Browsing by Subject "Turtle"
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Item Open Access A Systems Level Analysis of Temperature-Dependent Sex Determination in the Red-Eared Slider Turtle Trachemys Scripta Elegans.(2016) Czerwinski, Michael JamesSex determination is a critical biological process for all sexually reproducing animals. Despite its significance, evolution has provided a vast array of mechanisms by which sexual phenotype is determined and elaborated even within amniote vertebrates. The most prevalent systems of sex determination in this clade are genetic and temperature dependent sex determination. These two systems are sometimes consistent within large groups of species, such as the mammals who nearly ubiquitously utilize XY genetic sex determination, or they can be much more mixed as in reptiles that use genetic or temperature dependent systems and even both simultaneously. The turtles are a particularly diverse group in the way they determine sex with multiple different genetic and temperature based systems having been described. We investigated the nature of the temperature based sex determination system in Trachemys scripta elegans to ascertain whether it behaved as a purely temperature based system or if some other global source of sex determining information might be apparent within thermal regions insufficient to fully induce male or female development. These experiments found that sex determination in this species is much more complex and early acting than previously thought and that each gonad within an individual has the same sexual fate established enough that it can persist even without further communication between. We established a best practice for the assembly and annotation of de novo whole transcriptomes from T. scripta RNA-seq and utilized the technique to quantify the gene regulatory events that occur across the thermal sensitive period.
Evidence is entirely lacking on the resolution of TSD when eggs are incubated at the pivitol temperature in which equal numbers or males and females are produces. We have produced a timecourse data set that allowed for the elucidation of the gene expression events that occur at both the MPT and FPT over the course of the thermal sensitive period. Our data suggests that early establishment of a male or female fate is possible when temperature is sufficiently strong enough as at MPT and FPT. We see a strong pattern of mutually antagonistic gene expression patterns emerging early and expanding over time through the end of the period of gonad plasticity. In addition, we have identified a strong pattern of differential expression in the early embryo at stages prior to the formation of the gonad. Even without the known systemic signaling attributed to sex hormones emanating from the gonad, the early embryo has a clear male and female gene expression pattern. We discuss how this early potential masculinization or feminization of the embryo may indicate that the influence of temperature may extend beyond the determination of gonadal sex or even metabolic adjustments and how this challenges the well-defined paradigm in which gonadal sex determines peripheral sexual characteristics.
Item Open Access The Effect of Stream Restoration on Turtle Species Assemblages in the Piedmont Region of North Carolina, USA(2010-04-30T18:48:42Z) Nowalk, MauraIn response to the negative impact of urban and agricultural development on freshwater systems, stream restoration efforts often attempt to return degraded streams to a natural ecosystem structure and function. However, few attempts have been made to monitor the effectiveness of restored streams in supporting certain important groups of organisms found in native aquatic ecosystems, such as freshwater turtles. The purpose of this study was to compare six natural and six restored streams in the North Carolina Piedmont by quantifying habitat characteristics that might drive differences in turtle assemblages and by directly capturing turtles at each site. Stream habitat was characterized by water quality analyses, structural measurements of each stream, and floodplain vegetation surveys. Three baited hoop nets were set at each location for a total of 36 trap-nights at each stream, which were used to collect turtle population data from mid-May to late July 2009. In total 77 turtles were captured comprising eight species. At the natural sites, 24 turtles were captured representing five species (C. picta, C. serpentina, P. floridana, S. odoratus, and T. scripta scripta); 53 turtles were captured at the restored sites representing seven species (C. guttata, C. picta, C. serpentina, K. subrubrum, S. odoratus, T. scripta elegans and T. scripta scripta). Modified t-tests, based on randomized permutation tests, suggest that natural and restored sites differ in turtle abundance (p=0.13), but are not different in species richness (p>0.99) or gender ratios (p=0.80). A species community index suggests that natural and restored turtle assemblages overlap by 50%. Non-metric multidimensional scaling analyses of habitat characteristics indicate that natural and restored streams differ in channel structure, vegetation, and some water quality variables. Using Mantel’s test to compare turtle species composition with the most important variables separating natural and restored streams, canopy, slope, total phosphorus, chlorophyll A, and Juncus effuses abundance were found to be most strongly correlated with patterns in turtle assemblage composition. This is one of the first studies to address the possible impact of stream restoration on turtle assemblages, and the findings suggest that restored streams may be better habitat for turtles in the North Carolina Piedmont.Item Open Access The Role of Neural Crest Cells in Vertebrate Cardiac Outflow Development(2014) Alonzo-Johnsen, MarthaThroughout vertebrate evolution, the cardiac outflow vasculature has changed from a branchial arch system to a systemic and pulmonary circulatory system. However, all vertebrate hearts and outflow tracts still develop from a single heart tube. In the chick and mouse, cardiac neural crest cells divide the single outflow tract into the aorta and pulmonary arteries. Additionally, cardiac neural crest cells provide the smooth muscle of the aortic arch arteries, help to remodel the aortic arch arteries into asymmetrical structures, and contribute cardiac ganglia. I review the major contributions of cardiac neural crest cells to the outflow vasculature of the chick and mouse and apply this information to study cardiac neural crest cell contributions to vertebrates that lack a divided circulatory system. I re-evaluate the role of cardiac neural crest cells in zebrafish vasculature and find that these cells do contribute to the gill arch arteries, the ventral aorta and cardiac ganglia, but they do not contribute to myocardium. I also study the outflow tract development of the turtle Trachemys scripta to understand the process of outflow septation in a vertebrate that has a divided outflow tract but an incomplete division of the ventricle. I compare the chick outflow tract to the turtle. The formation of the proximal versus distal cushions and the appearance of smooth muscle cells within the distal cushions of the turtle are very similar to the cushion position and cell types within the cushions of the chick. In the chick, the smooth muscle positive cells in the distal cushions are derived from cardiac neural crest cells. I hypothesize that cardiac neural crest cells are also responsible for the outflow tract septation of reptiles. These results demonstrate that the pattern of cardiac neural crest cell contribution to vertebrate vasculature remains predictable and consistent, enabling future studies to focus on changes in vascular patterning caused by cardiac neural crest cells among different vertebrate lineages.