Morphological, functional and evolutionary aspects of tail autotomy and regeneration in the ‘living fossil’Sphenodon (Reptilia: Rhynchocephalia)

Seligmann, Hervé; Moravec, Jiří; Werner, Yehudah L.

doi:10.1111/j.1095-8312.2008.00975.x

Cited by 35 publications

(37 citation statements)

References 56 publications

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“…Corresponding to the relationship between bite force and territoriality in lizards, bite force has been shown to predict reproductive success; the hardest biters enjoy reproductive success nearly four times greater than similarly sized males with the weakest bites (Lappin & Husak 2005;Husak et al 2009). As with lizards (e.g., Lappin & Husak 2005), confrontations between male Sphenodon can be intense and lead to injuries (Buller 1877;Gans et al 1984;Gillingham et al 1995;Seligmann et al 2008). Pathologies occasionally found on Sphenodon dentaries may be the result of healed wounds or infections from wounds incurred during aggressive territorial encounters (Fig.…”

Section: Bite Force and Intrasexual Competitionmentioning

confidence: 99%

Bite‐force performance of the last rhynchocephalian (Lepidosauria:Sphenodon)

Jones

Lappin

2009

Journal of the Royal Society of New Zealand

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We present the first empirical measurements of bite-force performance from adult Sphenodon (Rhynchocephalia), the only extant non-squamate lepidosaur. Using raw bite-force data, we calculated maximum bite forces at the anterior and posterior extremes of the lower tooth row: 81.8 N and 163.5 N (female) and 119.1 N and 238.3 N (male). Combining our results with published data from juvenile animals, we calculated scaling coefficients of bite force on linear morphometrics of body and head size as c. 2.7 (anterior) and c. 3.5+ (posterior). These exceed isometric scaling predictions (2.0), yet are similar to those for other non-avian reptiles. This supports previous views that Sphenodon cannot bite as hard as agamidlizards. We discuss the role of bite force in the behavioural ecology of Sphenodon, propose that the lower temporal bar, unique among extant lepidosaurs, does not necessarily constrain bite force, and evaluate possible effects of other morphological characteristics on bite-force performance.Keywords Rhynchocephalia; skull morphology; ontogeny; feeding; tuatara INTRODUCTIONOne of New Zealand's most iconic animals is the tuatara (Sphenodon) (Parkinson 2002). It is the largest endemic non-avian reptilian and has significant cultural importance for Maori (Sharell 1966; Mot 1997;Ramstad et al. 2007). Currently restricted to approximately 35 small islands and the subject of concerted conservation efforts Mlot 1997;Gaze 2001;Parkinson 2002;Mitchell et al. 2008), Sphenodon is of great scientific significance because it is the only extant member of the Rhynchocephalia, a group that was diverse and globally distributed during the Mesozoic (Apesteguia & Novas 2003;Evans 2003;Jones 2008;Jones et al. 2009). Being the closest living relative (sister group) to Squamata (lizards, snakes, amphisbaenians;Rest et al. 2003;Evans 2003), Sphenodon has been the subject of much research and has played an essential role as an outgroup taxon in comparative studies of squamate biology (e.g., Schwenk 1986Schwenk , 2000McBrayer & Reilly 2002;Vitt et al. 2003;Herrel et al. 2007;Evans 2008; Jones et al. in press).There has been a long-standing interest in numerous aspects of Sphenodon biology, including its dietary ecology and social behaviour, as well as the unique morphology of this taxon's feeding apparatus. The diet of Sphenodon is diverse and comprises ants, moths, caterpillars,

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Section: Bite Force and Intrasexual Competitionmentioning

confidence: 99%

Bite‐force performance of the last rhynchocephalian (Lepidosauria:Sphenodon)

Jones

Lappin

2009

Journal of the Royal Society of New Zealand

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“…Studies on specific tissues that are regenerated in the tail have shown that the new cartilaginous tube and the spinal cord are similar to those of lizards (Alibardi & Meyer‐Rochow, , , ; Alibardi, ). Also, the regenerating scales, although smaller than the original ones and with irregular outlines (Seligmann et al, ), follow a morphogenetic process that resembles that seen in lacertilians (Alibardi & Maderson, ).…”

Section: Introductionmentioning

confidence: 99%

Microscopical observations on the regenerating tail in the tuataraSphenodon punctatusindicate a tendency to scarring, but also influence from somatic growth

Alibardi

Meyer‐Rochow

2019

Journal of Morphology

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The process of tail regeneration in the tuatara (Sphenodon punctatus) is not entirely known. Similarity to and differences from lizard tail regenerations are indicated in the present histological and ultrastructural study. Regeneration is influenced by the animal's age and ambient temperature, but in comparison to that of lizards it is very slow and tends to produce outgrowths that do not reach the length of the original tail. Although microscopically similar to lizard blastemas, the mesenchyme rapidly gives rise to a dense connective tissue that contains few muscle bundles, nerves, and fat cells. The unsegmented cartilaginous tube forming the axial skeleton is not calcified after 5 months of regeneration, but calcification in the inner region of the cartilage, present after 10 months, increases thereafter. Amyelinic and myelinic peripheral nerves are seen within the regenerating tails of 2–3 mm in length and the spinal cord forms an ependymal tube inside a cartilaginous casing. Tissues of the original tail, like muscles, vertebrae and the adipose mass, are largely replaced by dense connective tissue that occupies most of the volume of the new tail at 5 and 10 months of regeneration. It is unknown whether the differentiation of the dense connective tissue is caused by the relatively low temperature that this species lives under or stems from a genetic predisposition toward scarring as with most other amniotes. Increases of muscle and adipose tissues seen in older regenerated tails derive from somatic growth of the new tail in the years following tail loss and not from a rapid regeneration process like that in lizards.

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“…This could be a consequence of extended exposure to potential predators and thus an increased cumulative likelihood of injury and non-zero probability of survival following injury (Schall and Pianka, 1980;White et al, 1982;Willis et al, 1982;Seligmann et al, 2008;see Gregory and Isaac, 2005 for an alternative explanation). In Rhinechis scalaris, a terrestrial colubrid, an ontogenetic shift has been reported in the frequency of tail breakage, with the incidence of tail loss increasing as a logistic function of snake size (Pleguezuelos et al, 2010) resulting from predatory selection for medium-sized R. scalaris by their main predators (see also Gil and Pleguezuelos, 2001).…”

Section: Discussionmentioning

confidence: 99%

“…Tail breakage in snakes has been described as an effective antipredator strategy (Kaufman and Gibbons, 1975;Greene, 1988;Savage and Slowinsky, 1996;Aubret et al, 2005). Given that in snakes tail breakage is without regeneration and the conspicuous nature of this injury, comparisons between individuals, populations, and species are easy (Akani et al, 2002;Seligmann et al, 2008;Pleguezuelos et al, 2010). However, the interpretation of this injury is controversial (Willis Seligmann et al, 1996;Placyk and Burghardt, 2005), and it has been proposed that tail breakage may simply be evidence of inefficient predation (Schoener, 1979;Willis et al, 1982;Medel et al, 1988;Mushinsky and Miller, 1993) instead of predation risk (Jacksić and Busack, 1984).…”

Section: Introductionmentioning

confidence: 99%

Tail breakage frequency as an indicator of predation risk for the aquatic snake Natrix maura

et al. 2011

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It is difficult to measure predation risk for secretive animals such as snakes. The frequency of tail breakage has been suggested as a parameter for measuring predation risk in these reptiles. Consequently, we hypothesise that tail breakage frequency is expected to vary intraspecifically between populations submitted to different numbers of predators, probably, to different predation risk. The colubrid snake Natrix maura has adapted to living on fish farms, which are protected from aerial predators by wire mesh, so that these farms provide researchers with a predator-exclusion scenario. We measured tail breakage frequency in this snake on a fish farm and compared the results with data from three populations in natural settings in the Iberian Peninsula under assumed higher predation risk from a complete community of predators. A logistic regression analysis demonstrated that snake body size and predator exclusion affected the probability of tail breakage, while sex had no effect. We found an ontogenetic increase in the frequency of tail breakage, a general pattern in snakes and, notably, marked differences between populations according to predation risk: snakes from the fish farm showed a low frequency of tail breakage (5.1%), whereas snakes from natural habitats, with five-fold more potential predators on average, demonstrated a higher frequency of tail breakage (18.7%). We conclude that tail breakage frequency is a reliable indicator of predation risk in this aquatic snake.

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Morphological, functional and evolutionary aspects of tail autotomy and regeneration in the ‘living fossil’Sphenodon (Reptilia: Rhynchocephalia)

Cited by 35 publications

References 56 publications

Bite‐force performance of the last rhynchocephalian (Lepidosauria:Sphenodon)

Bite‐force performance of the last rhynchocephalian (Lepidosauria:Sphenodon)

Microscopical observations on the regenerating tail in the tuataraSphenodon punctatusindicate a tendency to scarring, but also influence from somatic growth

Tail breakage frequency as an indicator of predation risk for the aquatic snake Natrix maura

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