Beyond Pseudotime: Enhanced Single-cell Genomics Tools for Understanding the Temporal Dynamics of Development and Disease

超越伪时间：增强的单细胞基因组学工具用于理解发育和疾病的时间动态

• 批准号: 10472651
• 负责人: Darren A Cusanovich
• 金额: $ 36.46万
• 依托单位: UNIVERSITY OF ARIZONA
• 依托单位国家: 美国
• 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/10472651
• 关键词: Address; Adult; Biological Assay; Cells; Cues; DNA Sequence; Development; Developmental Biology; Developmental Process; Disease; Disease Progression; Event; Gene Expression Profile; Genome; Genomics; Hepatocyte; Hormonal; Human Development; Human Genome; Human body; Intervention; Leukocytes; Link; Measures; Pathogenicity; Pathway interactions; Pattern; Process; Public Health; Recording of previous events; Regulation; Stimulus; Technology; Time; Work; cell type; gene therapy; genome-wide; genomic tools; improved; multiplex assay; response; single cell technology; stem cell therapy; tool; zygote

ABSTRACT From a single fertilized egg, the human genome must regulate an incredible succession of cellular divisions and fate decisions to give rise to the adult human body and its ~30 trillion cells [1]. The genome must also orchestrate highly diverse functions in these terminal cell types and in many instances allow for dynamic responses to a variety of stimuli - from white blood cells responding to stimulation [2] to hepatocytes responding to hormonal cues [3]. Furthermore, developmental processes are asynchronous and continue for many cell types into adulthood. Fundamental to our understanding of the causal links in all of these processes is the concept of time. While time course studies have a long history in genomics [4], single-cell genomic technologies are providing unprecedented views into the temporal dynamics of cellular differentiation and response at a genomic scale [5]. This will have widespread implications for our strategies of stem cell therapy, windows of intervention in disease progression, and our basic understanding of developmental biology. However, these inferences are to-date limited and rely on a concept called ‘pseudotime’ [5], which is difficult to validate and can be warped relative to real time. To truly understand how the genome coordinates development, differentiation, and disease we need new tools that allow us to better measure several key features of developmental trajectories: the ordering of regulatory cascades, the duration of the key genomic events in developmental processes, and the specific DNA sequences that can regulate temporal expression patterns. In order to address these concerns, we will develop a new suite of tools that leverage single-cell readouts to better understand the genomic regulation of time. In particular, we will focus on highly multiplexed assays to better understand the necessary and sufficient ordering of regulatory cascades in differentiation pathways, assays to convert pseudotime to real time, and genome scalable assays to identify and validate the exact regulatory sequences that define temporal patterns of gene expression.

摘要 从一个受精卵，人类基因组必须调节一系列令人难以置信的细胞分裂和 命运决定了成年人体及其约30万亿个细胞的诞生。基因组还必须协调 在这些终端小区类型中具有高度多样化的功能，并且在许多情况下允许对 各种刺激--从白细胞对刺激的反应[2]到肝细胞对激素的反应 线索[3]。此外，发育过程是不同步的，并对许多类型的细胞持续到 成人期。我们理解所有这些过程中的因果联系的基础是时间的概念。 虽然时间进程研究在基因组学中有很长的历史[4]，但单细胞基因组技术正在提供 在基因组水平上对细胞分化和反应的时间动态的前所未有的观点[5]。 这将对我们的干细胞治疗策略产生广泛的影响，这是疾病干预的窗口 进展，以及我们对发育生物学的基本理解。然而，这些推论是最新的。 是有限的，并且依赖于一个被称为‘伪时间’的概念[5]，这个概念很难验证，并且可以相对于它来扭曲 实时的。为了真正了解基因组如何协调发育、分化和疾病，我们需要 使我们能够更好地衡量发展轨迹的几个关键特征的新工具：排序 调控级联反应、发育过程中关键基因组事件的持续时间以及 可以调节时间表达模式的特定DNA序列。为了解决这些问题 ，我们将开发一套新的工具，利用单细胞读数来更好地理解 基因组对时间的调节。特别是，我们将专注于高度多元化的分析，以更好地了解 在分化途径中调节级联的必要和充分的排序，分析以转换 伪时间到实时，以及基因组可扩展的分析，以识别和验证准确的调控 定义基因表达的时间模式的序列。