Visualization of the Superior Ocular Sulcus during Danio rerio Embryogenesis

Congenital ocular coloboma is a genetic disorder that is typically observed as a cleft in the inferior aspect of the eye resulting from incomplete choroid fissure closure. Recently, the identification of individuals with coloboma in the superior aspect of the iris, retina, and lens led to the discov...

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Veröffentlicht in:	Journal of Visualized Experiments 2019-03 (145)
Hauptverfasser:	Yoon, Kevin H., Widen, Sonya A., Wilson, Melissa M., Hocking, Jennifer C., Waskiewicz, Andrew J.
Format:	Artikel
Sprache:	eng
Schlagworte:	Animals Developmental Biology Embryo, Nonmammalian - cytology Embryo, Nonmammalian - physiology Embryonic Development Eye - embryology Fluorescent Antibody Technique Image Processing, Computer-Assisted Iris - embryology Iris - physiology Lens, Crystalline - embryology Lens, Crystalline - physiology Mice Organogenesis Retina - embryology Retina - physiology Zebrafish - embryology
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creator	Yoon, Kevin H. Widen, Sonya A. Wilson, Melissa M. Hocking, Jennifer C. Waskiewicz, Andrew J.
description	Congenital ocular coloboma is a genetic disorder that is typically observed as a cleft in the inferior aspect of the eye resulting from incomplete choroid fissure closure. Recently, the identification of individuals with coloboma in the superior aspect of the iris, retina, and lens led to the discovery of a novel structure, referred to as the superior fissure or superior ocular sulcus (SOS), that is transiently present on the dorsal aspect of the optic cup during vertebrate eye development. Although this structure is conserved across mice, chick, fish, and newt, our current understanding of the SOS is limited. In order to elucidate factors that contribute to its formation and closure, it is imperative to be able to observe it and identify abnormalities, such as delay in the closure of the SOS. Here, we set out to create a standardized series of protocols that can be used to efficiently visualize the SOS by combining widely available microscopy techniques with common molecular biology techniques such as immunofluorescent staining and mRNA overexpression. While this set of protocols focuses on the ability to observe SOS closure delay, it is adaptable to the experimenter’s needs and can be easily modified. Overall, we hope to create an approachable method through which our understanding of the SOS can be advanced to expand the current knowledge of vertebrate eye development.
doi_str_mv	10.3791/59259
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Recently, the identification of individuals with coloboma in the superior aspect of the iris, retina, and lens led to the discovery of a novel structure, referred to as the superior fissure or superior ocular sulcus (SOS), that is transiently present on the dorsal aspect of the optic cup during vertebrate eye development. Although this structure is conserved across mice, chick, fish, and newt, our current understanding of the SOS is limited. In order to elucidate factors that contribute to its formation and closure, it is imperative to be able to observe it and identify abnormalities, such as delay in the closure of the SOS. Here, we set out to create a standardized series of protocols that can be used to efficiently visualize the SOS by combining widely available microscopy techniques with common molecular biology techniques such as immunofluorescent staining and mRNA overexpression. While this set of protocols focuses on the ability to observe SOS closure delay, it is adaptable to the experimenter’s needs and can be easily modified. 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While this set of protocols focuses on the ability to observe SOS closure delay, it is adaptable to the experimenter’s needs and can be easily modified. 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Recently, the identification of individuals with coloboma in the superior aspect of the iris, retina, and lens led to the discovery of a novel structure, referred to as the superior fissure or superior ocular sulcus (SOS), that is transiently present on the dorsal aspect of the optic cup during vertebrate eye development. Although this structure is conserved across mice, chick, fish, and newt, our current understanding of the SOS is limited. In order to elucidate factors that contribute to its formation and closure, it is imperative to be able to observe it and identify abnormalities, such as delay in the closure of the SOS. Here, we set out to create a standardized series of protocols that can be used to efficiently visualize the SOS by combining widely available microscopy techniques with common molecular biology techniques such as immunofluorescent staining and mRNA overexpression. While this set of protocols focuses on the ability to observe SOS closure delay, it is adaptable to the experimenter’s needs and can be easily modified. Overall, we hope to create an approachable method through which our understanding of the SOS can be advanced to expand the current knowledge of vertebrate eye development.</abstract><cop>United States</cop><pub>MyJove Corporation</pub><pmid>30985739</pmid><doi>10.3791/59259</doi></addata></record>
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subjects	Animals Developmental Biology Embryo, Nonmammalian - cytology Embryo, Nonmammalian - physiology Embryonic Development Eye - embryology Fluorescent Antibody Technique Image Processing, Computer-Assisted Iris - embryology Iris - physiology Lens, Crystalline - embryology Lens, Crystalline - physiology Mice Organogenesis Retina - embryology Retina - physiology Zebrafish - embryology
title	Visualization of the Superior Ocular Sulcus during Danio rerio Embryogenesis
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