生物
巨核细胞
鉴定(生物学)
转录组
调节器
功能(生物学)
计算生物学
胚胎干细胞
神经发育
神经科学
细胞生物学
血小板
神经系统
功能分析
胚胎发生
遗传学
信号转导
血小板活化
微阵列分析技术
基因表达谱
基因
生物信息学
作者
Meijuan Xia,Yezi Ma,Yifei Cai,Jingjing Zhao,Yao Zhong,Sibei Guo,Minmin Li,Pei Su,Biao Shen,Huizhen He,Xiaoyuan Chen,Lin Zheng,Le Li,Ziqi Huo,Wen Zhou,Fei Wang,Cuicui Liu,H T Wang,Jiaxi Zhou
标识
DOI:10.1016/j.devcel.2026.04.005
摘要
The organ- and stage-specific diversity of megakaryocytes (MKs) has prompted a reassessment of their distribution and functions. By integrating single-cell transcriptomic data across multiple organs and developmental stages, we identified previously unreported MK and platelet markers, including Tnik , a key regulator of MK function and platelet production. Using these markers alongside established ones, we developed a machine learning-based MK identification system (MKIDS) that enables MK detection in the brain, heart, and placenta in mice and humans. Functional studies demonstrated that brain-resident MKs are essential for neural development, underscoring organ-specific roles of MKs in regulating tissue development and function. Transcriptomic integration of MKs across organs and stages, with functional validation, revealed a developmental shift in platelet production—from a mitochondria-low to a mitochondria-enriched subpopulation. Our findings offer a transformative perspective on the MK system, highlighting its cellular diversity, functional complexity, and developmental dynamics. • Identification of additional MK markers, such as TNIK • MKIDS enables detection of MKs across multiple organs not previously recognized • MKs in the embryonic brain support neural development • Two platelet-producing MK subsets (plt and mt) undergo a developmental transition Xia et al. integrate cross-organ and single-cell datasets to define megakaryocyte (MK) diversity, identify additional markers, and develop a machine learning-based identification system, MKIDS, to detect MKs in unrecognized organs. They show that MKs in the embryonic brain support neural development and reveal a developmental transition between platelet-producing MK subsets.
科研通智能强力驱动
Strongly Powered by AbleSci AI