLoS Genet 6, e1000930 (2010).