Exome Sequencing Starting from Single Cells

Current protocols Pub Date : 2024-09-26 DOI:10.1002/cpz1.70017

Ioanna Andreou, Markus Storbeck, Peter Hahn, Samuel Rulli, Eric Lader

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Abstract

Single-cell genomic analysis enables researchers to gain novel insights across diverse research areas, including developmental biology, tumor heterogeneity, and disease pathogenesis. Conducting single-cell genomic analysis using next-generation sequencing (NGS) methods has traditionally been challenging as the amount of genomic DNA present in a single cell is limited. Advancements in multiple displacement amplification (MDA) technologies allow the unbiased amplification of limited quantities of DNA under conditions that maintain its integrity. This method of amplification results in high yield and facilitates the generation of high-complexity NGS libraries that ensure the highest coverage to effectively allow variant calling.

With the introduction of new sequencing platforms and chemistry, whole genome sequencing became a more cost-effective application, but enrichment of specific regions of interest further reduces the amount of required sequencing output and associated costs. There are two enrichment methods, polymerase chain reaction (PCR)–based and hybrid-capture-based methods. PCR-based methods are very flexible and highly effective but focus on specific loci, typically known to be associated with disease. Inherited diseases of unknown genetic origin require a more comprehensive approach to capture the genetic variation that is not yet associated with a specific disease. Hybrid capture enrichment methods require considerable amounts of DNA such that exome enrichment from single cells is only possible after preamplification of this limited material.

This article describes the complete workflow from single cells and small quantities of DNA to exome-NGS libraries for Illumina sequencing instruments and includes the following protocols: © 2024 The Author(s). Current Protocols published by Wiley Periodicals LLC.

Basic Protocol 1: Whole genome amplification from single cells or small amounts of gDNA

Basic Protocol 2: NGS library generation of MDA-amplified material

Basic Protocol 3: Exome enrichment

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从单细胞开始的外显子组测序

单细胞基因组分析使研究人员能够在发育生物学、肿瘤异质性和疾病发病机制等多个研究领域获得新的见解。使用新一代测序（NGS）方法进行单细胞基因组分析历来具有挑战性，因为单细胞中的基因组 DNA 数量有限。多重置换扩增（MDA）技术的进步可以在保持 DNA 完整性的条件下对有限数量的 DNA 进行无偏扩增。这种扩增方法产量高，有利于生成高复杂度的 NGS 文库，确保最高的覆盖率，从而有效地进行变异调用。随着新的测序平台和化学方法的引入，全基因组测序成为一种更具成本效益的应用，但对特定感兴趣区域的富集进一步降低了所需的测序产出量和相关成本。目前有两种富集方法：基于聚合酶链反应（PCR）的方法和基于混合捕获的方法。基于聚合酶链式反应的方法非常灵活、高效，但主要针对特定位点，通常是已知与疾病相关的位点。基因来源不明的遗传性疾病需要更全面的方法来捕获尚未与特定疾病相关的基因变异。混合捕获富集方法需要大量 DNA，因此只有在对这些有限的材料进行预扩增后才能从单细胞中富集外显子组。本文介绍了从单细胞和少量 DNA 到用于 Illumina 测序仪器的外显子组-NGS 文库的完整工作流程，包括以下协议：© 2024 The Author(s).基本方案 1：从单细胞或少量 gDNA 扩增全基因组基本方案 2：MDA 扩增材料的 NGS 文库生成基本方案 3：外显子组富集

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Current protocols

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4.00

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