The origin(s) of extant amphibians: a review with emphasis on the “lepospondyl hypothesis”

Marjanović, David; Laurin, Michel

doi:10.5252/g2013n1a8

Cited by 84 publications

(132 citation statements)

References 140 publications

(58 reference statements)

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“…Branch lengths were calculated from estimated divergence times of the different nodes taken from the literature, because characters and clustering methods used to construct trees might have been different and thus might have affected branch lengths. Phylogenetic trees were constructed from Vidal and Hedges [68], Mulcahy et al [69] and Amer and Kumazawa [70] for squamates; Hackett et al [71] for birds; Marjanovic and Laurin [72] and Clack [73] for non-amniote tetrapods; Bennett [74] and Nesbitt [75] for non-dinosaurian archosaurs; Pisani et al [76] and Brusatte et al [77] for tyrannosaurid dinosaurs; Yates [78]–[79]; Sereno [80]; Allain and Aquesbi [81]; Remes et al [82] for Sauropodomorpha and Beck et al [83] and Perelman et al [84] for mammals using Mesquite v. 2.75 [80]. Additional information on node divergence times was taken from Benton et al [85] and Müller and Reisz [86].…”

Section: Methodsmentioning

confidence: 99%

Preliminary Analysis of Osteocyte Lacunar Density in Long Bones of Tetrapods: All Measures Are Bigger in Sauropod Dinosaurs

Stein

Werner

2013

PLoS ONE

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Osteocytes harbour much potential for paleobiological studies. Synchrotron radiation and spectroscopic analyses are providing fascinating data on osteocyte density, size and orientation in fossil taxa. However, such studies may be costly and time consuming. Here we describe an uncomplicated and inexpensive method to measure osteocyte lacunar densities in bone thin sections. We report on cell lacunar densities in the long bones of various extant and extinct tetrapods, with a focus on sauropodomorph dinosaurs, and how lacunar densities can help us understand bone formation rates in the iconic sauropod dinosaurs. Ordinary least square and phylogenetic generalized least square regressions suggest that sauropodomorphs have lacunar densities higher than scaled up or comparably sized mammals. We also found normal mammalian-like osteocyte densities for the extinct bovid Myotragus, questioning its crocodilian-like physiology. When accounting for body mass effects and phylogeny, growth rates are a main factor determining the density of the lacunocanalicular network. However, functional aspects most likely play an important role as well. Observed differences in cell strategies between mammals and dinosaurs likely illustrate the convergent nature of fast growing bone tissues in these groups.

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Section: Methodsmentioning

confidence: 99%

Preliminary Analysis of Osteocyte Lacunar Density in Long Bones of Tetrapods: All Measures Are Bigger in Sauropod Dinosaurs

Stein

Werner

2013

PLoS ONE

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“…Dissorophoidea is a large clade that was very successful during the Paleozoic and continues to be so today, as most authors consider some or all three groups of modern amphibians to be part of Dissorophoidea (Anderson, 2008;Anderson et al, 2008b;Milner, 1988Milner, , 1993Schoch and Milner, 2004;Sigurdsen and Green, 2011), but see, for example, Marjanović and Laurin (2013) for a different view. Recent phylogenetic analyses have recovered two distinct subclades within fossil dissorophoids, one comprising the Olsoniformes (dissorophids and trematopids) and one comprising the Xerodromes (amphibamids and branchiosaurids) (Anderson et al, 2008b;Fröbisch and Schoch, 2009;Schoch, 2012;Schoch and Milner, 2014).…”

Section: Introductionmentioning

confidence: 99%

New specimen of <i>Cacops woehri</i> indicates differences in the ontogenetic trajectories among cacopine dissorophids

2015

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Abstract. The Lower Permian Dolese locality has produced numerous exquisitely preserved tetrapod fossils representing members of a lower Permian upland fauna. Therein, at least nine taxa of the clade Dissorophoidea, ranging in size from the large predaceous trematopid Acheloma to the miniaturized amphibamid Doleserpeton, highlight the great taxic and ecological diversity of this anamniote clade. Here we describe a large specimen of the dissorophid Cacops woehri, which was previously only known from the juvenile or subadult holotype skull. Another member of the genus Cacops present at the Dolese locality, Cacops morrisi, is also represented by specimens spanning juvenile, subadult, and adult stages, allowing for a comparison of morphological changes taking place in the late phases of the ontogenetic trajectory of cacopine dissorophids. The new find shows that, in contrast to C. morrisi and C. aspidephorus, C. woehri only undergoes relatively subtle changes in skull morphology in late ontogeny and retains the overall more gracile morphology into adult stages. This includes retention of the rather shallow skull shape as well as a pattern of sculpturing consisting of elongate ridges and grooves and a large occipital flange. This suggests somewhat different functional demands in C. woehri than in other known species of Cacops, possibly associated with a different ecology paralleling the great taxic diversity of dissorophoids at the Dolese locality.

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“…). Whereas the analyses of Laurin & Reisz (), Vallin & Laurin (), Marjanović & Laurin () and Marjanović & Laurin () found lepospondyls (and thus microsaurs) to be stem‐amphibians, the present authors agree with Ruta, Coates & Quicke (), Ruta & Coates (), Sigurdsen & Green (), and Schoch () who regard lepospondyls as stem‐amniotes and lissamphibians as derived from temnospondyls, another large group of early non‐amniotic tetrapods.…”

Section: Resultsmentioning

confidence: 99%

Tail regeneration in the Paleozoic tetrapod Microbrachis pelikani and comparison with extant salamanders and squamates

2017

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Among extant tetrapods, salamanders are the only group capable of full limb and tail regeneration, the latter including the re-establishment of a fully functional tail with the axial skeleton and associated musculature. Tail regeneration is associated with autotomy (self-amputation) in some salamander taxa but is also possible in salamander taxa that lack tail autotomy. Modern squamates also frequently show tail autotomy as a defense or decoy mechanisms against predation, but contrary with salamanders, the tail skeleton is replaced by a cartilaginous rod in the regenerate and the associated musculature is rather unusual. Here, we describe details of the tail regeneration in a fossil early tetrapod, the microsaurian lepospondyl Microbrachis pelikani in comparison to two salamander species, Desmognathus monticola and D. ocoee. Two specimens of Microbrachis represent an early and a later stage of tail regeneration and clearly show that this microsaur was capable of salamander-like tail regeneration. The differentiation of the axial skeleton proceeds in a similar way to modern salamanders from proximal to distal and in a reversed order relative to development, i.e. with an early establishment of the vertebral centra, followed by the neural arches. Moreover, the morphological analysis suggests that Microbrachis autotomized its tails along an intravertebral autotomization plane, which is similar to modern squamates but differs from intervertebral tail autotomy seen in salamanders. The findings highlight that patterns of tail autotomy evolved independently from the overall capacity to regenerate the tail and the capacity to re-establish the axial skeleton. The phylogenetic distribution of salamander-like tail regeneration suggests that this may represent an ancient feature of sarcopterygians, which is in line with recent data on the evolution of full limb regeneration in tetrapods.

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The origin(s) of extant amphibians: a review with emphasis on the “lepospondyl hypothesis”

Cited by 84 publications

References 140 publications

Preliminary Analysis of Osteocyte Lacunar Density in Long Bones of Tetrapods: All Measures Are Bigger in Sauropod Dinosaurs

Preliminary Analysis of Osteocyte Lacunar Density in Long Bones of Tetrapods: All Measures Are Bigger in Sauropod Dinosaurs

New specimen of <i>Cacops woehri</i> indicates differences in the ontogenetic trajectories among cacopine dissorophids

Tail regeneration in the Paleozoic tetrapod Microbrachis pelikani and comparison with extant salamanders and squamates

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The origin(s) of extant amphibians: a review with emphasis on the “lepospondyl hypothesis”

Cited by 84 publications

References 140 publications

Preliminary Analysis of Osteocyte Lacunar Density in Long Bones of Tetrapods: All Measures Are Bigger in Sauropod Dinosaurs

Preliminary Analysis of Osteocyte Lacunar Density in Long Bones of Tetrapods: All Measures Are Bigger in Sauropod Dinosaurs

New specimen of &lt;i&gt;Cacops woehri&lt;/i&gt; indicates differences in the ontogenetic trajectories among cacopine dissorophids

Tail regeneration in the Paleozoic tetrapod Microbrachis pelikani and comparison with extant salamanders and squamates

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New specimen of <i>Cacops woehri</i> indicates differences in the ontogenetic trajectories among cacopine dissorophids