Third Party Funds Group - Sub project
Acronym: EYESPOT
Start date : 01.10.2021
End date : 30.09.2026
Website: https://cordis.europa.eu/project/id/101000504/de
The ornamental eyespots on the peacock’s tail are examples of structural colouration, which is responsible for some of the most extraordinary visual effects. The structural colours of bird feathers are generated by a combination of pigments and the precise arrangement of nanostructures interacting chemically and physically. However, existing studies focus on the optical and physical aspects of this phenomenon; the underlying molecular mechanisms remain unexplored. The EU-funded EYESPOT project will decipher the genetic and cellular basis of structural colouration by exploiting the exceptional diversity of peacock colour mutations that resulted from captive breeding and exploring wild species that display this phenomenon. The project will integrate techniques and expertise in genetics and genomics, cell and molecular biology, and photonics.
Structural colouration is widespread in nature and generates some of the most stunning visual effects known (e.g. eyespots in a peacock tail). In bird feathers, structural colours are produced by the combination of pigments and precise arrangements of nanostructures that interact both chemically and physically. Currently, almost all published studies on structural colour have focused on the optical and physical aspects of this phenomenon, while the underlying molecular mechanisms remain almost totally unexplored. This proposal seeks to decipher the genetic and cellular basis of structural colours by: 1) exploiting the extraordinary diversity of peacock colour mutants that have emerged from captive breeding, and 2) investigating wild bird species that exhibit structural colouration. My proposal is divided across four multidisciplinary aims that integrate techniques and expertise in the fields of genetics and genomics, cell and molecular biology, and photonics. Aim 1 will elucidate the nanoarchitectural basis of aberrant feather colouration in multiple Mendelian peacock mutants by combining microscopy, spectrophotometry, and chemical analysis of pigment content. Aim 2 will theoretically and experimentally model how abnormalities in the architecture of the photonic lattice result in aberrant light-scattering in these mutants. Aim 3 will combine genetic mapping together with molecular and functional genomic tools for experimental validation and identification of genes controlling the peacock colour phenotypes. Aim 4 will refine our understanding of the evolution of this trait in nature by combining transcriptomic and epigenomic data generated from wild bird species with comparative genomics across the entire avian phylogeny using publicly available genomes. Overall, these studies will significantly expand our understanding of the mechanics and molecular changes underlying a spectacular trait that constitutes a major component of bird phenotypic diversity.