{"title":"Molecular recording using DNA Typewriter","authors":"Hanna Liao, Junhong Choi, Jay Shendure","doi":"10.1038/s41596-024-01003-0","DOIUrl":null,"url":null,"abstract":"Recording molecular information to genomic DNA is a powerful means of investigating topics ranging from multicellular development to cancer evolution. With molecular recording based on genome editing, events such as cell divisions and signaling pathway activity drive specific alterations in a cell’s DNA, marking the genome with information about a cell’s history that can be read out after the fact. Although genome editing has been used for molecular recording, capturing the temporal relationships among recorded events in mammalian cells remains challenging. The DNA Typewriter system overcomes this limitation by leveraging prime editing to facilitate sequential insertions to an engineered genomic region. DNA Typewriter includes three distinct components: DNA Tape as the ‘substrate’ to which edits accrue in an ordered manner, the prime editor enzyme, and prime editing guide RNAs, which program insertional edits to DNA Tape. In this protocol, we describe general design considerations for DNA Typewriter, step-by-step instructions on how to perform recording experiments by using DNA Typewriter in HEK293T cells, and example scripts for analyzing DNA Typewriter data ( https://doi.org/10.6084/m9.figshare.22728758 ). This protocol covers two main applications of DNA Typewriter: recording sequential transfection events with programmed barcode insertions by using prime editing and recording lineage information during the expansion of a single cell to many. Compared with other methods that are compatible with mammalian cells, DNA Typewriter enables the recording of temporal information with higher recording capacities and can be completed within 4–6 weeks with basic expertise in molecular cloning, mammalian cell culturing and DNA sequencing data analysis. This protocol describes a CRISPR prime editing-based method for the sequential and unidirectional tracing of insertional events in mammalian cells, generating a dynamic recording of such information within living cells.","PeriodicalId":18901,"journal":{"name":"Nature Protocols","volume":"19 10","pages":"2833-2862"},"PeriodicalIF":13.1000,"publicationDate":"2024-06-06","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Nature Protocols","FirstCategoryId":"99","ListUrlMain":"https://www.nature.com/articles/s41596-024-01003-0","RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"BIOCHEMICAL RESEARCH METHODS","Score":null,"Total":0}
引用次数: 0
Abstract
Recording molecular information to genomic DNA is a powerful means of investigating topics ranging from multicellular development to cancer evolution. With molecular recording based on genome editing, events such as cell divisions and signaling pathway activity drive specific alterations in a cell’s DNA, marking the genome with information about a cell’s history that can be read out after the fact. Although genome editing has been used for molecular recording, capturing the temporal relationships among recorded events in mammalian cells remains challenging. The DNA Typewriter system overcomes this limitation by leveraging prime editing to facilitate sequential insertions to an engineered genomic region. DNA Typewriter includes three distinct components: DNA Tape as the ‘substrate’ to which edits accrue in an ordered manner, the prime editor enzyme, and prime editing guide RNAs, which program insertional edits to DNA Tape. In this protocol, we describe general design considerations for DNA Typewriter, step-by-step instructions on how to perform recording experiments by using DNA Typewriter in HEK293T cells, and example scripts for analyzing DNA Typewriter data ( https://doi.org/10.6084/m9.figshare.22728758 ). This protocol covers two main applications of DNA Typewriter: recording sequential transfection events with programmed barcode insertions by using prime editing and recording lineage information during the expansion of a single cell to many. Compared with other methods that are compatible with mammalian cells, DNA Typewriter enables the recording of temporal information with higher recording capacities and can be completed within 4–6 weeks with basic expertise in molecular cloning, mammalian cell culturing and DNA sequencing data analysis. This protocol describes a CRISPR prime editing-based method for the sequential and unidirectional tracing of insertional events in mammalian cells, generating a dynamic recording of such information within living cells.
将分子信息记录到基因组 DNA 是研究从多细胞发育到癌症进化等各种课题的有力手段。通过基于基因组编辑的分子记录,细胞分裂和信号通路活动等事件会驱动细胞 DNA 发生特定改变,从而在基因组上标记出细胞的历史信息,这些信息可以在事后读出。虽然基因组编辑已被用于分子记录,但捕捉哺乳动物细胞中记录事件之间的时间关系仍是一项挑战。DNA 打字机系统克服了这一限制,它利用素体编辑来促进对工程基因组区域的顺序插入。DNA 打字机包括三个不同的组件:作为 "底物 "的 DNA 磁带(其上的编辑以有序的方式累积)、素编辑酶和素编辑向导 RNA(将插入编辑编程到 DNA 磁带上)。在本方案中,我们介绍了 DNA 打字机的一般设计注意事项、如何在 HEK293T 细胞中使用 DNA 打字机进行记录实验的分步说明以及分析 DNA 打字机数据的示例脚本 ( https://doi.org/10.6084/m9.figshare.22728758 )。本实验方案涵盖了 DNA Typewriter 的两大应用:通过素描编辑记录带有编程条形码插入的连续转染事件,以及记录单细胞扩增到多细胞过程中的系谱信息。与其他与哺乳动物细胞兼容的方法相比,DNA Typewriter 能以更高的记录能力记录时间信息,而且只需具备分子克隆、哺乳动物细胞培养和 DNA 测序数据分析方面的基本专业知识,就能在 4-6 周内完成。
期刊介绍:
Nature Protocols focuses on publishing protocols used to address significant biological and biomedical science research questions, including methods grounded in physics and chemistry with practical applications to biological problems. The journal caters to a primary audience of research scientists and, as such, exclusively publishes protocols with research applications. Protocols primarily aimed at influencing patient management and treatment decisions are not featured.
The specific techniques covered encompass a wide range, including but not limited to: Biochemistry, Cell biology, Cell culture, Chemical modification, Computational biology, Developmental biology, Epigenomics, Genetic analysis, Genetic modification, Genomics, Imaging, Immunology, Isolation, purification, and separation, Lipidomics, Metabolomics, Microbiology, Model organisms, Nanotechnology, Neuroscience, Nucleic-acid-based molecular biology, Pharmacology, Plant biology, Protein analysis, Proteomics, Spectroscopy, Structural biology, Synthetic chemistry, Tissue culture, Toxicology, and Virology.