Distinct positional identity at the center of the caudal fin establishes forked shape

The morphogenesis of complex vertebrate appendages requires precise regulation of growth, governed by distinct positional identities. The zebrafish caudal fin achieves a symmetrical, forked morphology through the regional specialization of the bony rays: peripheral rays are composed of relatively long, thick segments; while the central rays are made up of shorter, thinner segments, and their overall length is restricted. This length differential establishes the definitive forked shape of the organ. We asked whether these regional morphological differences reflect distinct underlying positional identities. Transcriptomic profiling of intact tissues from adult wild-type zebrafish suggested that central rays possess unique expression profiles, distinct from those of peripheral rays. We previously identified a treatment during embryogenesis that allows excess growth in the central rays, creating a truncate fin shape in adults-we asked whether this novel fin shape was caused by a peripheralization of the central rays. Indeed, the central rays of truncate fins were not only longer, but were composed of longer and thicker individual segments, reminiscent of peripheral rays. Further, gene expression in the central regions of truncate backgrounds showed signatures of peripheral identity. During development of the truncate phenotype, peripheral markers became expressed in more central domains of the growing truncate caudal fin, and in the supportive endoskeleton, the central hypural diastema was lost from the earliest stages. Ultimately, our results demonstrate how adult morphologies may be altered by shifts in positional identities. These findings clarify the anatomical patterning and molecular profiles that underlie regional specialization during caudal fin development.