Browsing by Subject "Embryo"
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Item Open Access Cell Lineage Specification during Mouse Embryonic Gonad Development(2017) Lin, Yi-TzuThe mouse embryonic gonad provides an outstanding model to study the complex mechanisms involved in cell fate specification and maintenance. At the bipotential stage, both XX and XY gonads are capable of becoming testes or ovaries upon specific molecular cues. The specification of the supporting cell lineage (as either Sertoli cells in the male or granulosa cells in the female) initiates the testis or ovary program, leading to male or female fate. However, there are significant gaps in our understanding of how the somatic cells in the gonad arise, are competent to differentiate, and determine and maintain their fates. In this dissertation, we addressed these questions.
We found that NUMB (an antagonist of Notch signaling) serves as competence factor for somatic cell differentiation during early gonadogenesis. The asymmetric allocation of NUMB to the basolateral domain of actively dividing coelomic epithelial (CE) cells is indispensable to (1) maintain the totipotent stem cell-like reservoir at the CE domain, and (2) give rise to progenitor cells that can further differentiate into supporting and interstitial cell lineages. Deletion of Numb; Numbl resulted in disruption of cell polarity in the CE domain as well as a reduction of multiple differentiated cell lineages within XX and XY gonads, including supporting cells and male steroidogenic cells, which were most severely affected. We detected elevated Notch downstream signaling in the Numb; Numbl mutant gonads. Moreover, treatment of DAPT (which blocks Notch signaling) rescued the Numb; Numbl mutant phenotypes, strongly suggesting that upregulation of Notch is responsible.
Previous experiments indicate that when supporting cells commit to the male (Sertoli) fate, they must repress the alternative female (granulosa) cell fate. In another line of experiments, we investigated the hypothesis that the Polycomb repressive complex (PRC1) plays a critical role in repressing the female pathway during male gonad patterning. We found that loss of Ring1B (a component of PRC1) led to the disruption of XY gonad development specific to the posterior region of male gonads. Sry, the upstream driver of the male pathway, was not appropriately expressed in the posterior domain, which contained cells expressing female markers and, in some cases, small aggregates of undifferentiated cells. Using ChIP-Seq, we identified potential targets of PRC during male gonad development. Moreover, a key gene in the male pathway, SOX9, interacts with Ring1B, based on immunoprecipitation results, leading to the hypothesis that it may be involved in the recruitment of PRC to its target sites to execute the repression of female genes in male gonads.
Our findings provide insight into how somatic cell fate is determined and maintained during mammalian sex determination. Our results may be valuable for patients with disorders of sexual development with unidentified genetic contributions.
Item Open Access Hedgehog Signaling in Anterior Development of the Mammalian Embryo(2013) Davenport, ChandraSonic hedgehog (Shh) is a critical secreted signaling molecule that regulates many aspects of organogenesis. In the absence of Shh, many organs, including the foregut, larynx, palate, cerebellum and heart do not form properly. However, the cellular details of the roles of Shh, including the relevant domains of Shh expression and reception, have not been elucidated for many of these processes.
The single embryonic foregut tube must divide into the trachea and esophagus, which does not occur in the Shh-null mutant. In Chapter 5, I use Cre-Lox technology to determine that the ventral foregut endoderm is the relevant source of Shh for this process and the mesoderm must directly receive that Shh signal. Surprisingly, this signaling event appears to occur two days before the foregut begins to divide, indicating an early essential role for Shh in foregut division.
Shh is also expressed at later stages in the maturing trachea and esophagus. In Chapter 6, I demonstrate that these domains serve to establish differentiated mesoderm. In the trachea, Shh from the endoderm signals directly to the mesoderm to form the tracheal cartilage rings. In the esophagus, the roles of Shh are more complex. Shh regulates the size of the esophagus and controls patterning of the concentric rings of esophageal mesoderm, however this process seems to be indirect, requiring autocrine Shh signaling within the esophageal endoderm.
The laryngeal apparatus is entirely absent in the Shh-null mouse. I n Chapter 3, I dissect the domains of Shh expression and reception required for laryngeal development and demonstrate that loss of endodermal Shh expression causes laryngotracheoesophageal clefts and malformed laryngeal cartilages. As much of laryngeal morphogenesis poorly understood, I also utilize dual mesodermal and neural crest fate maps to determine the embryonic origins of various laryngeal tissues. Finally, as Shh signaling often occurs in concert with Bone Morphogenic Protein (BMP) signaling, I investigate the roles of BMP signaling in laryngeal development.
Much of Shh signaling occurs at the primary cilium, to which Smoothened, a critical pathway member, must translocate upon Shh signal transduction. This process requires a Smo-Kif3a-βarretin complex in mammalian cell culture. However, the roles of βarrestins in mouse development, and their relationship to Shh signaling have not been investigated in vivo. To do so, in Chapter 4, I analyze the phenotypes of the βarr1/βarr2 double knockout embryos and demonstrate that they have palatal, cerebellar, cardiovascular and renal defects consistent with a specific impairment of mitogenic Shh signaling.
Altogether, my work dissects the cellular details of Shh signaling during multiple organ systems in the mouse embryo. I further analyze the consequences of absent or misregulated Shh signaling across multiple developmental contexts and determine that Shh plays critical and diverse roles in organogenesis.
Item Open Access Identification of Transforming Growth Factor-beta as an Extracellular Signal Required for Axon Specification in Embryonic Brain Development(2009) Yi, Jason Joon-moThe specification of a single axon and multiple dendrites is the first observable event during neuronal morphogenesis and such structural specialization underlies neural connectivity and nervous system function. Numerous intracellular signaling components that are required for axon specification have been described but how such signaling paradigms are initiated by extracellular factor(s) within the embryonic milieu is poorly understood. Here, I describe how transforming growth factor-β (TGF-β), an embryonic morphogen that directs structural plasticity and growth in various cell types, initiates signaling pathways both in vivo and in vitro to fate naïve neurites into axons. Using conditional knockout strategies, I found that cortical neurons lacking the type II TGF-β receptor (TβR2) fail to initiate axons during development, and interestingly, fail to engage radial migration. In cultured neurons, exogenous TGF-β is sufficient to direct the rapid growth and differentiation of an axon and genetic enhancement of receptor activity promotes the formation of multiple axons. The cellular polarization of receptor activity occurs through the interaction of the type-I TGF-β receptor with Par6, a component of the axon-specifying Par3/Par6 polarity complex. Receptor distribution is restricted to axons, and downstream signaling events required for axon specification are triggered when Par6 is phosphorylated by TβR2. Together, these results indicate that TGF-β is the extrinsic cue for neuronal polarity in vivo and directs neuronal polarity by controlling Par6 activity and cellular migration during axon generation.
Item Open Access Reinterpreting the organizing principles of sex determination and gonadogenesis in the mouse(2021) Bunce, Corey MichaelThe mouse gonad begins its development as a bipotential primordia, capable of developing into a testis or ovary depending on the presence of the sex-determining gene, Sry. In the XY gonad, opposing pro-testis and pro-ovary pathways compete in gonadal supporting cells. While the individual cellular decision process is well understood, the higher-level process of coordination of cell fates across the gonad remains to be explained. The testis and ovary exhibit distinct patterns of differentiation, suggesting that either development of each organ requires a particular organizing principle or bipotentiality requires regional separation for fate specification or stabilization. The overall goal of this work is to improve characterizations of the spatiotemporal features of sex determination and gonadogenesis, including cell fate organization, morphogenic processes, and system context.Though several hypotheses have connected gonad morphogenesis to sex determination, the morphogenic processes that occur in the gonad have not been sufficiently characterized for formulating testable hypotheses. To capture and analyze the complexity of genital ridge morphogenesis, we generated a 3-dimensional time course of gonad development in native form and context using whole embryo tissue clearing and light sheet microscopy. Analysis revealed that the early gonad exhibits anterior-to-posterior patterns as well as increased rates of growth, rotation, and separation in the central domain. In extending characterization to the neighboring nephric ducts, we found a close alignment of gonad and mesonephric duct movements as well as delayed duct development in Cbx2 mutants, which undergo XY sex reversal and gonad dysgenesis. These data support mechanical integration of gonad and mesonephric duct morphogenesis. In investigating the mechanisms underlying the center-to-pole pattern of testis differentiation, we performed anteroposterior axis analyses and ex vivo gonad reconstruction cultures. These experiments allowed us to rule out two commonly accepted theories in the field: paracrine relay and center-first Sry expression. After searching for patterns in other cellular processes during gonadogenesis, including cell cycle arrest and coelomic epithelium proliferation, we uncovered a center-biased pattern of supporting cell precursor ingression. The updated model indicates that differences between the patterns of differentiation in the testis and ovary are due to features of their respective regulatory networks connecting their fate dynamics to different general gonadal organizing principles acting upstream of supporting cell differentiation. Following recent work on the rete testis and rete ovarii suggesting these structures contribute to gonadal supporting cell populations, we characterized early development of the rete and adjacent tissues in both sexes. Comparison of the GATA4+/PAX8+ presumptive rete with mesonephric and gonadal cells led to the identification of undescribed patterns in mesonephros development which may play a role in sexual dimorphism of the rete. Cells of the rete may derive from mesonephric condensates in a process similar to kidney nephron development. Cell cycle analysis revealed the mesonephric tubules and early rete to be a largely non-proliferating population of cells, suggesting expansion through recruitment of new cells. These results were used to establish preliminary theories for lineage relationships in early urogenital development. Initial attempts at lineage tracing to test the theory were unsuccessful. The findings presented here contribute to a more comprehensive and systems level understanding of sex determination and gonad development. In particular, the incorporation of high-resolution spatial information into theories of sex determination serves to connect individual cell fate decisions to organ level patterns of differentiation in space and time. These results will be useful for novel hypothesis generation as well as for designing more detailed models and simulations of sex determination and gonadogenesis.