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The ability to detect specific genetic material has been a cornerstone of progress in numerous fields, from genome engineering to contaminant detection, and not least in diagnostic testing. With the development of the quantitative polymerase chain reaction (qPCR), also sometimes called quantitative real time polymerase chain reaction, these capabilities were extended from traditional PCR, offering improved sensitivity and specificity of detection and importantly, accurate quantification of target sequences.

In this article, we will consider how qPCR works, experimental requirements, data analysis and applications of the technique.

qPCR is a technique for the selective amplification and quantitative detection of regions of DNA or complimentary DNA (cDNA). Oligonucleotide primers flanking a region of interest are used to amplify the sequence utilizing a DNA polymerase enzyme.1 Repeated cycling of the amplification process leads to exponential expansion of the number of copies of the target region which is tracked either using an intercalating dye or sequence-specific probe whose fluorescence is then detected in the qPCR machine and plotted on an output graph.

RT-qPCR stands for quantitative reverse transcription polymerase chain reaction, the “RT” not to be mistaken for “real time”.2 Unlike qPCR that uses a DNA template, the starting material for RT-qPCR is RNA.3 Therefore, protocols incorporate a reverse transcription step to convert the RNA to cDNA before the normal qPCR amplification process commences. This may be done all in one reaction tube (one-step) or sequentially with reverse transcription taking place in a separate reaction to the qPCR amplification (two-step) (Figure 1).  

Figure 1: Diagram demonstrating the difference between one-step and two-step RT-qPCR.

Like a standard PCR machine, a qPCR machine consists of a heated block and lid that facilitates the rapid transition of samples between temperatures to enable amplification of a DNA or cDNA template (Figure 2). However, a qPCR machine also incorporates a fluorescent source and fluorometer to excite the fluorophores and detect the fluorescent output generated during cycles of qPCR amplification (Figure 3). The machine typically has or is linked to a computer that records the fluorimeter output and uses software to interpret the experimental results based on user-defined information such as control wells and standards.  

Figure 2: Illustration of how the amplification process works in PCR and qPCR. qPCR protocols typically incorporate around 30 – 40 amplification cycles, with copy numbers doubling each time.  

Figure 3: Fluorescent signal generation by dye-based and probe-based qPCR assays.

In many cases, a premixed solution is used that contains the polymerase, dNTPs, buffers and (if applicable) dye.

  1) A master mix containing all the reaction components except the template is gently mixed and aliquoted into reaction tubes (often a 96-well plate). The template (or water in the case of a no template control – see “qPCR controls”), is then carefully added to the relevant wells and the plate or tubes sealed. It is advisable to run samples in duplicate or triplicate, if possible, to improve result reliability.

Passive reference dyes (such as ROX) are included in many premade master mixes. They provide an internal reference to which the reporter dye signal can be normalized during data analysis, correcting for variations in concentration or volume. These may be omitted where quantitation is not required.

2) Information regarding the well contents and location, dye or probe chemistry being used, any standards or controls included and cycling conditions are provided to the computer/control unit by the user.

3)The template DNA or cDNA is heated, causing denaturation and producing single stranded DNA (ssDNA) (Figure 2). Bound intercalating dyes (if present) also dissociate, returning to ground state.

4) Sequence-specific primers bind to their target sequence (annealing) and complimentary bases are added to the sequence by DNA polymerase to produce a complimentary copy (primer extension). During this process, the fluorophores in the assay absorb light at one wavelength and re-emit it at a longer, lower energy wavelength if it is not quenched. The wavelength of excitation and emission will depend on the fluorophore(s) used.

- In the case of dye-based protocols, the intercalating dye will bind the newly formed dsDNA, emitting light when it does so.

 - There are a number of different probe-based chemistries, however, they generally work on a similar principle. Some form of fluorescence quenching ensures that fluorescence only occurs when target sequences are present, resulting in light emission during amplification.

5) The fluorescence produced is then detected by the fluorimeter and recorded by the computer. With a probe-based assay, the fluorescent signal is therefore proportional to the number of ssDNA fragments being amplified that are complimentary to the probe, and with dye-based assays proportional to the number of double stranded (dsDNA) copies.

6) Once amplification is complete, melt curve analysis may be performed on intercalating dye-based assay products which assesses the dissociation characteristics of the dsDNA products. With intercalating dyes, fluorescence will reduce as the dsDNA strands dissociate. The temperature at which 50% of DNA is denatured is known as the melting temperature and will be impacted by the sequences of the qPCR products. Samples are incrementally heated, typically over a range from 65 ° C to 95 ° C, and the effect on fluorescence recorded. Melt curve analysis can help to differentiate off-target amplification. This approach cannot be used for probe-based assays, where fluorescence is produced during the amplification process. The use of post-amplification probes may, however, facilitate amplicon differentiation using melt curve analysis and is even able to detect single base variations.4, 5

Many of the same rules for designing PCR primers also apply to qPCR primers, such as:

However, there are some differences:

In dye-based qPCR, an intercalating dye is used that displays weak fluorescence in its unbound form, increasing to a strong fluorescent signal when bound to dsDNA (Figure 3). SYBR ® Green6 is one of the most commonly used dsDNA binding dyes.7, 8 Fluorescence is directly proportional to the amount of dsDNA present, enabling the original template amount to be calculated.

Intercalating dyes are not sequence-specific so do not need to be tailored to individual assays, simplifying assay design. This also makes them cheaper. However, it means that they will fluoresce in response to the amplification of off-target or non-specific products as well as the desired target, reducing specificity. The facility for melt curve analysis can help here, especially when evaluating new assays. Dyes cannot be used for multiplexed reactions as, unlike probes, the signals cannot be differentiated. Therefore, multiple reaction wells with separate primer sets must be set up to evaluate different targets.

There are a number of different types of fluorescent probe and primer chemistries available for qPCR, but most rely on some form of covalently attached fluorescence quencher molecule that is released in the presence of a specific target sequence.

Unlike intercalating dyes, probes are sequence-specific and so must be designed for each assay, increasing assay setup complexity and cost. This does however mean they also improve assay specificity. Different probes can emit fluorescence of differing wavelengths by using different fluorophores, so they can be multiplexed provided compatible probes are selected and the machine possess the required filters. While initial assay development time may be longer and more complex, multiplexing can reduce subsequent set up time and reagent use by running multiple tests in a single well.

Hydrolysis probes 9 – Also called TaqMan or 5' nuclease, hydrolysis probes include a sequence-specific fluorescently labeled oligonucleotide probe with a fluorescent reporter at one end and a quencher at the other. When intact, the quencher suppresses the florescent signal. The 5' to 3' exonuclease activity of certain polymerases cleaves the probe during target amplification, so the fluorescent reporter is no longer near the quencher, resulting in fluorescent signal (Figure 4).

This is one of the most commonly used probe types.  

Figure 4: Diagram showing how hydrolysis probes function. The fluorescent reporter (R) is shown in green and the quencher (Q) in purple, target DNA in grey, amplified sequence in yellow (heavy line weight) and primers in yellow (fine line).

Molecular beacons 10 – Like hydrolysis probes, molecular beacons are sequence-specific fluorescently labeled oligonucleotide probes. However, they have complimentary bases (five or six) near their ends that form a hairpin structure, bringing the quencher close to the reporter and quenching the signal. When the probe binds its target sequence, the stem denatures, moving the reporter and quencher apart, resulting in a signal (Figure 5). Due to their structure, molecular beacon probes are harder to design than hydrolysis probes.  

Figure 5: Diagram showing how molecular beacons function. The fluorescent reporter (R) is shown in green and the quencher (Q) in purple, target DNA in grey and primers in yellow.

Dual hybridization probes 11 – Also called LightCycler or FRET probes, this technique uses a pair of probes designed to bind adjacent sequences, labeled with a donor and acceptor dye pair that exhibit fluorescence resonance energy transfer (FRET). When the probes bind their target sequence, the donor and acceptor dyes come into close proximity, FRET occurs and the acceptor emits fluorescence (Figure 6).  

Figure 6: Diagram showing how dual hybridization probes function. The donor fluorophore (R1) is shown in pink and the acceptor fluorophore (R2) in green, target DNA in grey and primers in yellow.

Minor groove binder (MGB) probes 12 – Also called Eclipse probes, they have a fluorophore and quencher on either end like hydrolysis probes. However, they also have a MGB near the quencher. In the absence of the target, MGB probes coil randomly, bringing the fluorophore and quencher into close proximity. When the probe binds its target, aided by the MGB, the probe linearizes, allowing the fluorophore to emit light (Figure 7).  

Figure 7: Diagram showing how MGB probes function. The fluorescent reporter (R) is shown in green and the quencher (Q) in purple, the MGB in orange, target DNA in grey and primers in yellow.

Amplifluor assays 13 – Here, the “probe” is known as a UniPrimer. The UniPrimer has a fluorescence reporter on one end and quencher on the other, forming a hairpin loop in its unbound state that quenches the signal. In the first round of amplification, one of the target-specific primer pair (called the Z primer) anneals and extends to create a product. In the second round, the other primer of the pair attaches to the newly formed product and extends to create the second strand. This then serves as a template for the UniPrimer which binds the Z primer sequence. Extension causes the UniPrimer to unfold, releasing the fluorophore from quenching (Figure 8).  

Figure 8: Diagram showing how Amplifluor assays work. The fluorescent reporter (R) is shown in green and the quencher (Q) in purple, target DNA in grey, amplified sequence in dark yellow and primers in yellow with the Z primer, in black, indicated.

Scorpion probes 14 – Here, one of the primers also serves as the probe. It has a fluorescent reporter and quencher on opposing ends, forming a stem loop structure that quenches the signal when not bound to its target. A section of sequence complimentary to a region downstream of the primer binding site and within the amplicon is incorporated within the loop. During amplification, this region binds to its target, causing the loop to break open, liberating the fluorescent reporter from the quencher’s influence (Figure 9).  

Figure 9: Diagram showing how Scorpion probes function. The fluorescent reporter (R) is shown in green and the quencher (Q) in purple, target DNA in grey, amplified sequence in yellow (heavy weight line), PCR blocker in orange and primers in yellow (fine line).

Light-upon-extension (LUX) probes 15 – Again, one of the primers with LUX-based assays also acts as the probe, however, unlike Scorpions, no quencher is present. The LUX primer has a reporter on one end and adopts a hairpin structure that itself quenches the fluorophore signal. When the primer binds its target, it becomes linearized, unquenching the reporter and producing a fluorescent signal (Figure 10).  

Figure 10: Diagram showing how LUX probes function. The fluorescent reporter (R) is shown in green, target DNA in grey, amplified sequence in dark yellow and primers in pale yellow.

QZyme probes 16 – A substrate is incorporated in QZyme assays that contains a reporter and quencher maintained in close proximity. One of the primers incorporates the antisense sequence of a catalytic DNA region able to cleave the substrate. Once amplified, this region then cleaves the substrate, separating the quencher from the fluorophore and producing a fluorescent signal (Figure 11).  

Figure 11: Diagram showing how QZyme probes function. The fluorescent reporter (R) is shown in green and the quencher (Q) in purple, target DNA in grey, amplified sequence in dark yellow and primers in pale yellow with the complimentary catalytic region in pink and yellow.

Locked nucleic acid (LocNA) probes 17 – LocNAs are modified nucleotides that contain a methylene bridge, restricting the structure’s flexibility (Figure 12). Incorporating LocNAs within probe sequences can improve specificity and facilitate the use of shorter qPCR probes, helpful in challenging sequences.  

Figure 12: A locked nucleic acid monomer. Modified bases contain a methylene bridge bond (red) between the 2′ oxygen and the 4′ carbon of the pentose ring.

It is important to include appropriate controls18, 19 within the experimental set-ups to enable interpretation of the results and the identification of potential issues. These include a no template control (NTC), negative control and positive control.

The NTC should contain all the reagents of the other wells but use PCR grade water in place of a sample. These wells should show no amplification, otherwise it is indicative of DNA/RNA contamination of one or more reagents, or the equipment used to set up the experiment.

Negative controls contain DNA/RNA that lacks the region targeted by the primers and probe. Ideally this would be the same as the sample in every other way, so a strain/individual of the same species lacking the gene of interest (naturally or through genetic manipulation) would be optimal. As the name suggests, the negative control should show no amplification. Depending on how good the assay is, it may be possible to get non-target amplification which should be differentiable from the melt curve data in dye-based assays. If this occurs in assays to be used routinely, selecting an alternative target sequence may be desirable.

The positive control20 should contain the target sequence and be known to amplify successfully (in the case of an established assay) as this is the signal to which unknowns will be compared. If the assay is in development, having confirmatory data that this is a positive sample from other techniques (such as conventional PCR, next-generation sequencing (NGS) or culture) can help to confirm the results obtained. If a positive control fails to amplify, then results from that run should be considered void as it indicates a problem with the assay.

Where assays aim to measure relative quantitation rather than absolute quantitation, as is the case in some transcriptional studies, an endogenous control21 is required that should be measured in all wells. For this, a gene is chosen that should be transcribed at a constant, abundant level across all samples in all conditions, such as a housekeeping gene. This is then used to normalize data on transcription of the genes of interest to correct for factors like variation in the amount of starting material and reaction efficiency.

There are a number of terms that are important to know in understanding qPCR output.

Baseline : The background fluorescence signal, normally determined in the early cycles prior to detectable increases in fluorescence.

Rn (normalized reporter) : The fluorescence emission intensity of the fluorescent reporter divided by the fluorescence emission intensity of the passive reference dye.

Rn- : The Rn value of an un-reacted sample, obtained from early cycles or an NTC.

Rn+ : The Rn value of a well containing all reaction components, including the template.

ΔRn : The magnitude of the signal generated for a well by the qPCR experiment.

                                                     ΔRn = (Rn+) – (Rn-) Threshold : The threshold (often seen as a horizontal line on an amplification plot) is the average standard deviation of Rn for the early cycles, multiplied by an adjustable factor often determined by the machine’s software. It represents a statistically significant point above the calculated baseline and should be set in the region associated with an exponential increase in the amount of PCR product.

Ct (threshold cycle) : This is the cycle number at which the fluorescence generated by a well crosses the threshold when sufficient amplicons have accumulated. This is also sometimes called the quantification cycle (Cq), crossing point (Cp) or take-off point (TOP).

Many software packages will set the necessary analysis parameters for you; however, it is helpful to understand their meaning, how adjustments may affect results and learn to identify potential problems.

The output obtained from a qPCR experiment will depend in part on the type of analysis that was run, but for all an amplification plot should be obtained. This shows the magnitude of the fluorescent signal ( Δ Rn) generated on the y-axis plotted over the course of amplification cycles on the x-axis for each well (Figure 13). Where replicates of the same sample are included, they should be as close together as possible. Variations between replicates indicates likely experimental error and repetition may be required. Equally, it is important that no amplification is observed in the NTC or negative control and a good positive signal is seen in the positive control well(s). The earlier the cycle number at which the amplification line crosses the threshold, the higher the target copy number in that well.  

Figure 13: Example qPCR amplification plot, this example shows a set of standards run in duplicate. The white line indicates the threshold.

If the aim of the experiment is to determine if a target is present or not and quantification is not necessary, then standards are not included. Many qPCR packages include software that will automatically call such results positive or negative.

When quantification is required, there are two main options, absolute quantitation or relative quantitation. For absolute quantitation,22 standards are included to enable determination of the target copy number in an unknown sample. Standards use DNA of the same species used for the unknowns (often the same as the positive control) and should cover a wide range of concentrations across the full capabilities of the assay (its dynamic range), often in 10-fold serial dilutions, e.g., 1 x 101, 1 x 102, 1 x 103, 1 x 104, 1 x 105, 1 x 106 and 1 x 107 DNA genome copies per well. Quantification of samples that fall outside of this range will be less reliable and it is therefore advisable to adjust unknown sample dilutions to bring them into this range and repeat the test. From this, unknown sample quantities can be extrapolated. The number of DNA copies per µ l can be calculated for standards provided the user knows the concentration of the stock DNA sample being used to make the standards and the size of the genome in base pairs. Once this has been determined, appropriate dilutions can be made.

The log of the starting quantity (SQ) is plotted against the Ct value for each of the standard wells and a line of best fit drawn through the data points (Figure 14). The slope indicates the efficiency (E) of the assay and should be 100% (i.e., for each cycle the amount of product doubles).

                                                                E = -1+10(-1/slope)

Assays should aim for an efficiency between 90 and 110% which corresponds to a slope of -3.58 to -3.10. The R2 value is the coefficient of correlation obtained for the standard curve, indicating how good one value is at predicting the other and should be as close to 1 as possible, at least > 0.99.  

Figure 14: Example of a qPCR standard curve. For relative quantitation, normalization known as ΔΔCt is used. Here, the Ct values for each well for the housekeeping gene(s) selected are compared to the Ct values of the gene(s) of interest. These normalized values are then compared between controls and unknown samples. With this method, no standards are required, reducing reagent use. However, greater work is required during development, and it is important to note that this method assumes the amplification efficiencies for all targets are close to 100% and within 5% of each other. As mentioned previously, melt curve analysis can be used to check the identity of qPCR products, particularly helpful for dye-based amplification. Positive control wells (in a well-designed assay) should give a nice clean peak indicating the melting temperature of the qPCR product (Figure 15). If peaks other than these are observed for some wells, it indicates the presence of non-target products and can mean that quantification in these wells is unreliable. Equally, the absence of the target peak would indicate the absence of the target amplicon, suggesting the well is negative.  

Figure 15: Example of qPCR melt curve analysis. Dissociation temperatures are indicated on the x-axis. The change in fluorescence is indicated on the right y-axis (dashed line); at low temperatures the DNA is in double strand form, and it has 100% fluorescence, reducing as the temperature increases and the DNA dissociates. The left y-axis shows Rn, with peaks corresponding to the melting temperatures of the qPCR product(s).

For both qPCR and PCR, the amplification process occurs in pretty much the same way. However, there are notable differences.

Digital PCR (dPCR)23 amplifies target regions of DNA or cDNA in much the same way as qPCR, using primers and a probe. However, it differs from qPCR in the way the sample and reactions are handled and how the target is measured. The reaction mix is partitioned into many wells prior to amplification so that each acts as a separate reaction, with each well containing one or no copies of the target. The method relies on the assumption that sample partitioning will follow a Poisson distribution. Following amplification, wells are scored as positive (fluorescent), or negative (not fluorescent) and absolute quantitation is then calculated across all wells that originated from the same initial sample (Figure 16).

  As wells are scored positive or negative, the amplification process itself is not tracked like qPCR, but instead fluorescence is measured at the end of amplification. Also in contrast to qPCR, dPCR doesn’t incorporate standards as quantification is absolute, saving time and money and removing the reliance on calibration curves. Applications of dPCR include NGS library quantification, pathogen detection and gene transcription studies, and the technique has been shown to have high sensitivity and accuracy. Rare event detection24 in clinical studies is one area in particular where dPCR has found favor over qPCR thanks to its superior sensitivity.  

Figure 16: Workflow for a dPCR experiment and result interpretation.

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