‘Monster… -omics’: on segmentation, re-segmentation, and vertebrae formation in amphibians and other vertebrates

Buckley, David; Molnár, Viktor; Németh, Gábor; Petneházy, Örs; Vörös, Judit

doi:10.1186/1742-9994-10-17

Cited by 15 publications

(15 citation statements)

References 43 publications

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“…In all other amphibians that have been studied, the sclerotome is relatively small, which makes it difficult to observe the migration of sclerotome cells and to detect direct evidence for resegmentation (Wake, ; Wake and Lawson, ; Shishkin, ). Furthermore, formation of the vertebral column within amphibians appears to be a diverse process with variable patterns (Wake and Wake, ; Buckley et al, ) and even within salamanders, differences in the sclerotome (e.g., presence or absence of primary segmentation) have been observed that might affect vertebral column formation (Wake and Lawson, ; Buckley et al, ). If, and how, these differences affect the process of resegmentation is unknown.…”

Section: Discussionmentioning

confidence: 99%

“…Previous morphological analysis based on histological sections yield indirect support for resegmentation in salamanders and frogs based on the observation that the vertebral centra develop in an intersegmental position (Mookerjee, 1930(Mookerjee, , 1931Wake, 1970;Wake and Lawson, 1973). However, whether resegmentation occurs in amphibians has remained an unsolved question, because the intersegmental position of a vertebra developing between two adjacent somites does not necessarily explain the migratory routes of sclerotomal cells from the somites, and it is possible that sclerotome cells from one somite form one vertebra without resegmentation (Wake, 1970;Verbout, 1976Verbout, , 1985Shishkin, 1989;Keller, 1999;Wake and Wake, 2000;Buckley et al, 2013). Furthermore, the scanty sclerotome in these groups of amphibians makes it more challenging to find conclusive evidence for or against resegmentation (Wake and Lawson, 1973;Wake and Wake, 2000).…”

Section: Introductionmentioning

confidence: 99%

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Resegmentation in the mexican axolotl, Ambystoma mexicanum

Piekarski

Olsson

2013

Journal of Morphology

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The segmental series of somites in the vertebrate embryo gives rise to the axial skeleton. In amniote models, single vertebrae are derived from the sclerotome of two adjacent somites. This process, known as resegmentation, is well-studied using the quail-chick chimeric system, but the presumed generality of resegmentation across vertebrates remains poorly evaluated. Resegmentation has been questioned in anamniotes, given that the sclerotome is much smaller and lacks obvious differentiation between cranial and caudal portions. Here, we provide the first experimental evidence that resegmentation does occur in a species of amphibian. Fate mapping of individual somites in the Mexican axolotl (Ambystoma mexicanum) revealed that individual vertebrae receive cells from two adjacent somites as in the chicken. These findings suggest that large size and segmentation of the sclerotome into distinct cranial and caudal portions are not requirements for resegmentation. Our results, in addition to those for zebrafish, indicate that resegmentation is a general process in building the vertebral column in vertebrates, although it may be achieved in different ways in different groups.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Resegmentation in the mexican axolotl, Ambystoma mexicanum

Piekarski

Olsson

2013

Journal of Morphology

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“…Fusion of vertebrae in the fossil record and in modern embryology is not uncommon. The nature of fusion can be diverse, resulting from trauma, disease, or congenital malformation (Hanna, ; Buckeley et al ., ; Farke et al ., ; Xing et al ., ). While records of trauma and disease are well documented (Rothschild & Tanke, ; Molnar, ; Tanke & Rothschild, ; Rothschild, ), congenital vertebral pathologies are rarely reported from the fossil record.…”

Section: Discussionmentioning

confidence: 99%

“…Congenital vertebral fusion can be classified as a defect of neural tube closure, a defect of formation, or a defect of segmentation (Kaplan et al, 2005). The presence of multiple fully formed neural spines, transverse processes, and ribs in NHCC LB337 suggests sclerotomal cell precursors were present and properly regionalized after somitogenesis and primary segmentation (Chandraraj, 1987;Buckeley et al, 2013). This, along with no apparent failure of midline fusion, suggests the neural tube closed normally at the level of these vertebrae.…”

Section: Nhcc Lb337mentioning

confidence: 99%

“…While the early evolution of vertebral structure in basal (anamniote) vertebrates is still an active area of research (Zhang, 2009;Buckeley et al, 2013;Pierce et al, 2013), the processes of development are highly conserved in amniotes (Pourquie & Kusumi, 2001;Fleming et al, 2003Fleming et al, , 2015Christ et al, 2007). The pathology in NHCC LB337 represents the oldest occurrence of congenital block vertebra in the sacral vertebrae of a reptile.…”

Section: Nhcc Lb337mentioning

confidence: 99%

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Pathology in a Permian parareptile: congenital malformation of sacral vertebrae

Turner

Sidor

2017

Journal of Zoology

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Pareiasaurs were a group of herbivorous reptiles that lived during the middle to late . About 20 species are currently recognized from a fossil record spanning Europe, Asia, South America, and Africa. All pareiasaurs have a peculiar vertebral anatomy characterized by 'swollen' neural arches. Some species grew to large body size (e.g., 600 kg) and evolved up to five sacral vertebrae, but the detailed anatomy of the sacral region is poorly documented. Vertebral elements referable to the derived pareiasaur subclade Velosauria were recently recovered from the upper Madumabisa Mudstone Formation (Luangwa Basin) of Zambia and are described here. The specimen exhibits an abnormal morphology: the neural arches of the second, third, and fourth sacral vertebrae share a single, elongate centrum that is fused anteriorly with a 'normal' first sacral vertebra, and articulates posteriorly with a slightly disarticulated first caudal vertebra. We suggest two distinct pathologies are responsible for this morphology: (1) spondyloarthropathy (re-ossified intervertebral joint) and (2) congenital block vertebra. The processes of development of neural arches and centra, while evolutionarily independent in origin, have been found to be conserved in all amniotes. While paleopathological morphologies can provide insight into environmental and disease-based etiologies, pathological congenital malformations are particularly rare in fossil record and have the potential to be informative for understanding the evolution of vertebral development. The anatomy described here sheds light on pareiasaurian sacral morphology and provides insight into the pathology in one of the earliest clades of large-bodied reptiles near the base of the amniote tree.

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Repeated ecological and life cycle transitions make salamanders an ideal model for evolution and development

Bonett

Ledbetter

Hess

et al. 2021

Developmental Dynamics

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Observations on the ontogeny and diversity of salamanders provided some of the earliest evidence that shifts in developmental trajectories have made a substantial contribution to the evolution of animal forms. Since the dawn of evo-devo there have been major advances in understanding developmental mechanisms, phylogenetic relationships, evolutionary models, and an appreciation for the impact of ecology on patterns of development (eco-evo-devo). Molecular phylogenetic analyses have converged on strong support for the majority of branches in the Salamander Tree of Life, which includes 764 described species. Ancestral reconstructions reveal repeated transitions between life cycle modes and ecologies. The salamander fossil record is scant, but key Mesozoic species support the antiquity of life cycle transitions in some families. Colonization of diverse habitats has promoted phenotypic diversification and sometimes convergence when similar environments have been independently invaded. However, unrelated lineages may follow different developmental pathways to arrive at convergent phenotypes. This article summarizes ecological and endocrine based causes of life cycle transitions in salamanders, as well as consequences to body size, genome size, and skeletal structure. Salamanders offer a rich source of comparisons for understanding how the evolution of developmental patterns has led to phenotypic diversification following shifts to new adaptive zones.

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‘Monster… -omics’: on segmentation, re-segmentation, and vertebrae formation in amphibians and other vertebrates

Cited by 15 publications

References 43 publications

Resegmentation in the mexican axolotl, Ambystoma mexicanum

Resegmentation in the mexican axolotl, Ambystoma mexicanum

Pathology in a Permian parareptile: congenital malformation of sacral vertebrae

Repeated ecological and life cycle transitions make salamanders an ideal model for evolution and development

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