Global ETD Search

1	Identification of the molecular changes underlying head morphology variation in closely related Drosophila species Torres Oliva, Montserrat 23 May 2016 (has links) No description available. 570 eye development Drosophila evolution transcriptomics Biologie (PPN619462639)
2	アフリカツメガエルにおいてカンナビノイド受容体結合タンパク質１は目と神経の発生の制御因子である / Cannabinoid receptor-interacting protein 1 is a regulator of eye and neural development in Xenopus laevis 鄭, 小娜 23 March 2015 (has links) Kyoto University (京都大学) / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第19142号 / 生博第325号 / 新制\|\|生\|\|43 / 32093 / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授西田栄介, 教授豊島文子, 教授千坂修 / 学位規則第4条第1項該当 cnrip1 cnr1 eye development neural development Xenopus laevis 460
3	Molecular links between retinal determination factors and the oscillator mechanism Ghangrekar, Indrayani January 2011 (has links) The past two decades have highlighted the utility in using the fruit fly Drosophila as a model organism for unravelling the molecular and functional complexities of two important fields of research: the systems that guide retinal determination (RD) and circadian rhythms (the daily body clock or oscillator). RD and clock factors are of great interest as they are: (1) highly conserved in vertebrates; (2) also essential for other physiological systems; (3) implicated in several congenital disorders and other diseases. The RD factors operate within a network in which several of their interactions have been described. Two such factors, eyes absent (eya) and sine oculis (so), are known to function as a unit to direct transcriptional regulation during photoreceptor (PR) differentiation. The regulation of eya and so by a transcriptional repressor at the heart of the clock mechanism, vrille (vri), is here investigated. Two distinct observations advocated exploration of a link between vri and eya/ so is of interest. (1) vri is a core component of the clock and interacts with RD but the RD function is unknown. (2) Recent evidence suggests that an RD factor directly upstream of eya and so, twin-of-eyeless (toy), interacts with the oscillator mechanism through direct and indirect pathways. It is possible that the indirect influences of toy on the oscillator are mediated via eya and/ or so. Interactions between eya, so and vri during RD and within oscillator cells are investigated here.Eye development function was studied using immunohistochemistry and transgenic manipulation. VRI is not expressed within the developed PRs; rather, expression of VRI is down-regulated prior to differentiation. In addition, conversely to the hypothesised role, VRI is co-expressed with EYA in some regions. Together with data from transgenic manipulation of VRI regional expression, I propose that VRI is predominantly part of a developmental pathway but can attenuate eya and so expression.The VRI binding site has been described previously and several sites were identified within eya/ so loci, some of which were tested in an in vitro binding assay. Two such sites were located adjacent to a known enhancer of so. I generated two transgenic fly lines containing: 1) an extension of the original enhancer to contain the VRI sites; and 2) a similar construct with the VRI sites ablated. Comparison of the original enhancer to those from the current study confirmed that the VRI sites attenuate expression and that intervening regions must contain binding sites for other transcription factors.In adult brains over a circadian light-dark cycle, EYA protein was expressed in three of the central brain clock neurones. Furthermore, expression of eya and so transcripts in adult heads, PRs and the brain, changed over the light/ dark cycle independently of the clock - indicating that their expression is modulated over the light-dark cycle but not by the oscillator mechanism. These data suggest interactions between eye development factors eya/ so and oscillator components, or, the light/ dark cycle exist. These interactions may be important for tissue-specific circadian physiology as well as the overall oscillator mechanism and offer an intriguing route for future investigation. 571.861
4	Cannabinoid receptor-interacting protein 1 is a regulator of eye and neural development in Xenopus laevis / アフリカツメガエルにおいてカンナビノイド受容体結合タンパク質１は目と神経の発生の制御因子である Zheng, Xiaona 23 March 2015 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(生命科学) / 甲第19142号 / 生博第325号 / 新制\|\|生\|\|43(附属図書館) / 32093 / 京都大学大学院生命科学研究科統合生命科学専攻 / (主査)教授西田栄介, 教授豊島文子, 教授千坂修 / 学位規則第4条第1項該当 / Doctor of Philosophy in Life Sciences / Kyoto University / DFAM cnrip1 cnr1 eye development neural development Xenopus laevis 460
5	Biochemical and Functional Characterization of Semaphorin6A-PlexinA Signaling in Zebrafish Eye Development St. Clair, Riley 01 January 2019 (has links) During embryonic development, cells respond to extracellular signals to establish proper tissue organization. Semaphorins (Semas) are a large class of secreted and transmembrane proteins that signal through Plexin (Plxn) receptors to guide migrating cells to their correct position and thus play critical roles in the development of various tissues including the nervous and cardiovascular systems. We have previously shown that Sema6A-PlxnA2 signaling is essential for visual system development, as decreasing endogenous Sema6A or PlxnA2 in zebrafish results in decreased cohesion of the early eye field, impaired retinal lamination, and smaller eye size. However, the molecular mechanisms governing these phenotypes are unknown. This dissertation describes the elucidation of functionally-relevant mechanisms of Sema6A-PlxnA signaling during eye development using biochemical and proteomic approaches in cell culture systems and the zebrafish as an in vivo vertebrate model of eye development. We first describe our investigations on the receptor-proximal mechanisms of Sema6A-PlxnA signaling. The Src-family tyrosine kinase Fyn was known to bind to and phosphorylate PlxnA receptors. However, the specific sites of phosphorylation and their function were unknown. Using mass spectrometry, we identified highly-conserved, Fyn-induced PlxnA tyrosine phosphorylation sites. Mutation of these tyrosines to phenylalanine nearly eliminated Fyn-dependent PlxnA phosphorylation. Furthermore, unlike mRNA encoding wild type human PlxnA2, mRNA encoding the tyrosine-to-phenylalanine mutant PlxnA2 could not rescue the smaller eye size phenotype caused by endogenous PlxnA2 knockdown in zebrafish. This suggests that Fyn-dependent PlxnA2 phosphorylation is critical for proper vertebrate eye development. Next, we report the discovery and functional characterization of a naturally-released soluble ectodomain of Sema6A (sSema6A). We show that sSema6A production is increased by PKC activity. The identification of several PKC-dependent phosphorylation sites in the intracellular region of Sema6A suggests a mechanism for PKC-dependent release of sSema6A. Importantly, we show that sSema6A is functional as it promotes the cohesion of zebrafish early eye field explants. This is the first report of a soluble ectodomain of the Sema6 class and suggests that Sema6A can have regulated, long-range signaling capacity in addition to its canonical contact-mediated functions. Finally, we present our findings characterizing the role in eye development of CRMP2, a downstream effector of Sema-Plxn signaling. CRMP2 is known to be critical for lamination of the cerebral cortex, leading us to hypothesize that CRMP2 could also be involved in the lamination of the retina. Using morpholino-based knockdown of endogenous zebrafish Crmp2, we show that Crmp2 has a critical function in visual system development. Crmp2 knockdown results in smaller eye size, impaired retinal lamination and a weakened optic tract. Together, this dissertation describes important novel Sema6A-PlxnA signaling mechanisms and places them in the context of vertebrate eye development. Cell Signaling Eye Development Plexin Semaphorin Signal Transduction Zebrafish Cell Biology Developmental Biology Neuroscience and Neurobiology
6	Molecular mechanisms of choroid fissure closure and ventral retina formation in the zebrafish eye Lee, Jiwoon 10 February 2011 (has links) During optic cup morphogenesis, the neuroectodermal layers of the optic vesicle (OV) invaginate ventrally, and fuse at the choroid fissure (CF) along the proximo-distal axis such that the retina and retinal pigment epithelium (RPE) are confined within the cup. Failure of CF closure results in colobomas, which are characterized by the persistence of a cleft or hole at the back of the eye. While CF closure is a critical aspect of ocular development, the molecular and cellular mechanisms underlying this process are poorly understood. My research examined CF closure and colobomas using zebrafish as a model system. In the first study, I determined that early cell fate changes within the eye field could cause colobomas using the zebrafish mutant blowout. Colobomas in blowout resulted from defects in optic stalk morphogenesis whereby the optic stalk extended into the retina and impeded the edges of the CF from meeting and fusing. Positional cloning of blowout identified a nonsense mutation in patched1, a negative regulator of the Hedgehog pathway. Up-regulation of Hedgehog pathway activity causes disruption in the patterning of the OV into proximal and distal territories, revealing that cell fate determination, mediated by Hedgehog signaling, is intimately involved in regulating CF closure. In the second study, I examined Bcl6 function and regulation during zebrafish eye development. bcl6 encodes a transcriptional repressor expressed in the ventral retina during zebrafish eye development. Loss of Bcl6 function leads to colobomas along with up-regulation of p53, a previously known Bcl6 target, and an increase in the number of apoptotic cells in the retina, demonstrating that Bcl6 plays a critical role in preventing apoptosis in the retina during early eye development. I also showed that Vax1 and Vax2 act upstream of bcl6 in the ventral retina. Furthermore, I identified functional interactions between Bcl6, Bcor and Hdac1 during eye development, demonstrating that Bcl6 functions along with Bcor and Hdac1 to mediate cell survival by regulating p53 expression. Together my studies expand the gene regulatory network involved in cell fate determination and cell survival during CF closure and ventral retina formation, and provide mechanistic insight into coloboma formation. / text Choroid fissure closure Coloboma Shh Patched1 Bcl6 Zebrafish eye Retina Ocular development Eye development
7	Studies on development in Euphilomedes ostracods: Embryology, nervous system development, and the genetics of sexually dimorphic eye development Koyama, Kristina 01 January 2017 (has links) Model organism studies have been fundamental in understanding evolutionary and developmental biology. However, non-model organisms present opportunities to study unique characteristics and as comparisons to model organisms, leading us toward broader and more relevant perspectives on diversity. The Euphilomedes genus of ostracods is an example of a non-model group with potential for evolutionary and developmental studies. Ostracoda is an ancient, basally branching lineage of Crustaceans with a complete and prodigious fossil record. Despite the group’s promise for evolutionary studies, much remains unknown about the basic biology of this clade. There are a limited number of embryogenesis studies in Ostracoda; here, I study development in Euphilomedes. In Chapter 1, I study the main events in Euphilomedes’ embryology, focusing on cleavage and cell migration. I describe the general embryology of Euphilomedes, and devise a visual staging scheme for their development. Using fluorescent nuclear staining and microscopy, I visualize nuclei in cleavage throughout development of nuclear divisions and migrations during development. The meroblastic cleavage observed in Euphilomedes resembles that of another Myodocopid ostracod, Vargula hilgendorfii. Finally, immunostaining for acetylated-alpha tubulin and phalloidin staining are used to visualize the general anatomy of the embryonic brain. This provides new protocols for visualizing the nervous system, enabling more detailed nervous system studies in the future. In Chapter 2, I explore differential gene expression patterns in the developing eyes of juvenile Euphilomedes. Euphilomedes have sexually dimorphic eye types – males have lateral compound eyes, while females instead have eye rudiments. Previous studies in E. carcharodonta show that genes in the retinal determination and phototransduction gene networks have differential expression in males and females during eye development. In this thesis, we attempt to compare these patterns to expression in a sister species, E. morini. Developmental biology Genetics Biology Cleavage Crustacea Development Embryology Eye development Ostracoda Biology
8	Role of Growth Regulatory Pathways in Eye Development and Differentiation Wittkorn, Erika L. 05 June 2014 (has links) No description available. Developmental Biology Biology Genetics Differentiation Hippo signaling pathway eye development Drosophila
9	The Role of Sox4 in Regulating Choroid Fissure Closure and Retinal Neurogenesis Wen, Wen 01 January 2016 (has links) The development of the vertebrate eye is tightly controlled by precise genetic regulations. From a single ocular primordium to bilateral eyes with complex structures and cell types, it requires intensive proliferation and migration for cells in both the ectoderm and mesoderm to accomplish ocular morphogenesis, and during this process cell differentiation and interaction takes place to establish the complex composition of ocular cell types and cellular connections. Genetic defects can lead to severe abnormalities in eye morphogenesis and cell differentiation during ocular development. A tremendous amount of work has been done to identify both intrinsic and extrinsic factors that regulate ocular development. However, much more work is needed to fully understand this complex process. Sox4 is known as a transcription activator that regulates cell survival and differentiation in multiple embryonic tissues during development. Evidence of its requirement during ocular development has recently emerged, but the mechanism by which Sox4 regulates ocular development is far from elucidated. Chapter 1 of this dissertation provides an overview of different stages in embryonic eye development and known genetic interactions during each stage. It also reviews recent knowledge about SoxC proteins and their roles in ocular development. Chapter 2 presents data characterizing the expression profile of the zebrafish sox4 co-orthologs, sox4a and sox4b, in the developing eye. Additionally, it presents data from morpholino-mediated sox4 knockdown in zebrafish, which indicate that Sox4 deficiency leads to defects in choroid fissure closure through elevation in the Hedgehog (Hh) signaling pathway. Sox4 knockdown causes upregulation of the Hh ligand indian hedgehog b (ihhb), which alters the proximal-distal boundary of the optic vesicle and inhibits choroid fissure closure. Chapter 3 presents data reporting the generation of sox4 mutant zebrafish lines using the CRISPR/Cas9 genome editing system. Characterization of one sox4a maternal zygotic (MZ) mutant line confirms Sox4’s role in negative regulation of Hh signaling and reveals new evidence that maternal and zygotic sox4 are both critical for ocular development. Chapter 4 presents data demonstrating that sox4 is required for rod photoreceptor neurogenesis. Rod photoreceptor terminal differentiation is delayed in both sox4 morphants and sox4 CRISPR mutants, while rod progenitor and precursor cells are properly specified. In Chapter 5, the roles of Sox4 in regulating ocular development are summarized based on the results, and implications of the results are discussed to expand our understanding of the genetic regulation of ocular morphogenesis and retinal neurogenesis. Sox4 Eye development Coloboma Hedgehog signaling Rod photoreceptor CRISPR/Cas9 Developmental Biology Eye Diseases Genetics Molecular and Cellular Neuroscience
10	Genetic analysis of genes found on the 4th chromosome of Drosophila - emphasizing the developmental context of Pax6 Kronhamn, Jesper January 2004 (has links) The small size and the lack of recombination set the fourth chromosome of Drosophila melanogaster apart from the other chromosomes. I have shown that the Minute gene on chromosome 4, earlier named Minute-4, encodes the ribosomal protein RpS3A. Two Pax6 genes, eyeless (ey) and twin of eyeless (toy) are also located on chromosome 4. Pax6 genes are important in head and eye development in both mammals and Drosophila. I have focused much of the study on ey and toy. The first mutant of toy that was characterized showed a headless phenotype. This indicates that Toy is important for the development of both the eye and antennal discs. The phenotype of the null mutation in toy is temperature sensitive due to that transcription of ey is temperature dependent in the eye-antennal primordium in absence of Toy. This temperature dependence was used to find out that the phenocritical period for ey in the adult head development is during embryonic stage 12-16 when ey first is expressed in the eye-antennal primordium. I also conclude that ey is activated by Toy in the eye-antennal primordium. The strong eyD mutation was molecularly characterized and it was finally settled that it is an allele in the ey locus. I also show that eyD homozygotes have a headless phenotype, much stronger than the earlier ey mutations. Molecular genetics Pax6 twin of eyeless headless flies head development eye development eyeless Minute RpS3A regulatory region Drosophila Genetik Genetics Genetik

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