利用Hi-C、Micro-C和启动子捕获Micro-C表征调控元件和核小体位置的染色质相互作用。

IF 4.2 2区 生物学 Q1 GENETICS & HEREDITY Epigenetics & Chromatin Pub Date : 2022-12-21 DOI:10.1186/s13072-022-00473-4
Beoung Hun Lee, Zexun Wu, Suhn K Rhie
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引用次数: 3

摘要

背景:调控元件如启动子、增强子和绝缘子相互作用介导分子过程。为了捕获调控元件的染色质相互作用,开发了3c衍生的方法,如Hi-C和Micro-C。在这里,我们生成并分析了不同测序深度的Hi-C、Micro-C和启动子捕获Micro-C数据集,以研究人类前列腺癌细胞中调节元件和核小体位置的染色质相互作用。结果:与Hi-C相比,Micro-C识别出更高分辨率的环路,包括围绕结构变异的环路。通过评估测序深度的影响,我们发现在1kb分辨率下检测染色质相互作用需要超过20亿reads的Micro-C。此外,我们发现深度测序识别了距离超过1mb的额外远程环路。此外,我们发现超过50%的环与绝缘体有关,而不到10%的环是启动子-增强子环。为了全面捕获启动子参与的染色质相互作用,我们执行了启动子捕获Micro-C。启动子捕获Micro-C识别具有较低测序读数的启动子附近的环。1.6亿次启动子捕获Micro-C的测序导致鉴定循环达到平台期。然而,即使在深度测序之后,仍有一部分启动子不参与环。通过将Micro-C与name -seq和ChIP-seq整合,我们发现与不参与环的活性启动子相比,参与环的活性启动子具有更低水平的DNA甲基化和更高度分期的核小体更容易接近的区域。结论:我们确定了Micro-C和启动子捕获Micro-C所需的测序深度,以生成高分辨率的染色质相互作用图和环。我们还研究了Hi-C、Micro-C和启动子捕获Micro-C的测序覆盖范围对检测染色质环的影响。我们的分析表明存在不同的调控元件组,它们不同地参与核小体位置和染色质相互作用。本研究不仅为理解调控元件之间的染色质相互作用提供了有价值的见解,而且为设计调控元件之间的染色质相互作用的研究项目提供了指导。
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Characterizing chromatin interactions of regulatory elements and nucleosome positions, using Hi-C, Micro-C, and promoter capture Micro-C.

Background: Regulatory elements such as promoters, enhancers, and insulators interact each other to mediate molecular processes. To capture chromatin interactions of regulatory elements, 3C-derived methods such as Hi-C and Micro-C are developed. Here, we generated and analyzed Hi-C, Micro-C, and promoter capture Micro-C datasets with different sequencing depths to study chromatin interactions of regulatory elements and nucleosome positions in human prostate cancer cells.

Results: Compared to Hi-C, Micro-C identifies more high-resolution loops, including ones around structural variants. By evaluating the effect of sequencing depth, we revealed that more than 2 billion reads of Micro-C are needed to detect chromatin interactions at 1 kb resolution. Moreover, we found that deep-sequencing identifies additional long-range loops that are longer than 1 Mb in distance. Furthermore, we found that more than 50% of the loops are involved in insulators while less than 10% of the loops are promoter-enhancer loops. To comprehensively capture chromatin interactions that promoters are involved in, we performed promoter capture Micro-C. Promoter capture Micro-C identifies loops near promoters with a lower amount of sequencing reads. Sequencing of 160 million reads of promoter capture Micro-C resulted in reaching a plateau of identifying loops. However, there was still a subset of promoters that are not involved in loops even after deep-sequencing. By integrating Micro-C with NOMe-seq and ChIP-seq, we found that active promoters involved in loops have a more accessible region with lower levels of DNA methylation and more highly phased nucleosomes, compared to active promoters that are not involved in loops.

Conclusion: We determined the required sequencing depth for Micro-C and promoter capture Micro-C to generate high-resolution chromatin interaction maps and loops. We also investigated the effect of sequencing coverage of Hi-C, Micro-C, and promoter capture Micro-C on detecting chromatin loops. Our analyses suggest the presence of distinct regulatory element groups, which are differently involved in nucleosome positions and chromatin interactions. This study does not only provide valuable insights on understanding chromatin interactions of regulatory elements, but also present guidelines for designing research projects on chromatin interactions among regulatory elements.

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来源期刊
Epigenetics & Chromatin
Epigenetics & Chromatin GENETICS & HEREDITY-
CiteScore
7.00
自引率
0.00%
发文量
35
审稿时长
1 months
期刊介绍: Epigenetics & Chromatin is a peer-reviewed, open access, online journal that publishes research, and reviews, providing novel insights into epigenetic inheritance and chromatin-based interactions. The journal aims to understand how gene and chromosomal elements are regulated and their activities maintained during processes such as cell division, differentiation and environmental alteration.
期刊最新文献
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