Molecular Neurogenetics of Eye Development in Drosophila PDF Download

Author: Patricia Jean Renfranz
Publisher:
ISBN:
Category :
Languages : en
Pages : 416

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Author: Amit Singh
Publisher: Springer Science & Business Media
ISBN: 1461482321
Category : Medical
Languages : en
Pages : 375

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Undoubtedly, Drosophila melanogaster, fruit fly, has proved to be one of the most popular invertebrate model organisms, and the work horse for modern day biologists. Drosophila, a highly versatile model with a genetic legacy of more than a century, provides powerful genetic, cellular, biochemical and molecular biology tools to address many questions extending from basic biology to human diseases. One of the most important questions in biology focuses on how does a multi-cellular organism develop from a single-celled embryo. The discovery of the genes responsible for pattern formation has helped refine this question, and led to other questions, such as the role of various genetics and cell biological pathways in regulating the crucial process of pattern formation and growth during organogenesis. Drosophila eye model has been extensively used to study molecular genetic mechanisms involved in patterning and growth. Since the genetic machinery involved in the Drosophila eye is similar to humans, it has been used to model human diseases and homology to eyes in other taxa. This book will discuss molecular genetic mechanisms of pattern formation, mutations in axial patterning, Genetic regulation of growth in Drosophila eye, and more. There have been no titles in the past ten years covering this topic, thus an update is urgently needed.​

Author: Amit Singh
Publisher: Springer Nature
ISBN: 3030422461
Category : Medical
Languages : en
Pages : 368

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Drosophila melanogaster (fruit fly) is a highly versatile model with a genetic legacy of more than a century. It provides powerful genetic, cellular, biochemical and molecular biology tools to address many questions extending from basic biology to human diseases. One of the most important questions in biology is how a multi-cellular organism develops from a single-celled embryo. The discovery of the genes responsible for pattern formation has helped refine this question and has led to other questions, such as the role of various genetic and cell biological pathways in regulating the process of pattern formation and growth during organogenesis. The Drosophila eye model has been extensively used to study molecular genetic mechanisms involved in patterning and growth. Since the genetic machinery involved in the Drosophila eye is similar to humans, it has been used to model human diseases and homology to eyes in other taxa. This updated second edition covers current progress in the study of molecular genetic mechanisms of pattern formation, mutations in axial patterning, genetic regulation of growth, and more using the Drosophila eye as a model.

Author: Daisuke Yamamoto
Publisher: Landes Bioscience
ISBN:
Category : Medical
Languages : en
Pages : 192

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Author: Kevin Moses
Publisher: Springer Science & Business Media
ISBN: 3540453989
Category : Science
Languages : en
Pages : 296

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1 Kevin Moses It is now 25 years since the study of the development of the compound eye in Drosophila really began with a classic paper (Ready et al. 1976). In 1864, August Weismann published a monograph on the development of Diptera and included some beautiful drawings of the developing imaginal discs (Weismann 1864). One of these is the first description of the third instar eye disc in which Weismann drew a vertical line separating a posterior domain that included a regular pattern of clustered cells from an anterior domain without such a pattern. Weismann suggested that these clusters were the precursors of the adult ommatidia and that the line marks the anterior edge of the eye. In his first suggestion he was absolutely correct - in his second he was wrong. The vertical line shown was not the anterior edge of the eye, but the anterior edge of a moving wave of patterning and cell type specification that 112 years later (1976) Ready, Hansen and Benzer would name the "morphogenetic furrow". While it is too late to hear from August Weismann, it is a particular pleasure to be able to include a chapter in this Volume from the first author of that 1976 paper: Don Ready! These past 25 years have seen an astonishing explosion in the study of the fly eye (see Fig.

Author: Benjamin Jay Frankfort
Publisher:
ISBN:
Category :
Languages : en
Pages : 454

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Author:
Publisher:
ISBN:
Category :
Languages : en
Pages :

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Author: M. Elizabeth Fini
Publisher: Springer
ISBN: 9783642536786
Category : Science
Languages : en
Pages : 0

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"Who would believe that so small a space could contain the images of all the universe?" Leonardo da Vinci The last years of the 20th century have found the discipline of Developmental Biology returning to its original position at the forefront of biological re search. This progress can be attributed to the burgeoning knowledge base on molecules and gene families, and to the power of the molecular genetic ap proach. Topping the list of organ systems which have provided the most significant advances would have to be the eye. The vertebrate eye was one of the classic embryologic models, used to demonstrate many important prin ciples, including the concepts of inductive tissue interactions first put forth in the early 1900s. Within the last decade of this century, a return to some of the old questions with the new approaches has put eye development back into the limelight. I find this a highly appropriate topic for a book which aims to spark research for the new millennium. We begin with a chapter that discusses the anatomy of eye development, providing the basic reference information for the chapters that follow. A novel aspect of this introduction is the connection made between develop mental strategies and the eye's optical function. What also emerges from this chapter is the number of important eye structures that have barely been touched by the modern developmental biologist. Work on cornea and ante rior chamber development has lagged behind lens and retina.

Author: M Elizabeth Fini
Publisher:
ISBN: 9783642536779
Category :
Languages : en
Pages : 304

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Author: Meghana Tare
Publisher:
ISBN:
Category : Drosophila melanogaster
Languages : en
Pages : 240

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Complex network of genetic and molecular mechanisms governing the process of organogenesis have an important bearing on development of organisms. We are using an established model of Drosophila melanogaster commonly referred to as fruit fly in order to understand these mechanisms. We have used Drosophila eye to discern genetic hierarchy controlling the (i) event of axial patterning, and (ii) to study neurodegeneration in the developing eye. Axial patterning involves generation of dorsal-ventral (DV), anterior-posterior (AP) and proximal-distal (PD) axes in the organ primordium and is considered crucial for transformation of monolayer epithelium into a three dimensional organ. Any abnormalities in expression patterns of axial patterning genes may result in complete loss of organ. Drosophila eye develops from a default ventral state conferred by expression of genes Lobe (L) and Serrate (Ser). It has been found that antagonistic interaction of dorsal and ventral genes helps generation of midline or the equator which is essential for growth and differentiation of the eye field. Loss-of-function of L/Ser results in complete or loss-of-ventral eye depending on time axis involved. In a genetic modifier screen performed for search for modifiers of L mutant phenotypes, an E3 ubiquitin ligase, Cullin-4 (Cul-4) and GATA-1 transcription factor Pannier (Pnr) were identified. In the current study, we have characterized Cul-4, in promoting cell survival in the ventral domain of developing eye via downregulation of Wingless (Wg) signaling. Cul-4 also regulates JNK signaling to prevent cell death in the developing eye. We thus place the Cul-4 in the hierarchy of ventral genes involved in eye development.We also present the role of GATA-1 transcription factor Pnr in defining the dorsal eye margin boundary by suppressing the eye fate. Pnr downregulates retinal determination gene machinery via zinc finger transcription factor teashirt (tsh). We thus provide a novel mechanism involved in defining dorsal margins of the eye during early stages of organogenesis and an eye suppression function, as a late role of pnr in the developing eye. Identification and characterization of these genes in the dorsal and ventral domains of the eye may help enrich our understanding of the genetic hierarchy and the complex interactions of genes involved in axial patterning in the eye during organogenesis. Since the genetic machinery is highly conserved from flies to humans, these studies will have direct implications on higher vertebrates as well. Other than patterning and growth studies, Drosophila eye has been widely used to study genetic and molecular basis of neurodegeneration. A part of current study is to test the mechanisms involved in the neuronal cell death caused during the course of Alzheimer's disease (AD). AD is caused due to accumulation of Aß-42 peptide which is a product formed because of incorrect cleavage of Amyloid Precursor Protein (APP). Accumulation of Aß-42 results in formation of amyloid plaques which eventually results into stress and the neuronal cell death. We have found that JNK signaling pathway is induced upon Aß-42 accumulation and causes cell death of the neurons in the brain. Our study provides a new mechanistic insight from the perspective of identifying the new targets of AD neuropathy.