Browsing by Subject "regeneration"
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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 axolotl (Ambystoma mexicanum) has an astounding ability to regenerate entire lost body parts throughout its life. Significant progress has been made in recent years to understand the mechanisms of axolotl regeneration, but how the animal maintains its capacity for successful regeneration remains obscure. In mammals, the ability to repair damaged tissue drastically declines with age, in part due to the accumulation of senescent cells. However, in axolotls, the number of senescent cells does not increase upon aging. Low levels of chronic senescence in axolotls have been proposed to support their ability to regenerate even at an old age. Axolotls can efficiently clear senescent cells, but whether they can prevent the induction of senescence is not known. This thesis provides the first indication of a secreted anti-senescence activity from axolotl cells. Data presented here show that conditioned medium from cultured axolotl cells reduces senescence and increases proliferation in mouse embryonic fibroblast, a widely used model for spontaneous senescence. Remarkably, conditioned media from other tested cell types, namely cervical cancer cells and young mouse embryonic fibroblasts, did not considerably affect senescence, despite extensively increasing proliferation. Taken together, secreted factors from cultured axolotl cells seem to reduce senescence directly, and not by merely promoting proliferation. This observation forms a basis for future endeavors to determine whether preventing senescence facilitates regeneration in vivo.
Now showing items 1-2 of 2