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1. Feather Gene Expression Elucidates the Developmental Basis of Plumage Iridescence in African Starlings

   https://doi.org/10.1093/jhered/esab014  

   Rubenstein, Dustin R; Corvelo, André; MacManes, Matthew D; Maia, Rafael; Narzisi, Giuseppe; Rousaki, Anastasia; Vandenabeele, Peter; Shawkey, Matthew D; Solomon, Joseph (April 2021, Journal of Heredity)

   vonHoldt, Bridgett (Ed.)

   Abstract Iridescence is widespread in the living world, occurring in organisms as diverse as bacteria, plants, and animals. Yet, compared to pigment-based forms of coloration, we know surprisingly little about the developmental and molecular bases of the structural colors that give rise to iridescence. Birds display a rich diversity of iridescent structural colors that are produced in feathers by the arrangement of melanin-containing organelles called melanosomes into nanoscale configurations, but how these often unusually shaped melanosomes form, or how they are arranged into highly organized nanostructures, remains largely unknown. Here, we use functional genomics to explore the developmental basis of iridescent plumage using superb starlings (Lamprotornis superbus), which produce both iridescent blue and non-iridescent red feathers. Through morphological and chemical analyses, we confirm that hollow, flattened melanosomes in iridescent feathers are eumelanin-based, whereas melanosomes in non-iridescent feathers are solid and amorphous, suggesting that high pheomelanin content underlies red coloration. Intriguingly, the nanoscale arrangement of melanosomes within the barbules was surprisingly similar between feather types. After creating a new genome assembly, we use transcriptomics to show that non-iridescent feather development is associated with genes related to pigmentation, metabolism, and mitochondrial function, suggesting non-iridescent feathers are more energetically expensive to produce than iridescent feathers. However, iridescent feather development is associated with genes related to structural and cellular organization, suggesting that, while nanostructures themselves may passively assemble, barbules and melanosomes may require active organization to give them their shape. Together, our analyses suggest that iridescent feathers form through a combination of passive self-assembly and active processes. 

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2. Super black plumage is prevalent among Lepidothrix manakins

   https://doi.org/10.1093/ornithology/ukag001  

   Canton, Roberta C; Chow, Able; Moncrieff, Andre E; Brumfield, Robb T; Lord, Nathan P; Faircloth, Brant C (January 2026, Ornithology)

   Abstract Super black plumage has been observed across the avian phylogeny, yet few studies have examined the prevalence of super black plumage at the species and subspecies levels. One group where additional super black taxa likely exist is manakins in the genus Lepidothrix. Previous work on these sexually dichromatic taxa showed that male Lepidothrix velutina (Velvety Manakins) have super black plumage, and we observed that males of several other Lepidothrix taxa have black plumage with a velvety appearance that is often associated with super black barbule morphologies. Here, we combine spectrophotometry with scanning electron microscopy to examine the occurrence of super black plumage throughout Lepidothrix. We determine how the barbules of super black taxa differ structurally from barbules of black taxa that lack super black plumage. Our results show that 5 species and 7 subspecies of Lepidothrix have super black plumage, that barbules of back feathers are wider and closer together in super black taxa than in black taxa, and that the super black plumage trait appears to have evolved multiple times independently in the genus. We also show that olive-green immature males of super black taxa exhibit wider barbules that are closer together than their counterparts, suggesting the development of super black plumage begins before males molt into their definitive adult plumage. 

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3. Complex plumages spur rapid color diversification in kingfishers (Aves: Alcedinidae)

   https://doi.org/10.7554/eLife.83426  

   Eliason, Chad M; McCullough, Jenna M; Hackett, Shannon J; Andersen, Michael J (April 2023, eLife)

   Birds are among the most colorful animals on Earth. The different patterns and colors displayed on their feathers help them to identify their own species, attract mates or hide from predators. The bright plumages of birds are achieved through either pigments (such as reds and yellows) or structures (such as blues, greens or ultraviolet) inside feathers, or through a combination of both pigments and structures. Variation in the diversity of color patterns over time can give a helpful insight into the rate of evolution of a species. For example, structural colors evolve more quickly than pigment-based ones and can therefore be a key feature involved in species recognition or mate attraction. Studying the evolution of plumage patterns has been challenging due to differences in the vision of humans and birds. However, recent advances in technology have enabled researchers to map the exact wavelengths of the colors that make up the patterns, allowing for rigorous comparison of plumage color patterns across different individuals and species. To gain a greater understanding of how plumage color patterns evolve in birds, Eliason et al. studied kingfishers, a group of birds known for their complex and variable color patterns, and their worldwide distribution. The experiments analyzed the plumage color patterns of 72 kingfisher species (142 individual museum specimens) from both mainland and island populations by quantifying the amount of different wavelengths of light reflecting from a feather and accounting for relationships among species and among feather patches. The analyzes showed that having more complex patterns leads to a greater accumulation of plumage colors over time, supporting the idea that complex plumages provide more traits for natural or sexual selection to act upon. Moreover, in upper parts of the bodies, such as the back, the plumage varied more across the different species and evolved faster than in ventral parts, such as the belly or throat. This indicates that sexual selection may be the evolutionary force driving variation in more visible areas, such as the back, while patterns in the ventral part of the body are more important for kin recognition. Eliason et al. further found no differences in plumage complexity between kingfishers located in island or mainland habitats, suggesting that the isolation of the island and the different selection pressures this may bring does not impact the complexity of color patterns. However, kingfisher species located on islands did display higher rates of color evolution. This indicates that, regardless of the complexity of the plumage, island-specific pressures are driving rapid color diversification. Using a new multivariate approach, Eliason et al. have unearthed a pattern in plumage complexity that may otherwise have been missed and, for the first time, have linked differences in color pattern on individual birds with evolutionary differences across species. In doing so, they have provided a framework for future studies of color evolution. The next steps in this research would be to better understand why the island species are evolving more rapidly even though they do not have more complex plumage patterns and how the observed color differences relate to rapid rates of speciation. 

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4. Sequential introgression of a carotenoid processing gene underlies sexual ornament diversity in a genus of manakins

   https://doi.org/10.1126/sciadv.adn8339  

   Lim, Haw Chuan; Bennett, Kevin_F P; Justyn, Nicholas M; Powers, Matthew J; Long, Kira M; Kingston, Sarah E; Lindsay, Willow R; Pease, James B; Fuxjager, Matthew J; Bolton, Peri E; et al (November 2024, Science Advances)

   In a hybrid zone between two tropical lekking birds, yellow male plumage of one species has introgressed asymmetrically replacing white plumage of another via sexual selection. Here, we present a detailed analysis of the plumage trait to uncover its physical and genetic bases and trace its evolutionary history. We determine that the carotenoid lutein underlies the yellow phenotype and describe microstructural feather features likely to enhance color appearance. These same features reduce predicted water shedding capacity of feathers, a potential liability in the tropics. Through genome-scale DNA sequencing of hybrids and each species in the genus, we identifyBCO2as the major gene responsible for the color polymorphism. TheBCO2gene tree and genome-wide allele frequency patterns suggest that carotenoid-pigmented collars initially arose in a third species and reached the hybrid zone through historical gene flow. Complex interplay between sexual selection and hybridization has thus shaped phenotypes of these species, where conspicuous sexual traits are key to male reproductive success. 

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5. Testosterone Coordinates Gene Expression Across Different Tissues to Produce Carotenoid-Based Red Ornamentation

   https://doi.org/10.1093/molbev/msad056  

   Khalil, Sarah; Enbody, Erik D; Frankl-Vilches, Carolina; Welklin, Joseph F; Koch, Rebecca E; Toomey, Matthew B; Sin, Simon Yung; Edwards, Scott V; Gahr, Manfred; Schwabl, Hubert; et al (April 2023, Molecular Biology and Evolution)

   Parsch, John (Ed.)

   Abstract Carotenoid pigments underlie most of the red, orange, and yellow visual signals used in mate choice in vertebrates. However, many of the underlying processes surrounding the production of carotenoid-based traits remain unclear due to the complex nature of carotenoid uptake, metabolism, and deposition across tissues. Here, we leverage the ability to experimentally induce the production of a carotenoid-based red plumage patch in the red-backed fairywren (Malurus melanocephalus), a songbird in which red plumage is an important male sexual signal. We experimentally elevated testosterone in unornamented males lacking red plumage to induce the production of ornamentation and compared gene expression in both the liver and feather follicles between unornamented control males, testosterone-implanted males, and naturally ornamented males. We show that testosterone upregulates the expression of CYP2J19, a gene known to be involved in ketocarotenoid metabolism, and a putative carotenoid processing gene (ELOVL6) in the liver, and also regulates the expression of putative carotenoid transporter genes in red feather follicles on the back, including ABCG1. In black feathers, carotenoid-related genes are downregulated and melanin genes upregulated, but we find that carotenoids are still present in the feathers. This may be due to the activity of the carotenoid-cleaving enzyme BCO2 in black feathers. Our study provides a first working model of a pathway for carotenoid-based trait production in free-living birds, implicates testosterone as a key regulator of carotenoid-associated gene expression, and suggests hormones may coordinate the many processes that underlie the production of these traits across multiple tissues. 

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