PrimeTime® qPCR Assays
In multiplex PCR, multiple targets are amplified in a single reaction tube. Each target is amplified by a different set of primers and a uniquely-labeled probe that will distinguish each PCR amplicon. Multiplexing provides some advantages over single-reaction PCR, including a lower amount of starting material, increased throughput, lower reagent costs, and less sample handling. However, the experimental design for multiplexing is more complicated as the amplification of each target can affect others in the same reaction. Therefore, careful consideration of design and optimization of the reactions is critical. IDT PrimeTime® qPCR Assays offer multiple dye/quencher combinations and primer/probe ratios to simplify the multiplex experiment design.
Reporter dye choice
Each target must be identified by a separate reporter dye. Select dyes so that fluorophore emission spectra overlap as little as possible, noting that some instruments are compatible with only certain dyes—check the documentation for your instrument to be sure the dyes are compatible. It is a good idea to select FAM for low copy messages for its strong signal. Lower-signal fluorophores can then be used for the higher abundant messages. IDT PrimeTime qPCR Assays come with 5 different dye/quencher combinations for the best fit for your instrument and multiplexing needs. See articles in the Additional reading sidebar below for recommendations for dye and reporter combinations for different PCR platforms.
Master mix considerations
During multiplex PCR, master mix reagents can be depleted fairly quickly for highly expressed genes due to the limited amount of reaction components. For these assays, it is preferable to limit the primer concentration of higher expressing genes. If the primers are limited, the amplification of the higher expressing genes will decrease, thereby making the mastermix ingredients more available for amplification of lower expressing targets. The primer-to-probe ratios that work best will depend on your particular experiments, but a good starting point is to limit the primer-to-probe ratio for the highest expressing genes to 1:1 and increase the ratio for the lowest expressing genes to 4:1. IDT PrimeTime Assays allow you to select a premixed primer/probe ratio from 1:1 to 4:1 to maximize experimental flexibility.
Validate the multiplex reactions by running a multiplex reaction in parallel with an individual reaction to make sure that similar Cq values are obtained. Compare the standard curves and verify that the Cq values are similar at both the high and low ends. A good multiplex will have similar curves and similar limits of detection.
Product focus qPCR Reagents—everything but your sample
- Master mix
- Probe-based and intercalating dye qPCR assays
- Water and buffer
Multiplex qPCR—how to get started—Learn how multiplex qPCR can save sample, reagent cost, and time. The article provides recommendations for multiplex qPCR assay design and experimental setup.
Optimizing multiplex qPCR for detecting infectious diseases and biothreat agents in the field—Research profile: Tetracore scientists specialize in developing large sets of robust probe-based qPCR assays for use in a multiplex format to detect infectious diseases and bio-terrorism threat agents. Here they discuss the need to: use probe dyes compatible on common PCR instruments, maintain low background with multiple probes, and reformulate assays to address viral mutation; and how ZEN™ Double-Quenched Probes have helped meet these criteria.
Recommended dye combinations for multiplex qPCR—These recommendations for selecting dyes for multiplex qPCR minimize background and avoid overlap of fluorescent signals. Included is a table of compatible dyes for multiplexing on common qPCR instruments and a list of suggested quenchers.
qPCR Probes—Selecting the Best Reporter Dye and Quencher—Choose dyes and quenchers that take into account instrument compatibility and multiplex probe applications.
Author: Ellen Prediger, PhD, is a senior scientific writer at IDT.
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