AI Article Synopsis
- The evolution of the autopod (wrist and digits) involved losing the fin-fold and its dermal skeleton, while enhancing the endoskeleton.
- Developmental studies in fish suggest that a delay in converting the AER to a fin-fold allowed for more endoskeletal development, contributing to appendage evolution.
- Research on paddlefish and catsharks shows similarities in fin development and suggests that limb structures evolved from changes in early developmental patterns rather than just timing differences.
Article Abstract
The evolutionary origin of the autopod involved a loss of the fin-fold and associated dermal skeleton with a concomitant elaboration of the distal endoskeleton to form a wrist and digits. Developmental studies, primarily from teleosts and amniotes, suggest a model for appendage evolution in which a delay in the AER-to-fin-fold conversion fuelled endoskeletal expansion by prolonging the function of AER-mediated regulatory networks. Here, we characterize aspects of paired fin development in the paddlefish (a non-teleost actinopterygian) and catshark (chondrichthyan) to explore aspects of this model in a broader phylogenetic context. Our data demonstrate that in basal gnathostomes, the autopod marker co-localizes with the dermoskeleton component to mark the position of the fin-fold, supporting recent work demonstrating a role for in zebrafish fin ray development. Additionally, we show that in paddlefish, the proximal fin and fin-fold mesenchyme share a common mesodermal origin, and that components of the Shh/LIM/Gremlin/Fgf transcriptional network critical to limb bud outgrowth and patterning are expressed in the fin-fold with a profile similar to that of tetrapods. Together these data draw contrast with hypotheses of AER heterochrony and suggest that limb-specific morphologies arose through evolutionary changes in the differentiation outcome of conserved early distal patterning compartments.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC5454254 | PMC |
| http://dx.doi.org/10.1098/rspb.2016.2780 | DOI Listing |
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