在分化人类多能干细胞过程中对Perturb-seq进行基准测试和优化

Benchmarking and optimizing Perturb-seq in differentiating human pluripotent stem cells.

作者信息

Sivakumar Sushama, Wang Yihan, Goetsch Sean C, Pandit Vrushali, Wang Lei, Zhao Huan, Sundarrajan Anjana, Armendariz Daniel, Takeuchi Chikara, Nzima Mpathi, Chen Wei-Chen, Dederich Ashley E, El Hayek Lauretta, Gao Taosha, Ghazawi Renad, Gogate Ashlesha, Kaur Kiran, Kim Hyung Bum, McCoy Melissa K, Niederstrasser Hanspeter, Oura Seiya, Pinzon-Arteaga Carolos A, Sanghvi Menaka, Schmitz Daniel A, Yu Leqian, Zhang Yanfeng, Zhou Qinbo, Kraus W Lee, Xu Lin, Wu Jun, Posner Bruce A, Chahrour Maria H, Hon Gary C, Munshi Nikhil V

机构信息

Department of Internal Medicine, Division of Cardiology, University of Texas Southwestern Medical Center, Dallas, TX, USA.

Cecil H. and Ida Green Center for Reproductive Biology Sciences, University of Texas Southwestern Medical Center, Dallas, TX, USA.

出版信息

bioRxiv. 2025 Jan 23:2025.01.21.633969. doi: 10.1101/2025.01.21.633969.

DOI:10.1101/2025.01.21.633969

PMID:39896670

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11785042/

Abstract

Perturb-seq is a powerful approach to systematically assess how genes and enhancers impact the molecular and cellular pathways of development and disease. However, technical challenges have limited its application in stem cell-based systems. Here, we benchmarked Perturb-seq across multiple CRISPRi modalities, on diverse genomic targets, in multiple human pluripotent stem cells, during directed differentiation to multiple lineages, and across multiple sgRNA delivery systems. To ensure cost-effective production of large-scale Perturb-seq datasets as part of the Impact of Genomic Variants on Function (IGVF) consortium, our optimized protocol dynamically assesses experiment quality across the weeks-long procedure. Our analysis of 1,996,260 sequenced cells across benchmarking datasets reveals shared regulatory networks linking disease-associated enhancers and genes with downstream targets during cardiomyocyte differentiation. This study establishes open tools and resources for interrogating genome function during stem cell differentiation.

摘要

Perturb-seq是一种强大的方法，可系统地评估基因和增强子如何影响发育和疾病的分子及细胞途径。然而，技术挑战限制了其在基于干细胞的系统中的应用。在这里，我们在多种CRISPRi模式下、针对不同的基因组靶点、在多种人类多能干细胞中、在定向分化为多个谱系的过程中以及跨多个sgRNA递送系统对Perturb-seq进行了基准测试。为了作为基因组变异对功能的影响（IGVF）联盟的一部分确保大规模Perturb-seq数据集的经济高效生产，我们优化的方案在长达数周的过程中动态评估实验质量。我们对跨基准数据集的1,996,260个测序细胞的分析揭示了在心肌细胞分化过程中，将疾病相关增强子和基因与下游靶点联系起来的共享调控网络。这项研究建立了用于在干细胞分化过程中探究基因组功能的开放工具和资源。

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在分化人类多能干细胞过程中对Perturb-seq进行基准测试和优化

Benchmarking and optimizing Perturb-seq in differentiating human pluripotent stem cells.

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