Browsing by Subject "bearded dragon"
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(2020)Reptiles have long been studied in search of the mechanisms behind neuronal regeneration. This thesis delves into the regenerative areas of two emerging model species to the field of regenerative research: Pogona vitticeps (bearded dragon) and Pantherophis guttatus (corn snake). This fluorescent immunohistochemical study maps out and compares the constitutive proliferative zones in these two species to better define the focus of future comparative neurodegenerative experiments. A BrdU pulse chase experiment in conjunction with PCNA reveals proliferative zones in the lateral ventricular ependyma of both species. Stem cell niches were found in the ependymal lining adjacent to the medial cortex and dorsal ventricular ridge in both species, however, the nucleus sphericus ependyma was an active proliferative zone only in Pantherophis. Imaging of further markers in this study support the findings of the pulse chase experiment. High levels of the stem cell marker Sox2 was found in lateral ventricular ependymal cells in both species. The glial marker GFAP reveals a highly ordered array of radial glia in the cortical areas of Pogona, which is significantly reduced or absent in Pantherophis. And lastly the neuronal marker HU was found in the same cells that were BrdU positive and had migrated a short distance from the proliferative zones, which shows that the proliferative areas in the lateral ventricular lining do indeed produce neurons. The BrdU and PCNA marked cells were quantified in both species, and a brief comparison between the species showed that Pogona had a significantly higher number and concentration of proliferative cells in the proliferative zones than Pantherophis. Scattered BrdU positive cells that were neither neuronal nor positive for any other marker were also found scattered throughout the parenchyma of Pogona, and these cells remain uncharacterized. Differences between these two species are not surprising, as lizards are known to have better regenerative capabilities than snakes, however, more comparative research between these species is needed to gain further insight into the mechanisms behind their contrasting regenerative capabilities.
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(2020)The skull represents the most highly diversified and evolutionarily adapted anatomical aspect of metazoans, and its development and evolution have been a major driving force in the expansion of vertebrates. The evolution of skull and lower jaw bones have led to the adaptive radiation of jawed vertebrates, and skull tissues have changed rapidly over time and were finely tuned to meet functional and ecological demands with tremendous precision. Because of the long-lasting interest in conventional animal models, there is no general genetic or developmental model of skull evolution and diversity in vertebrates. Squamate reptiles represent the best model to study those aspects because of their key basal phylogenetic position within amniotes (i.e., mammals, birds, reptiles) and their exceptionally high levels of morphological variation (including their kinetic skulls). In particular, their lower jaw bones display tremendous variation. In order to assess this variation and the ecological and developmental factors connected to it, several methods from different fields of biology have to be used. In this study, morphometric, embryology and developmental approaches are used to investigate the ecological and developmental factors associated with the diversification of lower jaw bones in snakes and lizards. The shape diversity of squamate lower jaw bones was approached in a systematic way, using geometric morphometrics. Embryological methods were used to compare the embryonic stage of available squamate model animals at oviposition and to assess the order of ossification of embryo with earliest developmental stage at oviposition (bearded dragon, Pogona vitticeps). In addition, expression of major conserved candidate genes at different stages of lower jaw development (pharyngeal arches, mesenchyme patterning, ossification) were assessed in this species. The results indicate that the lower jaw bones of snakes versus lizards but also of fossorial squamates versus other habitats are significantly different. Heterochrony was also detected at both early stages (pharyngeal arche development at oviposition) and at the onset of ossification in lizards and snakes. Coherent with that, alterations in the expression pattern of Dlx genes in pharyngeal arches were observed in bearded dragon in comparison to earlier studies with mice, while other conserved markers of skeletogenesis were rather conserved. This analysis of the genotype and phenotype map of the reptilian skull provides some new insights into the development, origin and divergence of vertebrate tissues. The results will establish a good basis for future studies involving comparative developmental biology of bearded dragon. Future studies will offer excellent new opportunities to link craniofacial morphology, genetics/genomics and development to both ecological adaptation and evolutionary biology.
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