生物
胚胎干细胞
细胞生物学
内皮干细胞
转录组
转录因子
功能(生物学)
胚胎发生
内皮
基因
基因剔除小鼠
抄写(语言学)
血管内皮生长因子B
基因表达调控
循环系统
血管母细胞
嵌合体(遗传学)
细胞分化
胚胎
基因靶向
解剖
血管生成
基因表达
遗传学
免疫学
转录调控
血管生成
地图集(解剖学)
作者
Lihui Lin,Jing Zhong,Fu-qing Jiang,Yu-xiang Wang,Lan-yue_Ma,Jia-xin Yang,Yu-yan Li,Rongrong Gao,Huijian Feng,Baomei Cai,Ziyu Feng,Xin Zhou,Ya-hai Shu,Pan Chen,Xue Wu,Chenlin Cai,Qiang Wang,Guangming Wu,Shangtao Cao*,Duanqing Pei*
标识
DOI:10.57760/sciencedb.35184
摘要
Endothelial cells (ECs) are essential components of the vertebrate circulatory system; however, a comprehensive atlas characterizing how ECs acquire organ-specific transcriptomic heterogeneity has not been established. Here, we generated a time-series endothelial resource covering the entirety of mouse embryonic development, including 26 time points and 8 organs. Time-series multiorgan comparison revealed emergence timing and lineage trajectory of organotypic ECs together with organ-specific genes and pathways. Using these resources, we found that most ECs showed distinguishable organ specificity before late-gestation. The organotypic EC-enriched genes were associated with vascular function in the organs. Human and mouse pulmonary ECs underwent an evolutionarily conserved transcriptional transition. Endothelial-specific knockout of Casz1, a pulmonary EC-enriched transcription factor, resulted in impaired vascular growth, disturbed pulmonary endothelial organotypic differentiation, and deficient epithelial-ECs crosstalk. Our work provides a powerful endothelial resource that reveals fundamental principles of organ-specific ECs differentiation and uncovers previously unknown molecular mechanisms governing lung-specific vascular development.
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