The Shh/Gli3 gene regulatory network precedes the origin of paired fins and reveals the deep homology between distal fins and digits

Joaquín Letelier,Silvia Naranjo,Ismael Sospedra-Arrufat,Juan Ramón Martinez-Morales,Javier Lopez-Rios,Neil Shubin,José Luis Gómez-Skarmeta

doi:10.1073/pnas.2100575118

Abstract

One of the central problems of vertebrate evolution is understanding the relationship among the distal portions of fins and limbs. Lacking comparable morphological markers of these regions in fish and tetrapods, these relationships have remained uncertain for the past century and a half. Here we show that Gli3 functions in controlling the proliferative expansion of distal progenitors are shared among dorsal and paired fins as well as tetrapod limbs. Mutant knockout gli3 fins in medaka (Oryzias latipes) form multiple radials and rays, in a pattern reminiscent of the polydactyly observed in Gli3-null mutant mice. In limbs, Gli3 controls both anterior-posterior patterning and cell proliferation, two processes that can be genetically uncoupled. In situ hybridization, quantification of proliferation markers, and analysis of regulatory regions reveal that in paired and dorsal fins, gli3 plays a main role in controlling proliferation but not in patterning. Moreover, gli3 down-regulation in shh mutant fins rescues fin loss in a manner similar to how Gli3 deficiency restores digits in the limbs of Shh mutant mouse embryos. We hypothesize that the Gli3/Shh gene pathway preceded the origin of paired appendages and was originally involved in modulating cell proliferation. Accordingly, the distal regions of dorsal fins, paired fins, and limbs retain a deep regulatory and functional homology that predates the origin of paired appendages.

Highlights

One of the central problems of vertebrate evolution is understanding the relationship among the distal portions of fins and limbs
Letelier et al The Shh/Gli3 gene regulatory network precedes the origin of paired fins and reveals the deep homology between distal fins and digits
Our results show that the presence of the shh/gli3 regulatory network in fish fins, so vital for limb formation and digit patterning, is primitive to limbs

Summary

Introduction

One of the central problems of vertebrate evolution is understanding the relationship among the distal portions of fins and limbs. Gli3-deficient mice show Shh pathway derepression in the anterior limb bud margin, leading to the anterior expansion of the expression domains of posterior markers and concordant down-regulation of anterior transcription factors [9,10,11,12,13,14] These mutants reveal polydactylous manus and pes along with softtissue fusion of digits. While Gli functions and interactions with Shh are essential features of limb development, little is known about its role in fins This deficit is unfortunate because an understanding of this issue could reveal the origin of distal patterns between the two organs. We show that the inactivation of the gli gene in medaka fish results in the formation of larger dorsal and paired fins These mutant fins display multiple radial bones and fin rays which resemble polydactyly in Gli3-deficient mice. We show that the key regulatory networks that mediate the expansion of digit progenitor cells in tetrapods were already in place in the fins of the last common ancestor between ray and lobefinned fishes, suggesting an ancient similarity between distal fins and digits

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