Endocytic Control of Notch-Mediated Cell Fate Decisions in Neurogenesis

神经发生中Notch介导的细胞命运决定的内吞控制

• 批准号: 7533760
• 负责人: Fabrice J. Roegiers
• 金额: $ 34.16万
• 依托单位: RESEARCH INST OF FOX CHASE CAN CTR
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-07-01 至 2013-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7533760
• 关键词: Adult; Animals; Arts; Biochemical; Biochemical Genetics; Biological; Cell division; Cell membrane; Cells; Disease; Drosophila genus; Early Endosome; Endosomes; Failure; Genetic; Genome; Goals; Golgi Apparatus; Homologous Gene; Image; Imaging Techniques; Integral Membrane Protein; Integrins; Lateral; Life; Malignant Neoplasms; Mediating; Membrane; Membrane Protein Traffic; Membrane Proteins; Mitosis; Molecular; N-terminal; Notch Signaling Pathway; Numbers; Pathway interactions; Pattern; Peripheral Nervous System; Process; Protein Dynamics; Protein Precursors; Proteins; Public Health; Reagent; Reporter; Role; Sequence Analysis; Signal Transduction; Sorting - Cell Movement; Stem cells; Study models; System; Tissues; Vertebrates; Vesicle; base; cell behavior; cellular imaging; comparative; daughter cell; human disease; in vivo; insight; molecular modeling; neurogenesis; notch protein; rab GTP-Binding Proteins; stem; trafficking

DESCRIPTION (provided by applicant): The goal of this proposal is to determine how membrane trafficking during asymmetric cell division controls a Notch signaling pathway-mediated cell fate switch. Understanding how fundamental cell biological mechanisms are mobilized to establish a specific context to regulate the Notch signaling pathway will provide insights into how dysregulation of these mechanisms in stem and progenitor cells contributes to human diseases, including cancer. One such context is the progenitor cells of the Drosophila adult peripheral nervous system (PNS), which provide a powerful model for the study of binary cell fate decisions based on the activation or inhibition of Notch activity. We have generated exciting new in vivo reagents to exploit this system using state of the art imaging techniques. We will build on the genetic framework our lab and others have established that a specific subset of conserved membrane trafficking regulators are required for correct Notch- mediated cell fate assignments after asymmetric cell division. These membrane regulators do not control Notch signaling during tissue patterning and lateral inhibition, rather they appear to target Sanpodo, a four pass transmembrane protein expressed exclusively in asymmetrically dividing cells. Previously, we demonstrated that Sanpodo promotes Notch activity to confer correct cell fates after asymmetric cell division in the adult peripheral nervous system. In preliminary studies, we developed Sanpodo-GFP, an in vivo reporter of Sanpodo protein dynamics, which faithfully recapitulates Sanpodo function in Notch signaling. Furthermore, through genetic and biochemical studies, we demonstrate that the N-terminal region of Sanpodo, which contains a previously uncharacterized and evolutionarily conserved motif, is critical for Sanpodo's function. In live imaging studies we show that key trafficking regulators are required for Sanpodo sorting to two discrete membrane domains within minutes after asymmetric progenitor cell mitosis. We hypothesize that evolutionarily conserved vesicle trafficking regulators function to establish these membrane domains to promote Notch signaling in one daughter cell, and to inhibit Notch signaling in the other daughter cell. Our lab is poised to dissect the evolutionarily conserved molecular, cellular, and genetic mechanisms underlying the establishment asymmetric cell fate decisions by our unique ability to combine molecular modeling, biochemical analysis, and live cell imaging of progenitor cell behavior in the intact animal, and propose the following specific aims: Aim 1: To determine the mechanism of Sanpodo function in controlling Notch signaling at the plasma membrane in asymmetrically dividing cells. Aim 2: To determine the roles of conserved regulators of vesicle trafficking in regulating Notch signaling. Elucidating the mechanisms of spatial-temporal control of signaling in cell fate decisions is critical to our understanding of how vertebrate neurogenesis is regulated and how failure of these mechanisms leads to disease states. PUBLIC HEALTH RELEVANCE: Elucidating the mechanisms of spatial-temporal control of signaling in cell fate decisions is critical to our understanding of how vertebrate neurogenesis is regulated and how failure of these mechanisms leads to disease states.

描述（由申请人提供）：本提案的目的是确定不对称细胞分裂期间膜运输如何控制Notch信号通路介导的细胞命运开关。了解基本的细胞生物学机制如何被动员起来建立一个特定的环境来调节Notch信号通路，将有助于深入了解干细胞和祖细胞中这些机制的失调如何导致人类疾病，包括癌症。一个这样的背景是果蝇成体外周神经系统（PNS）的祖细胞，它提供了一个强大的模型，用于研究基于Notch活性的激活或抑制的二元细胞命运决定。我们已经产生了令人兴奋的新的体内试剂，利用最先进的成像技术的状态，这个系统。我们将建立在我们实验室和其他人已经建立的遗传框架上，即在不对称细胞分裂后，正确的Notch介导的细胞命运分配需要保守的膜运输调节因子的特定子集。这些膜调节剂在组织图案化和侧向抑制期间不控制Notch信号传导，而是它们似乎靶向Sanpodo，一种仅在不对称分裂细胞中表达的四次通过跨膜蛋白。先前，我们证明了Sanpodo促进Notch活性，以在成人外周神经系统中不对称细胞分裂后赋予正确的细胞命运。在初步研究中，我们开发了Sanpodo-GFP，一种Sanpodo蛋白动力学的体内报告基因，它忠实地再现了Notch信号传导中的Sanpodo功能。此外，通过遗传和生物化学研究，我们证明了Sanpodo的N-末端区域，其中包含一个以前未表征的和进化上保守的基序，是至关重要的Sanpodo的功能。在现场成像研究中，我们表明，关键的贩运监管机构所需的Sanpodo分选两个离散的膜结构域在几分钟内不对称祖细胞有丝分裂后。我们假设进化上保守的囊泡运输调节因子的功能是建立这些膜结构域，以促进一个子细胞中的Notch信号传导，并抑制另一个子细胞中的Notch信号传导。我们的实验室准备解剖进化保守的分子，细胞和遗传机制的基础上建立不对称的细胞命运的决定，我们独特的能力，结合联合收割机分子建模，生化分析，活细胞成像的祖细胞行为在完整的动物，并提出以下具体目标：目的1：确定Sanpodo功能在不对称分裂细胞中控制质膜上Notch信号传导的机制。目的2：研究保守的囊泡运输调控因子在Notch信号转导中的作用。阐明细胞命运决定中信号传导的时空控制机制对于我们理解脊椎动物神经发生是如何调节的以及这些机制的失败如何导致疾病状态至关重要。 公共卫生关系：阐明细胞命运决定中信号传导的时空控制机制对于我们理解脊椎动物神经发生是如何调节的以及这些机制的失败如何导致疾病状态至关重要。