极端qPCR的动力学要求

Q1 Biochemistry, Genetics and Molecular Biology Biomolecular Detection and Quantification Pub Date : 2019-03-01 DOI:10.1016/j.bdq.2019.100081

Adam L. Millington, Jessica A. Houskeeper, John F. Quackenbush, James M. Trauba, Carl T. Wittwer

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引用次数: 17

摘要

定量PCR的动力学要求实验分为DNA变性、引物退火和聚合酶延伸三个阶段。两个阶段的温度/时间条件保持最优，而另一个阶段的温度/时间条件则被限制到扩增效率(通过定量周期(Cq)的增加来测量)下降。在商用毛细管LightCycler®上研究延伸。使用Taq的快速缺失突变体(KlenTaq™)，每70 bp的产物长度大约需要1 s。为了研究退火和变性时间，使用定制的“极限”PCR仪，在3种温度下，增加引物和聚合酶浓度。实际样品温度和时间是测量的，而不是编程或预测的。对于变性，需要在变性阈值以上200-500 ms才能达到最大效率。退火时，要求低于退火阈值300-1000 ms。温度阈值设定在引物退火或PCR产物变性98%时，由熔融曲线实验确定。从快速循环PCR到极端PCR，循环次数减少了10-60倍。如果温度控制准确，试剂的灵活性是允许的，短产物的PCR可以在不到15秒内进行。我们也把PCR的背景下，其他新兴的方法，并考虑其相关的分子诊断的演变。

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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The kinetic requirements of extreme qPCR

The kinetic requirements of quantitative PCR were experimentally dissected into the stages of DNA denaturation, primer annealing, and polymerase extension. The temperature/time conditions for 2 stages were kept optimal, while the other was limited until the amplification efficiency decreased as measured by an increase in quantification cycle (Cq). Extension was studied in a commercial capillary LightCycler®. Using a rapid deletion mutant of Taq (KlenTaq^™), about 1 s was required for every 70 bp of product length. To study annealing and denaturation times of <1 s, a custom “extreme” PCR instrument with 3 temperatures was used along with increased primer and polymerase concentrations. Actual sample temperatures and times were measured rather than programmed or predicted. For denaturation, 200–500 ms above the denaturation threshold was necessary for maximal efficiency. For annealing, 300-1000 ms below the annealing threshold was required. Temperature thresholds were set at 98% primer annealing or PCR product denaturation as determined experimentally by melting curves. Progressing from rapid cycle PCR to extreme PCR decreased cycling times by 10–60 fold. If temperatures are controlled accurately and flexibility in reagents is allowed, PCR of short products can be performed in less than 15 s. We also put PCR in context to other emerging methods and consider its relevance to the evolution of molecular diagnostics.

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