Dual-Labeled Probes in Digital PCR

Digital PCR (dPCR) is an end-point PCR method that is used for absolute quantification and for analysis of minority sequences against a background of similar majority sequences, e.g., quantification of somatic mutations. When using this technique, the sample is taken to limiting dilution (more accurately, partitioned) and the number of positive and negative reactions is used to determine a precise measurement of target concentration.

The sample is partitioned into some cases as many as a million or more reaction chambers, some of which contain one copy of the target nucleic acid molecule (positive), and some of which do not contain a copy (negative)—positive and negative are also described as "1" and "0," respectively, hence "digital."

This article begins with a basic overview of digital PCR and ends with a case study of how our Dual-Labeled Probes performed against those of a competitor as tested by a customer.

Overview

When performing conventional PCR, the final concentration of template is proportional to the starting copy number and the number of amplification cycles. One experiment of a given number of reactions is performed on a single sample and the result is an analysis of fragment sizes or, for quantitative real-time PCR (qPCR), the analysis is an estimate of the concentration of the target sequences in the reaction-based on the number of cycles required to reach a quantification cycle (Cq). When using dPCR, the sample is separated into a large number of reaction chambers, such that each partition contains either one or no copies of target (Figure 1, Table 1). The number of reaction chambers or partitions varies between systems, from several thousand to millions. The PCR is then performed in each partition and the amplicon detected using a fluorescent label such that the collected data are a series of positive and negative results. In theory, this would result in a positive signal from a partition that originally contained a single copy of target and a negative (i.e., no signal) from one that did not originally contain template. However, since it is possible that some partitions will contain more than a single copy of template, the dispersal of the sample into the partitions is considered to obey Poisson distribution.

In theory, dPCR can be used to overcome some of the difficulties that are encountered when using conventional PCR. When using dPCR, a sample is partitioned so that individual nucleic acid molecules within the sample are localized into many separate regions and therefore detection of any target is not dependent on the number of amplification cycles. This approach results in a much more sensitive differentiation of fold change than that afforded by qPCR; a well-optimized qPCR may differentiate 1.5-fold changes at best, whereas dPCR has been reported to differentiate 1.2-fold.¹ The dilution of sample makes this a useful tool for studying minority sequences against a majority of similar but differing sequences. For example, dPCR can be used to detect a low incidence somatic single nucleotide polymorphism (SNP) against a high concentration of WT sequence. This is because, when the total sample is partitioned, the rare sequence is also partitioned to a single copy, so it will be amplified in the absence of competition from the prominent sequence. Far fewer partitions will contain a positive for the rare SNP than for the WT, so it is possible to make an accurate measurement of the ratio of the two sequences.

Digital PCR has many potential applications, including the detection and quantification of low-level pathogens, rare genetic sequences, copy number variations (CNVs) and relative gene expression in single cells. Clonal amplification enabled by single-step dPCR is a key factor in reducing the time and cost of many of the “next-generation sequencing” methods, hence enabling personal genomics.

Primers & Probes

Though the reaction format and instrumentation needed varies, dPCR uses the same primers and probes as qPCR.
Figure 2 highlights the method of action of Dual-Labeled (hydrolysis) Probes, the most common detection chemistry.

Data Analysis

Both end-point PCR and qPCR detect the amplification of the target nucleic acid molecule ensemble present in the sample, which is one reaction chamber (Figure 3). In dPCR, the sample is partitioned into many reaction chambers (droplets), each of which either does or does not have one copy of the target nucleic acid molecule (Figure 4).

Case Study

A well-known life science research tools company compared the performance of our Dual-Labeled Probes with various changes in configuration, e.g. different quenchers, as well as against the probes of a competitor in a battery of dPCR tests. All experiments were performed on a Bio-Rad QX200 Droplet Digital^™ PCR (ddPCR^™) System.

Thermal Modifications

The first test (Figure 5) compared our probes with and without Locked Nucleic Acid against those of a competitor labeled with a different thermal modification, Minor Groove Binder (MGB).

Our probes detected 113.3 wild-type copies and 343 mutant copies per microliter, whereas the competitor probes detected 112.1 and 342, respectively. The equivalence of our probes vs. that of the competitor is evident as is the requirement that a thermal modification, such as Locked Nucleic Acid, is present to discriminate between SNPs.

HEX vs. ATTO-532

The second test (Figure 6, Table 2) compared our probes with HEX reporter dye and an alternative to HEX, ATTO-532.

*Coefficient of Variation

ATTO-532 appears to provide similar performance when compared against HEX. However, there is a limited body of literature with such comparisons. Therefore, we recommend that those interested in using ATTO-532 in dPCR to perform additional experiments to determine if it meets performance requirements.

Fluorescent vs Non-Fluorescent Quencher

The third test (Figure 7, Table 3) compared our probes with TAMRA and BHQ™-1 as quencher to determine if one or both would be sufficient compared to the performance of the competing NFQ (also called a DQ or Dark Quencher).

*Coefficient of Variation

As expected from published qPCR experiments and seen here, BHQ™-1 provides better separation of fluorescence signals than TAMRA in two-plex reactions with 6-FAM and HEX.

Dark Quencher vs. Dark Quencher

The fourth test (Figure 8, Table 4) compared our probes with BHQ™-1 and OQ^™ (Onyx Quencher^™), our own license and royalty-free non-fluorescent (dark) quencher.

*Coefficient of Variation

OQA provides equivalent quenching performance when compared against BHQ™-1. Given that OQ is available license and royalty free, it is an attractive option to consider when commercialization of dPCR probes is the goal.

SNP Detection

The fifth and final test (Figure 9 and associated tables) compared our probes against those of a competitor for detection of SNPs in common target genes.

*Coefficient of Variation

*Coefficient of Variation

*Coefficient of Variation

*Coefficient of Variation

*Coefficient of Variation

Our probes labeled with Locked Nucleic Acid and alternative reporters / quenchers perform comparably to those of a popular brand.

Conclusion

Our Dual-Labeled Probes perform well in dPCR when compared against a popular brand. If possible, follow these guidelines when setting up an experiment:

• Locked Nucleic Acid is required for detection of SNPs, but it may not be necessary for CNV (copy number variants) and gene expression analysis
• ATTO-532 might be a suitable replacement for HEX
• TAMRA should be avoided as a quencher
• OQ is comparable to BHQ™ in quenching

Both online and consultative design options are available. If additional help is needed, please consult our technical services group at oligotechserv@sial.com.