41 / 2024-10-02 13:43:30
单细胞尺度空间Hi-C技术探究哺乳动物脑的染色质高级结构
Abstract Accepted
陈雪鹏 / 广州实验室
The 3D chromatin architecture is crucial for understanding gene regulatory programs in the development and disease. However, the direct mapping genome-wide 3D chromatin structures while retaining spatial information in tissues is still lacking. Here, we develop a spatial Hi-C method to resolve chromatin architecture profiling in situ tissue at single-cell resolution. The spatial Hi-C alone can obviously distinguish different cell niches in mammalian brains. Single-cell spatial Hi-C profiles in mouse brains show a decreased trend of the long-range interactions along the inside-to-outside radial direction on coronal brain sections, which is associated with neuronal differentiation states. In all, spatial Hi-C provides a valuable tool to study spatial 3D genome regulation in complex tissues.The 3D chromatin architecture is crucial for understanding gene regulatory programs in the development and disease. However, the direct mapping genome-wide 3D chromatin structures while retaining spatial information in tissues is still lacking. Here, we develop a spatial Hi-C method to resolve chromatin architecture profiling in situ tissue at single-cell resolution. The spatial Hi-C alone can obviously distinguish different cell niches in mammalian brains. Single-cell spatial Hi-C profiles in mouse brains show a decreased trend of the long-range interactions along the inside-to-outside radial direction on coronal brain sections, which is associated with neuronal differentiation states. In all, spatial Hi-C provides a valuable tool to study spatial 3D genome regulation in complex tissues.
Important Date
  • Conference Date

    Oct 31

    2024

    to

    Nov 03

    2024

  • Nov 03 2024

    Registration deadline

Sponsored By
崖州湾国家实验室
华中农业大学
浙江大学
中国遗传学会
中国遗传学会三维基因组学专委会
Organized By
中国生物信息学基因组信息学专委会
中国遗传学会表观遗传分会
中国细胞生物学学会染色质生物学分会
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