Chromosome-level genome assembly of the swallowtail butterfly Parides eurimedes mylotes is a valuable resource for studying wing coloration

High-quality chromosome-scale assemblies are scarce in Papilionidae. This limits comparative genomics to model species, Lepidoptera, Bombyx mori. Here, we present a phased, chromosome-level genome assembly of Parides eurimedes mylotes. We generated this assembly using 125[x] PacBio HiFi sequencing and assembled it with hifiasm. The final haplotype assemblies (Hap1 and Hap2) span 274 Mb and 270 Mb, respectively. These assemblies are organized into 31 near-telo-mere-to-telomere chromosomes, with scaffold N50 values of 9.72 Mb and 9.22 Mb, respectively. BUSCO analysis revealed assembly completeness of 96.6 % and 96.4 % for Hap1 and Hap2, respectively. Repeats annotation identified 18-19 % repetitive content, with Helitron elements being the dominant class of transposable elements. We identified the W and Z sex chromosomes and completely assembled the mitochondrial genome. Compared to the previously available Parides photinus draft assembly, our genome exhibits an 11,000-fold reduction in scaffold fragmentation and nearly complete gene assembly. This assembly provides a robust genomic reference for functional, evolutionary, and multi-omics investigation in Papilionidae. In addition to serving as a high-quality genomic reference for Papilionidae, this assembly is essential for linking the genetic architecture of butterfly wings to the hierarchical nanostructures underlying structural coloration. By identifying the genes and regulatory networks involved in scale morphogenesis, we can correlate the butterflys genotype with its photonic function. This insight into the evolutionary origin of the biological photonic systems informs the design of biomimetic, structurally colored materials.