The red-eared slider turtle (Trachemys scripta) possesses temperature-dependent sex determination (TSD) in which the incubation temperature determines gonadal sex. Although a number of mammalian gene homologues have been identified in reptiles with TSD, the exact sex-determining trigger(s) is not known. To date, the current study represents the most comprehensive simultaneous evaluation of the chronology of mRNA expression profiles of putative sex-determining/differentiation genes (Dmrt1, Sox9, Amh, Lhx9, and Foxl2) from gonads incubated at male- and female-producing temperatures in T. scripta. Additionally, sex-reversing treatments with 17β-estradiol and letrozole were examined. At a male-producing temperature, Dmrt1 expression was sexually dimorphic by stage 17, Sox9 by 19 and Amh by 21. In contrast, Foxl2 did not significantly increase until after the thermosensitive period at a female-producing temperature. Treatment with 17β-estradiol resulted in reduced gonad size and/or inhibited gonadal development and differentiation. Gene expression was subsequently low in this group. Sex reversal utilizing letrozole failed to produce testes at a female-producing temperature and as such, gene expression was comparable to ovary. These results indicate that Dmrt1 and Sox9 are potential triggers for testis differentiation and Amh, Lhx9 and Foxl2 represent a conserved core set of genes in the sex-determining/differentiation pathway of TSD species.
Many reptiles, including the red-eared slider turtle (Trachemys scripta), possess a temperature-dependent sex determination (TSD) mechanism where the temperature at which the developing embryos are incubated dictates the gonadal sex of the animal. A number of mammalian gene orthologues have been identified in the sex determination/differentiation cascade of reptiles with TSD although the exact trigger(s) is not well understood. A potential early regulator of gonadal differentiation, Lhx9, controls the proliferation of gonadal cells in mice and its absence prevents gonadal development and drastically reduces the expression of Sf-1, a gene that regulates the expression of steroidogenic enzymes in the bipotential gonad. In the current study, we cloned Lhx9 from T. scripta and analyzed its expression throughout the thermosensitive period of gonad development using quantitative PCR. We examined the expression profiles of Lhx9 in embryos incubated under control conditions at male- and female-producing temperatures and with the application of exogenous 17β-estradiol or an aromatase inhibitor, Letrozole, to induce sex reversal. The T. scripta Lhx9 cDNA and predicted amino acid sequence showed high homology to those of chicken, anole, and mouse. Lhx9 was expressed at both male- and female-producing temperatures with expression levels increasing throughout the thermosensitive period. Letrozole induced sex-reversal did not alter Lhx9 expression levels. 17β-estradiol treatments appeared to inhibit or delay gonadal differentiation and resulted in lower Lhx9 expression from the presumptive gonadal ridge region. The structural homology and temporal expression pattern of Lhx9 suggests that this represents a conserved element in the gonadal differentiation cascade of T. scripta.
Genetic screens are used in Drosophila melanogaster to identify genes key in the regulation of organismal development and growth. These screens have defined signalling pathways necessary for tissue and organismal development, which are evolutionarily conserved across species, including Drosophila . Here, we have used an FLP/FRT mosaic system to screen for conditional regulators of cell growth and cell division in the Drosophila eye. The conditional nature of this screen utilizes a block in the apoptotic pathway to prohibit the mosaic mutant cells from dying via apoptosis. From this screen, we identified two different mutants that mapped to the Hedgehog signalling pathway. Previously, we described a novel Ptc mutation and here we add to the understanding of disrupting the Hh pathway with a novel allele of Cos2 . Both of these Hh components are negative regulators of the pathway, yet they depict mutant differences in the type of overgrowth created. Ptc mutations lead to overgrowth consisting of almost entirely wild-type tissue (non-autonomous overgrowth), while the Cos2 mutation results in tissue that is overgrown in both the mutant and wild-type clones (both autonomous and non-autonomous). These differences in tissue overgrowth are consistent in the Drosophila eye and wing. The observed difference is correlated with different deregulation patterns of pMad, the downstream effector of DPP signalling. This finding provides insight into pathway-specific differences that help to better understand intricacies of developmental processes and human diseases that result from deregulated Hedgehog signalling, such as basal cell carcinoma.
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