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扰动追踪能够对多尺度3D基因组调控因子进行高内涵筛选。

Perturb-tracing enables high-content screening of multi-scale 3D genome regulators.

作者信息

Cheng Yubao, Hu Mengwei, Yang Bing, Jensen Tyler B, Zhang Yuan, Yang Tianqi, Yu Ruihuan, Ma Zhaoxia, Radda Jonathan S D, Jin Shengyan, Zang Chongzhi, Wang Siyuan

机构信息

Department of Genetics, Yale School of Medicine, Yale University, New Haven, CT, USA.

M.D.-Ph.D. Program, Yale University, New Haven, CT, USA.

出版信息

Nat Methods. 2025 May;22(5):950-961. doi: 10.1038/s41592-025-02652-z. Epub 2025 Apr 10.

DOI:10.1038/s41592-025-02652-z
PMID:40211002
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12074983/
Abstract

Three-dimensional (3D) genome organization becomes altered during development, aging and disease, but the factors regulating chromatin topology are incompletely understood and currently no technology can efficiently screen for new regulators of multi-scale chromatin organization. Here, we developed an image-based high-content screening platform (Perturb-tracing) that combines pooled CRISPR screens, a cellular barcode readout method (BARC-FISH) and chromatin tracing. We performed a loss-of-function screen in human cells, and visualized alterations to their 3D chromatin folding conformations, alongside perturbation-paired barcode readout in the same single cells. We discovered tens of new regulators of chromatin folding at different length scales, ranging from chromatin domains and compartments to chromosome territory. A subset of the regulators exhibited 3D genome effects associated with loop extrusion and A-B compartmentalization mechanisms, while others were largely unrelated to these known 3D genome mechanisms. Finally, we identified new regulators of nuclear architectures and found a functional link between chromatin compaction and nuclear shape. Altogether, our method enables scalable, high-content identification of chromatin and nuclear topology regulators that will stimulate new insights into the 3D genome.

摘要

三维(3D)基因组组织在发育、衰老和疾病过程中会发生改变,但调节染色质拓扑结构的因素尚未完全明确,目前也没有技术能够有效地筛选多尺度染色质组织的新调节因子。在此,我们开发了一种基于图像的高内涵筛选平台(Perturb-tracing),该平台结合了混合CRISPR筛选、细胞条形码读出方法(BARC-FISH)和染色质追踪技术。我们在人类细胞中进行了功能缺失筛选,并在同一单细胞中观察了其3D染色质折叠构象的变化以及与扰动配对的条形码读出结果。我们发现了数十种不同长度尺度下染色质折叠的新调节因子,范围从染色质结构域和区室到染色体区域。一部分调节因子表现出与环挤压和A-B区室化机制相关的3D基因组效应,而其他调节因子在很大程度上与这些已知的3D基因组机制无关。最后,我们鉴定出了核结构的新调节因子,并发现了染色质压缩与核形状之间的功能联系。总之,我们的方法能够对染色质和核拓扑结构调节因子进行可扩展的高内涵鉴定,这将为3D基因组带来新的见解。

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