Rithu K Pattali, Izaiah J Ornelas, Carolyn D Nguyen, Da Xu, Nikita S Divekar, James K Nunez
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引用次数: 0
摘要
基于 CRISPR 的技术的出现,使细胞、组织和整个生物体内的可编程基因操作得以快速发展。表观遗传编辑是一种新兴的靶向基因扰动平台,它直接编辑 DNA 和组蛋白上的化学修饰,最终导致靶向基因的抑制或激活。与 CRISPR 核酸酶不同的是,表观遗传编辑调节基因表达,而不会诱导 DNA 断裂或改变宿主细胞的基因组序列。最近,我们开发出了 CRISPRoff 表观遗传编辑技术,它能同时在目标基因启动子上建立 DNA 甲基化和抑制性组蛋白修饰。在哺乳动物细胞中瞬时表达 CRISPRoff 和相应的引导 RNA 会导致目标基因的转录抑制,这种抑制会通过细胞分裂和分化被细胞遗传记忆。在这里,我们介绍了通过质粒 DNA 转染将 CRISPRoff 以及 CRISPRoff mRNA 导入转化人细胞系和原代免疫细胞的方案。我们还提供了评估目标基因沉默的指导,并强调了利用 CRISPRoff 进行基因扰乱时的主要注意事项。随着可编程基因组操作工具的快速发展,我们的方案也广泛适用于其他基于 CRISPR 的表观遗传编辑技术。
CRISPRoff epigenetic editing for programmable gene silencing in human cells without DNA breaks
The advent of CRISPR-based technologies has enabled the rapid advancement of programmable gene manipulation in cells, tissues, and whole organisms. An emerging platform for targeted gene perturbation is epigenetic editing, the direct editing of chemical modifications on DNA and histones that ultimately results in repression or activation of the targeted gene. In contrast to CRISPR nucleases, epigenetic editors modulate gene expression without inducing DNA breaks or altering the genomic sequence of host cells. Recently, we developed the CRISPRoff epigenetic editing technology that simultaneously establishes DNA methylation and repressive histone modifications at targeted gene promoters. Transient expression of CRISPRoff and the accompanying guide RNAs in mammalian cells results in transcriptional repression of targeted genes that is memorized heritably by cells through cell division and differentiation. Here, we describe our protocol for the delivery of CRISPRoff through plasmid DNA transfection, as well as the delivery of CRISPRoff mRNA, into transformed human cell lines and primary immune cells. We also provide guidance on evaluating target gene silencing and highlight key considerations when utilizing CRISPRoff for gene perturbations. Our protocols are broadly applicable to other CRISPR-based epigenetic editing technologies, as programmable genome manipulation tools continue to evolve rapidly.