DNA Fiber Assay for the Analysis of DNA Replication Progression in Human Pluripotent Stem Cells

Q2 Biochemistry, Genetics and Molecular Biology Current Protocols in Stem Cell Biology Pub Date : 2020-06-25 DOI:10.1002/cpsc.115

Jason A. Halliwell, Polly Gravells, Helen E. Bryant

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引用次数: 9

Abstract

Human pluripotent stem cells (PSC) acquire recurrent chromosomal instabilities during prolonged in vitro culture that threaten to preclude their use in cell-based regenerative medicine. The rapid proliferation of pluripotent cells leads to constitutive replication stress, hindering the progression of DNA replication forks and in some cases leading to replication-fork collapse. Failure to overcome replication stress can result in incomplete genome duplication, which, if left to persist into the subsequent mitosis, can result in structural and numerical chromosomal instability.

We have recently applied the DNA fiber assay to the study of replication stress in human PSC and found that, in comparison to somatic cells states, these cells display features of DNA replication stress that include slower replication fork speeds, evidence of stalled forks, and replication initiation from dormant replication origins. These findings have expanded on previous work demonstrating that extensive DNA damage in human PSC is replication associated. In this capacity, the DNA fiber assay has enabled the development of an advanced nucleoside-enriched culture medium that increases replication fork progression and decreases DNA damage and mitotic errors in human PSC cultures.

The DNA fiber assay allows for the study of replication fork dynamics at single-molecule resolution. The assay relies on cells incorporating nucleotide analogs into nascent DNA during replication, which are then measured to monitor several replication parameters. Here we provide an optimized protocol for the fiber assay intended for use with human PSC, and describe the methods employed to analyze replication fork parameters. © 2020 Wiley Periodicals LLC.

Basic Protocol 1: DNA fiber labeling

Basic Protocol 2: DNA fiber spreading

Basic Protocol 3: Immunostaining

Support Protocol 1: Microscopy/data acquisition

Support Protocol 2: Data analysis

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DNA纤维法分析人多能干细胞DNA复制过程

人类多能干细胞(PSC)在长时间体外培养过程中获得复发性染色体不稳定性，这威胁到它们在基于细胞的再生医学中的应用。多能细胞的快速增殖导致组成性复制应激，阻碍DNA复制叉的进展，在某些情况下导致复制叉崩溃。不能克服复制压力会导致不完全的基因组复制，如果持续到随后的有丝分裂，会导致染色体结构和数量的不稳定。我们最近将DNA纤维分析应用于人类PSC的复制应激研究，发现与体细胞状态相比，这些细胞表现出DNA复制应激的特征，包括较慢的复制分叉速度，停滞分叉的证据，以及从休眠复制起点开始复制。这些发现扩展了先前的工作，表明人类PSC中广泛的DNA损伤与复制有关。在这种情况下，DNA纤维测定能够开发出一种先进的富含核苷的培养基，这种培养基可以增加复制叉的进展，减少人类PSC培养中的DNA损伤和有丝分裂错误。DNA纤维分析允许在单分子分辨率下研究复制叉动力学。该实验依赖于细胞在复制过程中将核苷酸类似物整合到新生DNA中，然后对其进行测量以监测几个复制参数。在这里，我们提供了一种用于人类PSC的纤维分析的优化方案，并描述了用于分析复制叉参数的方法。©2020 Wiley期刊有限责任公司基本协议1:DNA纤维标记基本协议2:DNA纤维扩散基本协议3:免疫染色支持协议1:显微镜/数据获取支持协议2:数据分析

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Current Protocols in Stem Cell Biology Biochemistry, Genetics and Molecular Biology-Cell Biology

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期刊介绍： Published in affiliation with the International Society for Stem Cell Research (ISSCR), Current Protocols in Stem Cell Biology (CPSC) covers the most fundamental protocols and methods in the rapidly growing field of stem cell biology. Updated monthly, CPSC will constantly evolve with thelatest developments and breakthroughs in the field. Drawing on the expertise of leading researchers from around the world, Current Protocols in Stem Cell Biology includes methods and insights that will enhance the progress of global research.