Parallels in leg and wing proximal-distal patterning in Holometabola

The wings and legs of insects are both appendages that develop along a proximal-distal (PD) axis and likely share many underlying patterning mechanisms. Comparisons between the two appendages have been detailed in Drosophila melanogaster, a derived insect where both traits develop initially as imaginal discs. Here, we visualise and compare the expression of prominent PD developmental genes in the embryonic legs and larval wings of a lepidopteran species, Bicyclus anynana. We examine the domains of twelve leg gap genes that subdivide legs into distal, medial, or proximal domains, three morphogens, and two genes that refine the PD axis after initial specification. Our results reveal high spatial congruence in the order of PD gene expression between the two appendages. Notably, we observe a distinct loss of the medial domain in the Bicyclus wing compared to the leg, providing evidence for the evolutionary re-patterning of these structures. Comparisons with Drosophila further highlight conserved versus lineage-specific regulatory architectures. These findings suggest a deeply conserved PD patterning logic across Holometabola, while pointing to divergent mechanisms that likely facilitated the morphological innovation of butterfly wings.