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1. Ultrabithorax Is a Micromanager of Hindwing Identity in Butterflies and Moths

   https://doi.org/10.3389/fevo.2021.643661  

   Tendolkar, Amruta; Pomerantz, Aaron F.; Heryanto, Christa; Shirk, Paul D.; Patel, Nipam H.; Martin, Arnaud (March 2021, Frontiers in Ecology and Evolution)

   null (Ed.)

   The forewings and hindwings of butterflies and moths (Lepidoptera) are differentiated from each other, with segment-specific morphologies and color patterns that mediate a wide range of functions in flight, signaling, and protection. The Hox gene Ultrabithorax ( Ubx ) is a master selector gene that differentiates metathoracic from mesothoracic identities across winged insects, and previous work has shown this role extends to at least some of the color patterns from the butterfly hindwing. Here we used CRISPR targeted mutagenesis to generate Ubx loss-of-function somatic mutations in two nymphalid butterflies ( Junonia coenia , Vanessa cardui ) and a pyralid moth ( Plodia interpunctella ). The resulting mosaic clones yielded hindwing-to-forewing transformations, showing Ubx is necessary for specifying many aspects of hindwing-specific identities, including scale morphologies, color patterns, and wing venation and structure. These homeotic phenotypes showed cell-autonomous, sharp transitions between mutant and non-mutant scales, except for clones that encroached into the border ocelli (eyespots) and resulted in composite and non-autonomous effects on eyespot ring determination. In the pyralid moth, homeotic clones converted the folding and depigmented hindwing into rigid and pigmented composites, affected the wing-coupling frenulum, and induced ectopic scent-scales in male androconia. These data confirm Ubx is a master selector of lepidopteran hindwing identity and suggest it acts on many gene regulatory networks involved in wing development and patterning. 

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2. Porcupine/Wntless‐dependent trafficking of the conserved WntA ligand in butterflies

   https://doi.org/10.1002/jez.b.23046  

   Hanly, Joseph J.; Robertson, Erica C.; Corning, Olaf B.; Martin, Arnaud (May 2021, Journal of Experimental Zoology Part B: Molecular and Developmental Evolution)

   null (Ed.)

   Wnt ligands are key signaling molecules in animals, but little is known about the evolutionary dynamics and mode of action of the WntA orthologs, which are not present in the vertebrates or in Drosophila. Here we show that the WntA subfamily evolved at the base of the Bilateria + Cnidaria clade, and conserved the thumb region and Ser209 acylation site present in most other Wnts, suggesting WntA requires the core Wnt secretory pathway. WntA proteins are distinguishable from other Wnts by a synapomorphic Iso/Val/Ala216 amino-acid residue that replaces the otherwise ubiquitous Thr216 position. WntA embryonic expression is conserved between beetles and butterflies, suggesting functionality, but the WntA gene was lost three times within arthropods, in podoplean copepods, in the cyclorrhaphan fly radiation, and in ensiferan crickets and katydids. Finally, CRISPR mosaic knockouts (KOs) of porcupine and wntless phenocopied the pattern-specific effects of WntA KOs in the wings of Vanessa cardui butterflies. These results highlight the molecular conservation of the WntA protein across invertebrates, and imply it functions as a typical Wnt ligand that is acylated and secreted through the Porcupine/Wntless secretory pathway. HIGHLIGHTS - WntA was lost in vertebrates and three arthropod lineages including Drosophila - The WntA thumb region and acylation site are conserved - Disruptions of Porcupine (Porc) and Wntless (Wls) recapitulate WntA knockouts in butterfly wings - WntA requires Porc and Wls for acylation and trafficking 

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3. Perfect mimicry between Heliconius butterflies is constrained by genetics and development

   https://doi.org/10.1098/rspb.2020.1267  

   Van Belleghem, Steven M.; Alicea Roman, Paola A.; Carbia Gutierrez, Heriberto; Counterman, Brian A.; Papa, Riccardo (July 2020, Proceedings of the Royal Society B: Biological Sciences)

   null (Ed.)

   Müllerian mimicry strongly exemplifies the power of natural selection. However, the exact measure of such adaptive phenotypic convergence and the possible causes of its imperfection often remain unidentified. Here, we first quantify wing colour pattern differences in the forewing region of 14 co-mimetic colour pattern morphs of the butterfly species Heliconius erato and Heliconius melpomene and measure the extent to which mimicking colour pattern morphs are not perfectly identical. Next, using gene-editing CRISPR/Cas9 KO experiments of the gene WntA , which has been mapped to colour pattern diversity in these butterflies, we explore the exact areas of the wings in which WntA affects colour pattern formation differently in H. erato and H. melpomene. We find that, while the relative size of the forewing pattern is generally nearly identical between co-mimics, the CRISPR/Cas9 KO results highlight divergent boundaries in the wing that prevent the co-mimics from achieving perfect mimicry. We suggest that this mismatch may be explained by divergence in the gene regulatory network that defines wing colour patterning in both species, thus constraining morphological evolution even between closely related species. 

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4. A long noncoding RNA at the cortex locus controls adaptive coloration in butterflies

   https://doi.org/10.1073/pnas.2403326121  

   Livraghi, Luca; Hanly, Joseph J; Evans, Elizabeth; Wright, Charlotte J; Loh, Ling S; Mazo-Vargas, Anyi; Kamrava, Kiana; Carter, Alexander; van_der_Heijden, Eva_S M; Reed, Robert D; et al (September 2024, Proceedings of the National Academy of Sciences)

   Evolutionary variation in the wing pigmentation of butterflies and moths offers striking examples of adaptation by crypsis and mimicry. Thecortexlocus has been independently mapped as the locus controlling color polymorphisms in 15 lepidopteran species, suggesting that it acts as a genomic hotspot for the diversification of wing patterns, but functional validation through protein-coding knockouts has proven difficult to obtain. Our study unveils the role of a long noncoding RNA (lncRNA) which we nameivory, transcribed from thecortexlocus, in modulating color patterning in butterflies. Strikingly,ivoryexpression prefigures most melanic patterns during pupal development, suggesting an early developmental role in specifying scale identity. To test this, we generated CRISPR mosaic knock-outs in five nymphalid butterfly species and show thativorymutagenesis yields transformations of dark pigmented scales into white or light-colored scales. Genotyping ofVanessa carduigermline mutants associates these phenotypes to small on-target deletions at the conserved first exon ofivory. In contrast,cortexgermline mutant butterflies with confirmed null alleles lack any wing phenotype and exclude a color patterning role for this adjacent gene. Overall, these results show that a lncRNA gene acts as a master switch of color pattern specification and played key roles in the adaptive diversification of wing patterns in butterflies. 

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5. Morphogen Patterning in Dynamic Tissues

   https://doi.org/10.1103/h74q-3dgj  

   Plum, Alex M; Serra, Mattia (November 2025, PRX Life)

   Embryogenesis integrates morphogenesis—coordinated cell movements—with morphogen patterning and cell differentiation. While largely studied independently, morphogenesis and patterning often unfold simultaneously in early embryos. Yet how cell movements affect morphogen transport and cells' exposure over time remains unclear, as most pattern formation models assume static tissues. Here we develop a theoretical framework for morphogen patterning in dynamic tissues, recasting advection-reaction-diffusion equations in the cells' moving reference frames. This framework (i) elucidates how morphogenesis mediates morphogen transport and compartmentalization: cell-cell diffusive transport is enhanced at multicellular flow attractors, while repellers act as barriers, affecting cell fate induction and bifurcations. (ii) It formalizes cell-cell signaling ranges in dynamic tissues, deconfounding morphogenetic movements to identify which cells could communicate via morphogens. (iii) It provides two new nondimensional numbers to assess when and where morphogenesis affects morphogen transport. We demonstrate this framework by analyzing classical patterning models with common morphogenetic motifs as well as experimental tissue flows. Our work rationalizes dynamic tissue patterning in development, constraining candidate patterning mechanisms and parameters using accessible cell motion data. 

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