Plethodontid salamanders capture prey with enhanced tongue protraction relative to other salamander taxa, yet metamorphosing plethodontids are hypothesized to be constrained relative to direct‐developing plethodontids in their degree of tongue evolution (protraction length and velocity) by the presence of a larval stage in development. In this biphasic life history the hyobranchial apparatus serves the conflicting functions of larval suction feeding and adult tongue protraction. The deletion of the larval stage removes one of the conflicting functions and has thus permitted direct‐developing plethodontids to circumvent this constraint and evolve extremely long tongues, which in some species can be projected to 80% of body length. To evaluate this constraint hypothesis and explore taxonomic diversity of feeding behaviours, we studied feeding in larvae, adults and metamorphosing individuals of seven species of metamorphosing plethodontids from the basal taxa Desmognathinae and Hemidactyliini using direct observations, high‐speed videography and kinematic analysis. We found that larval plethodontids suction feed, but feeding is suspended entirely during metamorphosis, and aquatic adults do not suction feed. Adults have exapted the terrestrial modes of tongue and jaw prehension for aquatic prey capture. These findings substantiate the premise that suction feeding and tongue protraction are conflicting functions, and thus our results support the constraint hypothesis. Plethodontid adults have evolved their extreme tongue protraction ability at the expense of adult suction feeding. The rapid metamorphosis that characterizes plethodontids may be an adaptation that minimizes the non‐feeding period imposed by the evolution of derived tongue protraction in adults. © 2002 The Linnean Society of London, Zoological Journal of the Linnean Society, 2002, 134, 375–400.
Salamanders are infrequently mentioned in analyses of tetrapod limb formation, as their development varies considerably from that of amniotes. However, urodeles provide an opportunity to study how limb ontogeny varies with major differences in life history. Here we assess limb development in Desmognathus aeneus, a direct-developing salamander, and compare it to patterns seen in salamanders with larval stages (e.g., Ambystoma mexicanum). Both modes of development result in a limb that is morphologically indistinct from an amniote limb. Developmental series of A. mexicanum and D. aeneus were investigated using Type II collagen immunochemistry, Alcian Blue staining, and whole-mount TUNEL staining. In A. mexicanum, as each digit bud extends from the limb palette Type II collagen and proteoglycan secretion occur almost simultaneously with mesenchyme condensation. Conversely, collagen and proteoglycan secretion in digits of D. aeneus occur only after the formation of an amniote-like paddle. Within each species, Type II collagen expression patterns resemble those of proteoglycans. In both, distal structures form before more proximal structures. This observation is contrary to the proximodistal developmental pattern of other tetrapods and may be unique to urodeles. In support of previous findings, no cell death was observed during limb development in A. mexicanum. However, apoptotic cells that may play a role in digit ontogeny occur in the limbs of D. aeneus, thereby suggesting that programmed cell death has evolved as a developmental mechanism at least twice in tetrapod limb evolution.
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