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Optimization Tips for Luna^® qPCR

New England Biolabs provides Luna products for your qPCR and RT-qPCR experiments. For RT-qPCR guidelines, please visit Optimization Tips for Luna One-Step RT-qPCR.

Target Selection

Short PCR amplicons, ranging from 70 to 200 bp, are recommended for maximum PCR efficiency
Target sequences should ideally have a GC content of 40–60%
Avoid highly repetitive sequences when possible

Use high quality, purified DNA templates whenever possible. Luna qPCR is compatible with DNA samples prepared through typical nucleic acid purification methods.
Template dilutions should be freshly prepared in either TE or water for each qPCR experiment
Generally, useful concentrations of standard and unknown material will be in the range of 10⁶ copies to 1 copy. For gDNA samples from large genomes, (e.g., human, mouse) a range of 50–1 pg of gDNA is typical. For small genomes, adjust as necessary using 10⁶–1 copy input as an approximate range. Note that for dilutions in the single-copy range, some samples will contain multiple copies and some will have none, as defined by the Poisson distribution.
To generate cDNA, use of the LunaScript^® RT SuperMix Kit (NEB #E3010) is recommended. Up to 1 µg total RNA, 1 µg mRNA or 100 ng specific RNA can be used in a 20 µl reaction.
cDNA does not need to be purified before addition to the Luna reaction but should be diluted at least 1:20 before addition to qPCR

Primers should typically be 15–30 nucleotides in length
Ideal primer content is 40–60% GC
Primer Tm should be approximately 60°C
Primer Tm calculation should be determined with NEB’s Tm calculator using the Hot Start Taq setting
For best results in qPCR, primer pairs should have Tm values that are within 3°C
Avoid secondary structure (e.g., hairpins) within each primer and potential dimerization between primers
G homopolymer repeats ≥ 4 should be avoided
Optimal primer concentration for dye-based experiments (250 nM) is lower than for probe-based experiments (400 nM). If necessary, the primer concentration can be optimized between 100–500 nM for dye-based qPCR or 200–900 nM for probe-based experiments.
Higher primer concentrations may increase secondary priming and create spurious amplification products
When using primer design software, enter sufficient sequence around the area of interest to permit robust primer design and use search criteria that permit cross-reference against relevant sequence databases to avoid potential off-target amplification.
For cDNA targets, it is advisable to design primers across known exon-exon junctions in order to prevent amplification from genomic DNA
Primers designed to target intronic regions can ensure amplification exclusively from genomic DNA

Probes should typically be 15–30 nucleotides in length to ensure sufficient quenching of the fluorophore
The optimal probe concentration is 200 nM but may be optimized between 100 to 500 nM
Both single or double-quenched probes may be used
In general, non-fluorescence quenchers result in better signal-to-noise ratio than fluorescence quenchers
Ideal probe content is 40–60% GC
The probe Tm should be 5–10°C higher than the Tm of the primers to ensure all targeted sequences are saturated with probe prior to amplification by the primers
Probes may be designed to anneal to either the sense or antisense strand
Generally, probes should be designed to anneal in close proximity to either the forward or reverse primer without overlapping
Avoid a 5´-G base which is known to quench 5´-fluorophores

Avoid primer/probe combinations that contain complementary sequences, and ensure target sequences do not overlap
Probes should be designed such that each amplicon has a unique fluorophore for detection
Select fluorophores based on the detection capabilities of the available real-time PCR instrument
The emission spectra of the reporter fluorophores should not overlap
Test each primer/probe combination in a singleplex reaction to establish a performance baseline. Ensure C_q values are similar when conducting the multiplex qPCR.
Pair dim fluorescence dyes with high abundance targets and bright dyes with low abundance targets
Optimization may require lower primer/probe concentrations to be used for high copy targets along with higher concentrations for low copy targets

Generally, best performance is achieved using the cycling conditions provided in the manual
Longer amplicons (> 400 bp) can be used but may require optimization of extension times
Due to the hot start nature of the polymerase, it is not necessary to preheat the thermocycler prior to use
Select the “Fast” ramp speed where applicable (e.g., Applied Biosystems QuantStudio^®)
Amplification for 40 cycles is sufficient for most applications, but for very low input samples 45 cycles may be used

For best results, keep reactions on ice prior to thermocycling
A reaction volume of 20 µl is recommended for 96-well plates while a reaction volume of 10 µl is recommended for 384-well plates
Reactions should be carried out in triplicate for each sample
For each amplicon, ensure to include no template controls (NTC)
To prevent carry-over contamination, treat reactions with 0.025 units/µl Antarctic Thermolabile UDG (NEB #M0372) for 10 minutes at room temperature prior to thermocycling
A universal passive reference dye is included in the following Luna® qPCR products: Luna Universal qPCR Master Mix (NEB #M3003), Luna Universal Probe qPCR Master Mix (NEB #M3004), Luna Universal One-Step RT-qPCR Kit (NEB #E3005), and Luna Universal Probe One-Step RT-qPCR Kit (NEB #E3006). These products support broad instrument compatibility (High-ROX, Low-ROX, ROX-independent) so no additional ROX is required for normalization.

The Luna Probe One-Step RT-qPCR Kit (No ROX) (NEB #E3007) contains no reference dye and is compatible with any instrument that does not require ROX. If ROX normalization is needed, ROX can be added. Please refer to instrument manufacturer’s instructions for details.

Ensure 90–110% PCR efficiency for the assay over at least three log₁₀ dilutions of template
Linearity over the dynamic range (R^₂) should ideally be ≥ 0.99
Target specificity should be confirmed by product size, sequencing or melt-curve analysis

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