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单细胞分辨率的内胚层命运图谱揭示了细胞周期对胰腺祖细胞的界定。

A single-cell-resolution fate map of endoderm reveals demarcation of pancreatic progenitors by cell cycle.

机构信息

Institute of Developmental Biology and Regenerative Medicine, Southwest University, 400715 Chongqing, China.

Institute of Developmental Biology and Regenerative Medicine, Southwest University, 400715 Chongqing, China;

出版信息

Proc Natl Acad Sci U S A. 2021 Jun 22;118(25). doi: 10.1073/pnas.2025793118.

DOI:10.1073/pnas.2025793118
PMID:34161274
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8237672/
Abstract

A progenitor cell could generate a certain type or multiple types of descendant cells during embryonic development. To make all the descendant cell types and developmental trajectories of every single progenitor cell clear remains an ultimate goal in developmental biology. Characterizations of descendant cells produced by each uncommitted progenitor for a full germ layer represent a big step toward the goal. Here, we focus on early foregut endoderm, which generates foregut digestive organs, including the pancreas, liver, foregut, and ductal system, through distinct lineages. Using unbiased single-cell labeling techniques, we label every individual zebrafish foregut endodermal progenitor cell out of 216 cells to visibly trace the distribution and number of their descendant cells. Hence, single-cell-resolution fate and proliferation maps of early foregut endoderm are established, in which progenitor regions of each foregut digestive organ are precisely demarcated. The maps indicate that the pancreatic endocrine progenitors are featured by a cell cycle state with a long G1 phase. Manipulating durations of the G1 phase modulates pancreatic progenitor populations. This study illustrates foregut endodermal progenitor cell fate at single-cell resolution, precisely demarcates different progenitor populations, and sheds light on mechanistic insights into pancreatic fate determination.

摘要

在胚胎发育过程中,祖细胞可以产生特定类型或多种类型的后代细胞。明确所有后代细胞类型和每个未分化祖细胞的发育轨迹仍然是发育生物学的最终目标。对每个未分化祖细胞产生的所有胚层后代细胞的特征描述是朝着这一目标迈出的重要一步。在这里,我们重点研究早期前肠内胚层,它通过不同的谱系产生前肠消化器官,包括胰腺、肝脏、前肠和导管系统。我们使用无偏单细胞标记技术,对 216 个细胞中的每一个斑马鱼前肠内胚层祖细胞进行标记,以便直观地追踪其后代细胞的分布和数量。因此,建立了早期前肠内胚层的单细胞分辨率命运和增殖图谱,其中每个前肠消化器官的祖细胞区域被精确划定。图谱表明,胰腺内分泌祖细胞的特征是具有长 G1 期的细胞周期状态。操纵 G1 期的持续时间可以调节胰腺祖细胞群体。这项研究以单细胞分辨率阐明了前肠内胚层祖细胞命运,精确划定了不同的祖细胞群体,并为胰腺命运决定的机制提供了启示。

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