TRANSCRIPTIONAL AND MORPHOLOGICAL CHANGES DURING THYROXINE-INDUCED METAMORPHOSIS OF THE MEXICAN AXOLOTL AND AXOLOTL-TIGER SALAMANDER HYBRIDS

Page, Robert Bryce

01 January 2009

For nearly a century, amphibian metamorphosis has served as an important model of how thyroid hormones regulate vertebrate development. Consequently metamorphosis has been studied in a number of ways including: morphologically, developmentally, ecologically, and from an endocrine perspective. Over the last two decades, much has been learned about the molecular basis of anuran (frog) metamorphosis. However, very little is known about the molecular underpinnings of urodele (salamander) metamorphosis. Using the axolotl and axolotl hybrids as models, I present some of the first studies on the gene expression changes that occur during urodele metamorphosis. In Chapter 1, the motivation for the research described in the subsequent chapters is presented and the literature is briefly reviewed. In Chapter 2, the first microarray analysis of urodele metamorphosis is presented. This analysis shows that hundreds of genes are differentially expressed during thyroid hormone-induced metamorphic skin remodeling. Chapter 3 extends the analysis presented in Chapter 2 by showing that the transcriptional patterns associated with metamorphic skin remodeling are robust even when the concentration of thyroid hormone used to induce metamorphosis is varied by an order of magnitude. Chapter 4 makes use of the differentially expressed genes identified in Chapters 2 and 3 to articulate the first model of urodele metamorphosis to integrate changes in morphology, gene expression, and histology. In addition, Chapter 4 outlines a novel application for piecewise linear regression. In turn, Chapter 5 makes use of the model presented in Chapter 4 to demonstrate that full siblings segregating profound variation in metamorphic timing begin to diverge in phenotype early during larval development. In Chapter 6 the conclusions drawn from the research are summarized and future directions are suggested.

Biology

BERYLLIUM NITRATE SUPPORTS FIBROBLAST MIGRATION AS AN ESSENTIAL COMPONENT OF SKIN AND LIMB REGENERATION IN AXOLOTLS

Cook, Adam Boyd

01 January 2015

Tissue regeneration in salamanders is a robust process that is not easily interrupted or altered. Therefore, inhibiting regeneration provides a means to interrogate the underlying cellular and molecular mechanisms regulating this complex event. Here we show that application of a relatively low concentration of beryllium nitrate solution (100mM) causes a delay in skin regeneration and severely alters normal limb regeneration. We provide evidence showing a beryllium-induced reduction in dermal fibroblast migration in vivo and in vitro. We link this phenomenon to delayed regeneration of the skin and abnormal blastema formation resulting in limb patterning defects during regeneration. Though our results show a slight reduction in fibroblast proliferation during the early stages of limb regeneration, we attribute this to an overall reduction in fibroblast presence at the site of injury. Keratinocytes appeared unresponsive to beryllium treatment with the rates of re-epithelialization and proliferation not significantly different between treatment and control groups. Taken together, these data reinforce a necessary role for fibroblasts during tissue regeneration and show that beryllium nitrate inhibits normal fibroblast behavior.

Beryllium Nitrate

Fibroblast Migration

Mexican Axolotl

Regeneration

Histology

Developmental Biology

Molecular Biology

Structural Biology

Ontogenetický původ chrupavčitých elementů lebky axolotla / Developmental origin of cartilage skull elements in axolotl

Kloučková, Lenka

January 2011

Despite the fact that some aspects of single studies differ, there's a generally accepted view that the whole cartilaginous viscerocranium of vertebrates is neural crest derived. By the series of isotopic transplantation experiments of presumptive neural crest on the model organism Ambystoma mexicanum I partly specify this oppinion and prove that the most ventro-caudal cartilage, the second basibranchial, is of a different origin. Furher I mention the level of the presumptive neural crest where the single parts of cartilaginous viscerocranium arise from. Moreover there is one element, the first basibranchial, which has double origin. I discuss also some other neural crest derivatives such as head and outer gills mesenchyme, the trabeculae cranii, part of the cartilaginous otic capsule or the connective tissue in the head. I have performed 179 transplantations between transgenic and normal axolotl embryos. My final analysis is composed of 65 embryos of stage 40 - 42 and 7 larvae of lenght of 15 - 17 mm.