<p>The comprehensive spatiotemporal atlas of gene expression during early human embryonic development is critical for insights into embryogenesis<sup><CitationRef CitationID="CR1">1</CitationRef></sup>, organogenesis<sup><CitationRef CitationID="CR2">2</CitationRef></sup> and disease origins<sup><CitationRef CitationID="CR3">3</CitationRef>,<CitationRef CitationID="CR4">4</CitationRef></sup>. Here, leveraging Stereo-seq technology, we generated spatial transcriptomic profiles across 77 sagittal sections of 13 whole-human embryos ranging from Carnegie stage 12 to 23, integrated with single-nucleus RNA sequencing to elucidate gene expression patterns within defined cellular contexts, revealing the cellular heterogeneity that drives organ-specific differentiation. Our study has established a regulatory profile for the development of 50 organs and 198 substructures, and identified potential tissue-identity regulators. Of note, it uncovered previously uncharacterized gene functions in cardiac and brain development. The atlas not only substantiates and refines the current understanding of human organ development but also highlights key organs susceptible to genetic disorders. Furthermore, we characterized the allelic gene expression within specific organs at different developmental stages. This work presents a comprehensive compilation of genome-wide gene expression profiles for each spatially defined cell population, which can be visualized as a spatial display of the embryonic transcriptional landscape. These results offer the most thorough delineation to data of the spatiotemporal transcriptomic dynamics of human organogenesis.</p>

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Spatiotemporal transcriptome atlas of human embryos after gastrulation

  • Jiexue Pan,
  • Yuejiao Li,
  • Zhongliang Lin,
  • Qing Lan,
  • Ying Zhang,
  • Huixi Chen,
  • Shengwei Sui,
  • Man Zhai,
  • Gaochen Zhang,
  • Yi Cheng,
  • Yunhui Tang,
  • Qingchen Wang,
  • Yue Xu,
  • Guoling Li,
  • Chunyan Xu,
  • Haoqi Yan,
  • Yiting Mao,
  • Xingxia Wang,
  • Hao Li,
  • Yiping Zhu,
  • Qinfang Chen,
  • Yichun Guan,
  • Nan Meng,
  • Chang Wang,
  • Haiqian Lu,
  • Xiangjuan Li,
  • Tingting Zheng,
  • Xiaoying Yao,
  • Tingyu Yang,
  • Xuan Chen,
  • Qiuyu Qin,
  • Bin Jiang,
  • Yuxing Ren,
  • Xinmei Liu,
  • Yuxin Zhang,
  • Minghui Yu,
  • Lifang Wang,
  • Yanrong Wei,
  • Meiqi Luo,
  • Ji Nancuo,
  • Fuhe Ma,
  • Ziwei Wang,
  • Zhihua Ou,
  • Ying Lei,
  • Xin Jin,
  • Jianzhong Sheng,
  • Congjian Xu,
  • Yanting Wu,
  • Chenming Xu,
  • Lijian Zhao,
  • Hongbo Yang,
  • Ya Gao,
  • Guolian Ding,
  • Xun Xu,
  • Hefeng Huang

摘要

The comprehensive spatiotemporal atlas of gene expression during early human embryonic development is critical for insights into embryogenesis1, organogenesis2 and disease origins3,4. Here, leveraging Stereo-seq technology, we generated spatial transcriptomic profiles across 77 sagittal sections of 13 whole-human embryos ranging from Carnegie stage 12 to 23, integrated with single-nucleus RNA sequencing to elucidate gene expression patterns within defined cellular contexts, revealing the cellular heterogeneity that drives organ-specific differentiation. Our study has established a regulatory profile for the development of 50 organs and 198 substructures, and identified potential tissue-identity regulators. Of note, it uncovered previously uncharacterized gene functions in cardiac and brain development. The atlas not only substantiates and refines the current understanding of human organ development but also highlights key organs susceptible to genetic disorders. Furthermore, we characterized the allelic gene expression within specific organs at different developmental stages. This work presents a comprehensive compilation of genome-wide gene expression profiles for each spatially defined cell population, which can be visualized as a spatial display of the embryonic transcriptional landscape. These results offer the most thorough delineation to data of the spatiotemporal transcriptomic dynamics of human organogenesis.