Abstract
The dorsal, anal and caudal fins of vertebrates are proposed to have originated by the partitioning and transformation of the continuous median fin fold that is plesiomorphic to chordates. Evaluating this hypothesis has been challenging, because it is unclear how the median fin fold relates to the adult median fins of vertebrates. To understand how new median fins originate, here we study the development and diversity of adipose fins. Phylogenetic mapping shows that in all lineages except Characoidei (Characiformes) adipose fins develop from a domain of the larval median fin fold. To inform how the larva’s median fin fold contributes to the adipose fin, we study Corydoras aeneus (Siluriformes). As the fin fold reduces around the prospective site of the adipose fin, a fin spine develops in the fold, growing both proximally and distally, and sensory innervation, which appears to originate from the recurrent ramus of the facial nerve and from dorsal rami of the spinal cord, develops in the adipose fin membrane. Collectively, these data show how a plesiomorphic median fin fold can serve as scaffolding for the evolution and development of novel, individuated median fins, consistent with the median fin fold hypothesis.
Highlights
Fins have evolved repeatedly in vertebrates[1,2,3,4] and, provide a powerful system for studying how new body parts originate
In all other clades for which data is available, adipose fins appear to develop by the retention of a domain of the larval median fin fold (LMFF) between the dorsal and caudal fin (Fig. 1b)[23]
Adipose fins that develop from the LMFF can evolve skeleton[4,33,44], musculature[32], and sensory anatomy
Summary
Fins have evolved repeatedly in vertebrates[1,2,3,4] and, provide a powerful system for studying how new body parts originate. To inform hypotheses of (1) phylogenetic transformation from MFFs into individuated fins and (2) ontogenetic transformation of the LMFF into adult fins, we study the diversity and development of adipose fins. These appendages have evolved repeatedly within teleosts[4] and are positioned on the dorsal midline between the dorsal and caudal fins. We discuss how these data inform hypotheses of median fin origin in early vertebrates
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