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Project 1 - Molecular mechanisms controlling TEC dynamics and lineage hierarchies in the perinatal thymus

项目 1 - 围产期胸腺中控制 TEC 动态和谱系层次的分子机制

基本信息

批准号：
10251297
负责人：
Ellen R Richie
金额：
$ 53.2万
依托单位：
UNIVERSITY OF TX MD ANDERSON CAN CTR
依托单位国家：
美国
项目类别：
财政年份：
2020
资助国家：
美国
起止时间：
2020-09-01 至 2025-08-31
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10251297
关键词：
Adolescent Adult Affinity Age Antigens Atlases Binding Proteins Binding Sites Bioinformatics Biological Assay Biometry Biostatistics Core CDK4 gene Cell Compartmentation Cell Cycle Cell Cycle Progression Cell Differentiation process Cell Lineage Cellular Structures ChIP-seq Characteristics Chromatin Coupled Cyclin D1 Data Development Differentiation and Growth Epigenetic Process Epithelial Cell Proliferation Event Family member Gene Expression Profile Gene Expression Profiling Gene Family Generations Genetic Genetic Transcription Goals Growth Homeostasis Human Image In Vitro Kidney Knowledge Life Link Location Maps Mediating Molecular Mus Newborn Infant Organ Culture Techniques Organizational Change Pathway interactions Perinatal Process Production Proteomics Regulatory T-Lymphocyte Reporting Resolution Retinoblastoma Self Tolerance Series Signal Pathway Signal Transduction T-Cell Development T-Lymphocyte T-cell receptor repertoire Testing Thymic Tissue Thymic epithelial cell Thymocyte Selection Thymus Gland Time Tissues Transgenes Transplantation autoreactivity capsule epithelial stem cell experimental study imaging approach in vivo in vivo evaluation insight keratin 5 multiplexed imaging perinatal period peripheral lymphoid organ progenitor programs promoter single-cell RNA sequencing transcriptome sequencing

项目摘要

Project Summary/Abstract Thymic epithelial cells (TECs) provide growth and differentiation signals that are indispensable for the development of T cells with a diverse, yet self-tolerant TCR repertoire. The number of TECs increases exponentially in newborns as the thymus grows to support increased production of naïve T cells that are exported to colonize peripheral lymphoid organs. The perinatal period is a time of dynamic changes in TEC subset composition, differentiation, organization and function. Although the conversion of perinatal thymus growth to juvenile thymus homeostasis is well established, the specific changes that occur in the composition of transcriptionally distinct TEC subsets and identification of signaling pathways that initially promote and subsequently limit expansion and remodeling of the TEC compartment are poorly understood. Furthermore, the TEC progenitors in which such molecular re-programming events occur have not been defined. Our preliminary data suggest that the Cyclin D1-retinoblastoma (RB)-E2F pathway is a key molecular switch that modulates TEC proliferation during the perinatal to adult transition. We have shown that expansion of the perinatal TEC compartment can be maintained into adulthood by deleting Rb family members or by expressing a keratin 5 driven Cyclin D1 (K5.D1) transgene to inactivate RB function. Our overall hypothesis is that perinatal and juvenile TECs express distinct transcriptional profiles that coordinate TEC proliferation and differentiation, and that the Cyclin D1-RB-E2F pathway regulates both processes. We propose a series of experiments that will test this hypothesis and provide new insights into currently unresolved questions regarding the perinatal TEC compartment. These questions include: 1) what changes occur in the composition of TEC subsets during the perinatal to juvenile transition; 2) how do the transcriptional signatures of TEC subsets change across the transition; 3) what molecular mechanisms and pathways regulate these changes; 4) what are the identities and lineage hierarchies of TEC progenitors during the transition; and 5) do comparable cellular and molecular changes occur in human TECs. The overall goal of RP1 is to resolve these knowledge gaps. In Aim 1, we will use scRNA-seq to determine changes in the transcriptional profiles and advanced imaging to map localization of transcriptionally distinct TEC subsets during the perinatal to juvenile transition. Parallel scRNA-seq and imaging analyses will be performed on human TECs and thymus tissue. In Aim 2 we will perform in vitro and in vivo assays to directly test the differentiation potential of candidate TEC progenitors identified in Aim 1. In Aim 3 we will determine whether molecular pathways that regulate TEC proliferation and differentiation are coordinately linked by performing proteomic screens coupled with ChIP- seq analyses.

项目摘要/摘要胸腺上皮细胞(TECs)提供生长和分化信号，这是胸腺细胞发展具有多样性但自我耐受的TCR谱系的T细胞。TEC的数量增加随着胸腺的生长以支持输出的幼稚T细胞的增加，新生儿的胸腺呈指数级增长来定植外周淋巴器官。围产期是TEC亚群动态变化的时期组成、分化、组织和功能。尽管围产期胸腺生长转换为幼年胸腺的动态平衡是建立良好的，在组成上发生的具体变化转录上不同的TEC亚群和识别最初促进和因此，对TEC间隔部的极限扩张和重塑知之甚少。此外，发生这种分子重编程事件的TEC前体还没有定义。我们的预赛研究表明，Cyclin D1-视网膜母细胞瘤(Rb)-E2F通路是调控TEC的关键分子开关在围产期向成人期过渡过程中的增殖。我们已经证明，围产期TEC的扩张通过删除RB家族成员或通过表达角蛋白5可以将间隔保持到成年期驱动Cyclin D_1(K5.D_1)转基因灭活Rb功能。我们的总体假设是围产期和幼年TEC表达不同的转录谱，协调TEC的增殖和分化，以及 Cyclin D1-Rb-E2F通路调控这两个过程。我们提出了一系列实验，以检验这一假说为目前尚未解决的有关围产期TEC的问题提供了新的见解车厢。这些问题包括：1)TEC子集的组成在围产期到青少年的转变；2)TEC亚群的转录签名是如何在不同时期变化的转变；3)什么分子机制和途径调节这些变化；4)什么是身份和过渡期间TEC祖细胞的谱系等级；以及5)具有可比性的细胞和分子人类的TEC发生了变化。RP1的总体目标是解决这些知识差距。在目标1中，我们将使用scRNA-seq来确定转录图谱的变化，并使用高级成像来定位地图在围产期到幼年期的转变过程中转录上不同的TEC亚群。并行scRNA-seq和成像分析将在人类TECs和胸腺组织上进行。在目标2中，我们将在体外和在体内实验直接测试Aim 1中确定的候选TEC前体细胞的分化潜能 3我们将确定调控TEC增殖和分化的分子途径是否通过进行蛋白质组筛选和芯片序列分析进行协调连接。