qPCR primer design revisited

Q1 Biochemistry, Genetics and Molecular Biology Biomolecular Detection and Quantification Pub Date : 2017-12-01 DOI:10.1016/j.bdq.2017.11.001

Stephen Bustin , Jim Huggett

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引用次数: 168

Abstract

Primers are arguably the single most critical components of any PCR assay, as their properties control the exquisite specificity and sensitivity that make this method uniquely powerful. Consequently, poor design combined with failure to optimise reaction conditions is likely to result in reduced technical precision and false positive or negative detection of amplification targets. Despite the framework provided by the MIQE guidelines and the accessibility of wide-ranging support from peer-reviewed publications, books and online sources as well as commercial companies, the design of many published assays continues to be less than optimal: primers often lack intended specificity, can form dimers, compete with template secondary structures at the primer binding sites or hybridise only within a narrow temperature range. We present an overview of the main steps in the primer design workflow, with data that illustrate some of the unexpected variability that often occurs when theory is translated into practice. We also strongly urge researchers to report as much information about their assays as possible in their publications.

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重新设计qPCR引物

引物可以说是任何PCR检测中最关键的组成部分，因为它们的特性控制了这种方法独特的特异性和敏感性。因此，不良的设计加上未能优化反应条件可能导致技术精度降低和扩增目标的假阳性或阴性检测。尽管MIQE指南提供了框架，并且从同行评审的出版物、书籍和在线资源以及商业公司获得了广泛的支持，但许多已发表的检测方法的设计仍然不够理想:引物通常缺乏预期的特异性，可以形成二聚体，在引物结合位点与模板二级结构竞争，或者只能在狭窄的温度范围内杂交。我们概述了引物设计工作流程中的主要步骤，并用数据说明了理论转化为实践时经常发生的一些意想不到的变化。我们还强烈敦促研究人员在其出版物中尽可能多地报告有关其检测的信息。

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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