Determining the cell fate programs of mammalian retina development

确定哺乳动物视网膜发育的细胞命运程序

基本信息

批准号：
10316121
负责人：
Martin Tran
金额：
$ 4.6万
依托单位：
CALIFORNIA INSTITUTE OF TECHNOLOGY
依托单位国家：
美国
项目类别：
财政年份：
2021
资助国家：
美国
起止时间：
2021-09-01 至 2025-08-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10316121
关键词：
Address Adult Animal Model Bar Codes Biological Biology Birth Order Blindness Brain Cell Communication Cell Lineage Cell division Cells Collaborations Core Facility Data Set Development Developmental Biology Developmental Process Disease Disease Progression Doctor of Philosophy Educational process of instructing Embryonic Development Engineering Family Fellowship Frequencies Funding Gene Expression Gene Expression Profile Generations Genetic Transcription Genome Goals Grant Heritability Heterogeneity Image In Situ Individual Investigation Knowledge Lead Learning Maps Measurement Methods Modeling Molecular Mus Mutation Neurobiology Neurons Operative Surgical Procedures Paper Pattern Pharmacology Positioning Attribute Procedures Process Publications Recording of previous events Regenerative Medicine Research Research Personnel Resolution Rest Retina Retinal Diseases Role Sampling Seminal Series Signal Transduction Spatial Distribution Statistical Models Stochastic Processes Structure System Techniques Technology Time Tissues Training Programs Trees Work Writing base career cell type doctoral student experimental study genome editing image processing insight large scale data novel novel strategies novel therapeutic intervention progenitor programs reconstruction regenerative retinal progenitor cell single molecule single-cell RNA sequencing statistics student mentoring symposium tool transcriptomics visual stimulus

项目摘要

Project Summary/Abstract The overarching goal of this proposal is to understand how the stereotypical structure of retina forms during embryonic development. Towards this goal, this proposal seeks to develop novel molecular recording technologies that allow the reconstruction of lineage history based on endpoint measurements. This method leverages genome editing techniques to stochastically create heritable mutations within synthetic barcode arrays that accumulate edits over time. Because readout of these arrays is compatible with spatial transcriptomics technologies, these methods when combined will allow the simultaneous capturing of transcriptional cell state, lineage relationships, and spatial position of single cells within retina tissue. The resulting lineage tree datasets will then be analyzed using a novel statistical tool termed Lineage Motif Analysis, a computational approach to identify all significantly over- or under-represented cellular patterns. This approach systematically enumerates all possible arrangements of observed fates on progressively larger subtrees and then compares their frequencies to those expected in a null model based on uncorrelated cell fate between cell divisions. Lineage trees will reveal how birth-order of cell types is regulated on the clonal level and lineage motifs will reveal the extent to which lineage in the retina is stochastic or preprogrammed. Furthermore, lineage motifs represent direct insight into the “rules” that govern how the retina forms during development, and provide a way to describe how such “rules” change in different contexts like disease or pharmacological perturbation. The datasets and analysis proposed here will inform the development of new therapeutic strategies for regenerative medicine to treat retinal diseases that lead to blindness. My training program outlined here will equip me with the necessary tools and knowledge to (1) carry out the aims of this proposal and gain novel biological understanding, and (2) advance me towards my career goal of leading a research team focused on studying the fundamental principles that underlie embryonic development and disease progression. I will work with Dr. Long Cai, a pioneer in spatial transcriptomics, to learn imaging and image processing techniques, as well as Dr. Carlos Lois, an expert in neurobiology, to learn mouse manipulation and surgical procedures. Dr. Elowitz and I will meet regularly to discuss my research progress, writing plans for paper publications and grants, teaching/mentoring students, and opportunities to present my research at Caltech and national conferences. As a PhD student at Caltech, I will have access to leaders well-versed in applying quantitative approaches to study developmental biology, state-of-the-art core facilities, and cutting-edge coursework in both biology and statistics. By funding the rest of my PhD research, this fellowship will enable me to uncover the fundamental principles that underlie retina development and set me up for independence as I transition towards becoming an independent investigator in my later career.

项目概要/摘要该提案的首要目标是了解视网膜的典型结构是如何形成的为了实现这一目标，该提案旨在开发新的分子记录。允许基于端点测量重建谱系历史的技术。利用基因组编辑技术在合成条形码中随机创建可遗传的突变随着时间的推移累积编辑的数组，因为这些数组的读出与空间兼容。转录组学技术，这些方法结合起来将允许同时捕获视网膜组织内单个细胞的转录细胞状态、谱系关系和空间位置。然后，将使用一种名为“谱系基序”的新型统计工具对所得谱系树数据集进行分析分析，一种计算方法，用于显着识别所有过度或代表性不足的细胞模式。方法系统地列举了在逐渐更大的范围内观察到的命运的所有可能安排子树，然后将它们的频率与基于不相关单元的空模型中预期的频率进行比较细胞分裂之间的命运将揭示细胞类型的出生顺序如何在克隆上受到调节。水平和谱系图案将揭示视网膜中的谱系随机或预编程的程度。此外，谱系图案代表了对控制视网膜如何形成的“规则”的直接洞察。发展，并提供一种方法来描述这些“规则”在不同情况下如何变化，例如疾病或这里提出的数据集和分析将为新药物的开发提供信息。再生医学治疗导致失明的视网膜疾病的治疗策略。这里概述的培训计划将为我提供必要的工具和知识，以便 (1) 执行该提案的目的并获得新颖的生物学理解，以及（2）推动我实现我的职业目标领导一个研究小组专注于研究胚胎的基本原理我将与空间转录组学先驱蔡龙博士合作，共同研究疾病的发展和进展。学习成像和图像处理技术，并向神经生物学专家Carlos Lois博士学习 Elowitz 博士和我将定期会面讨论我的研究。进展、撰写论文出版物和资助计划、教学/指导学生以及机会作为加州理工学院的博士生，我将有机会在加州理工学院和全国会议上展示我的研究成果。领导者精通应用定量方法来研究发育生物学，最先进的核心通过资助我其余的博士研究，这项研究金将使我能够揭示视网膜发育和设定的基本原理当我在以后的职业生涯中转向成为一名独立调查员时，我准备独立。