QuantiFast Multiplex RT-PCR Kits

For fast, multiplex, one-step qRT-PCR using sequence-specific probes for gene expression analysis

Products

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QuantiFast Multiplex RT-PCR +R Kit (2000)

Cat. No. / ID:  204956

For 2000 x 25 µl reactions: 25 ml 2x QuantiFast Multiplex RT-PCR Master Mix (without ROX dye), 500 µl QuantiFast RT Mix, 1.05 ml ROX Dye Solution, 1 x 20 ml RNase-Free Water
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QuantiFast Multiplex RT-PCR Kit (400)

Cat. No. / ID:  204854

IMPORTANT NOTE: As announced earlier, the production of this kit has been discontinued since mid-2021. Hence, this product will be available only until stocks last.   For 400 x 25 µl reactions: 3 x 1.7 ml 2x QuantiFast Multiplex RT-PCR Master Mix (with ROX dye), 100 µl QuantiFast RT Mix, 2 x 2 ml RNase-Free Water
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This kit is being phased out. We recommend switching to the QuantiNova successor product. For more information and FAQs on this transition, visit: www.qiagen.com/PCRresource.

Features

  • Sensitive detection of multiple RNA targets in 1 well
  • Faster results with time savings of up to 50%
  • Successful multiplex RT-PCR without the need for optimization
  • Precise discrimination of small differences in target amount
  • Detection of reference gene and up to 3 targets in the same tube

Product Details

QuantiFast Multiplex RT-PCR Kits enable fast and reliable quantification of up to 4 RNA targets in a single tube by multiplex, real-time one-step RT-PCR. A special blend of reverse transcriptases delivers fast and efficient cDNA synthesis. Q-bond technology and an optimized master mix promote fast, multiplex real-time RT-PCR, not only on fast cyclers with short ramping times, but also on standard cyclers. The combination of a hot start and a unique PCR buffer system in the ready-to-use master mix ensures highly sensitive qPCR on any real-time cycler without the need for optimization. Two kit formats are available: the QuantiFast Multiplex RT-PCR Kit for cyclers that require ROX dye for fluorescence normalization, and the QuantiTect Multiplex RT-PCR +R Kit for all other cyclers. For convenience, the master mix can be stored at 2–8°C.

IMPORTANT NOTE: As announced earlier, the production of the QuantiFast Multiplex RT-PCR Kit (400) and the QuantiFast Multiplex RT-PCR +R Kit (400) has been discontinued since mid-2021. Hence, these products will be available only until stocks last. Visit the product page of the successor kit to view improved features or to request a trial kit.

The QuantiFast Multiplex RT-PCR +R Kit (2000) will remain available.

For more information and FAQs on this transition, visit: www.qiagen.com/PCRresource.

Performance

QuantiFast Multiplex RT-PCR Kits reduce RT-PCR run times by up to 50%, allowing you to get results significantly faster (see figure " Significantly reduced RT-PCR times"). You can also greatly increase your sample throughput or efficiently share a cycler with other users. Amplifying control and target genes in the same reaction, instead of in separate reactions, increases the reliability of gene quantification by minimizing handling errors (see figure " Reliable relative quantification"). The special master mix supplied with QuantiFast Multiplex RT-PCR Kits allows rapid setup of multiplex reactions and delivers successful results at the first attempt, providing multiplex RT-PCR data that are comparable with singleplex RT-PCR data (see figure " Comparable results in triplex and singleplex RT-PCR").

QuantiFast Multiplex RT-PCR Kits can clearly distinguish between small differences in the amount of template. Even with two-fold differences in template amount, the kits provide accurate quantification of targets of widely differing abundance. Fast results in multiplex, real-time RT-PCR of up to 4 targets are achieved without compromising performance (see figure " Uncompromised sensitivity in 4-plex RT-PCR").

See figures

Principle

QuantiFast Multiplex RT-PCR Kits deliver highly sensitive and rapid results over a wide dynamic range on both standard and fast cyclers without optimization (see flowchart "  QIAGEN multiplex kits"). The specially developed fast PCR buffer contains the novel additive Q-Bond, which significantly reduces denaturation, annealing, and extension times (see figure " Fast primer annealing").

Amplifying reference and target genes in the same reaction instead of in separate reactions increases the reliability of gene quantification by minimizing handling errors. The QuantiFast Multiplex RT-PCR Buffer includes a balanced combination of K+ and NH4+ ions to promote specific primer annealing, while unique Factor MP stabilizes specifically bound primers (see figure " Unique PCR buffer"). In addition, an optimized mix of reverse transcriptases provides efficient cDNA synthesis in just 20 minutes, while HotStarTaq Plus DNA Polymerase provides a stringent hot start, preventing the formation of nonspecific products.

Components of 2x QuantiFast Multiplex RT-PCR Kit
Component Features Benefits
HotStarTaq Plus DNA Polymerase 5 min activation at 95ºC Set up of qPCR reactions at room temperature
QuantiFast Multiplex RT-PCR Buffer Balanced combination of NH4+ and K+ ions Specific primer annealing ensures reliable PCR results
Synthetic Factor MP Reliable multiplexing analysis of up to 4 genes in the same tube
Unique Q-Bond additive Faster PCR run times, enabling faster results and more reactions per day
ROX dye Normalizes fluorescent signals on Applied Biosystems and, optionally, Agilent instruments Precise quantification on cyclers that require ROX dye. Does not interfere with PCR on any real-time cycler
QuantiFast RT Mix Special blend of reverse transcriptases with high affinity for RNA RNA can be transcribed in just 20 minutes, even through complex secondary structures
See figures

Procedure

QuantiFast Multiplex RT-PCR Kits contain ready-to-use master mixes that eliminate the need for optimization of reaction and cycling conditions. Simply add template RNA and primer-probe sets to the master mix and follow the protocol in the handbook to get fast and reliable results on any real-time cycler. Kits are available with or without ROX passive reference dye in the master mix, enabling use on virtually any real-time cycler (see table). Due to the optimized ROX concentrations, detection of even low copy numbers is achieved through automatic data analysis.

Choosing the right QuantiFast Multiplex RT-PCR Kit
ROX dyeKit Compatible cyclers
Supplied in master mix QuantiFast Multiplex RT-PCR Kit All cyclers from Applied Biosystems except Applied Biosystems 7500
Supplied in separate tube QuantiFast Multiplex RT-PCR +R Kit Applied Biosystems 7500 and cyclers from
Bio-Rad, Cepheid, Eppendorf, QIAGEN, Roche, Agilent, and other suppliers

Applications

QuantiFast Multiplex RT-PCR Kits can be used for multiplex gene expression analysis of RNA targets on any real-time cycler. This includes instruments from Applied Biosystems, Bio-Rad, Cepheid, Eppendorf, Roche, and Agilent. For the Rotor-Gene Q and other Rotor-Gene cyclers, we recommend using the Rotor-Gene Multiplex RT-PCR Kit, which has been specially developed for fast cycling on these instruments.

Supporting data and figures

Specifications

FeaturesSpecifications
ApplicationsReal-time quantification of RNA targets in a multiplex format
Reaction typeReal-time one-step RT-PCR
Single or multiplexMultiplex
SYBR Green I or sequence-specific probesSequence-specific probes
Real-time or endpointReal-time
Thermal cyclerReal-time cyclers dedicated for multiplex PCR (e.g., most Applied Biosystems real-time PCR cyclers, Roche LightCycler 480, and Bio-Rad iCycler iQ)
Sample/target typeRNA
With or without ROXAvailable with ROX in master mix or with ROX as separate vial

Resources

Safety Data Sheets (2)
Download Safety Data Sheets for QIAGEN product components.
Quick-Start Protocols (2)
Kit Handbooks (1)
For quantitative, multiplex, real-time one-step RT-PCR with fast cycling using sequence-specific probes
Certificates of Analysis (1)

FAQ

How do I setup and validate a multiplex PCR assay with QIAGEN PCR kits?

Ensure PCR amplicons are as short as possible, ideally 60–150 bp. Always use the same algorithm or software to design the primers and probes. For optimal results, only combine assays that have been designed using the same parameters.

 

Check the functionality of each set of primers and probes in individual assays before combining the different sets in the multiplex assay. Choose compatible reporters and quenchers based on a specific instrument. See How do I select appropriate reporter and quencher combinations for multiplex PCR.

 

FAQ ID -9093
What is the maximum number of targets that can be amplified per reaction with the QuantiFast Multiplex RT-PCR Kit?

We have successfully tested up to 4 targets per reaction with the QuantiFast Multiplex RT-PCR Kit. A higher degree of multiplexing is achievable only on a limited number of PCR instruments (e.g., LightCycler 2.0). For these rare applications, further optimization of primer–probe concentration, cycling protocol, etc., might be needed.

 

 

FAQ ID -2145
Do you have any information or guidelines regarding the choice of reference genes for real-time PCR?

Yes, please visit our website section 'Using endogenous control genes in real-time RT-PCR' for general information. It provides a list of relative gene expression levels for commonly used human and mouse reference genes.

We offer a set of ready-to-order control genes for use in SYBR Green based as well as probe based real-time RT-PCR.

In addition, you may want to refer to the following citations on reference gene selection for quantitative real-time PCR:

• Vandesompele J, De Preter K, Pattyn F, Poppe B, Van Roy N, DePaepe A, Speleman F [2002]: Accurate normalization of real-time quantitative RT-PCR data by geometric averaging of multiple internal control genes. Genome Biol 2002, 3:0034.

• Radonic A, Thulke S, Mackay IM, Landt O, Siegert W, Nitsche A., 2004. Guideline to reference gene selection for quantitative real-time PCR. Biochem Biophys Res Commun. 313(4): 856-62.

• Katrien Smits,Karen Goossens, Ann Van Soom, Jan Govaere, Maarten Hoogewijs, Emilie Vanhaesebrouck,Cesare Galli, Silvia Colleoni, Jo Vandesompele, and Luc Peelman [2009]Selection of reference genes for quantitative real-time PCR in equine in vivo and fresh and frozen-thawed in vitro blastocysts. BMC Res Notes. Dec 11;2:246.

FAQ ID -2371
Why do replicates in real-time PCR have different plateau heights?

Replicates in real-time PCR may have different plateau heights due to differences in the reaction kinetics for each sample. Even though replicates start out with identical template amounts, the rate at which reagents are being depleted, and the point when exponential accumulation of PCR product stops and becomes linear, differ between replicates. This will result in different plateau heights, the stage where PCR reactions have come to a halt, and little or no additional PCR product is being amplified. You can find further information in Chapter 'Quantification of target amounts' of our Brochure "Critical Factors for Successful Real-Time PCR".

 

FAQ ID -539
Why are the denaturation and annealing/extension times for QuantiFast Multiplex RT-PCR Kits much shorter than those for QuantiFast Multiplex PCR Kits?

The QuantiFast Buffer in the QuantiFast Multiplex RT-PCR Kit has been further optimized to enable fast multiplex one-step RT-PCR.

 

 

 

FAQ ID -2147
Can I use uracil-N-glycosylase (UNG) with the QuantiFast and Rotor-Gene PCR kits?

No. UNG treatment does not provide any advantage for the QuantiFast and Rotor-Gene PCR kits because the mastermixes do not contain dUTP. Use the QuantiTect kits if you intend to use the UNG treatment.

FAQ ID -9092
Why do I see multiple high-intensity peaks in my qPCR dissociation curve at temperatures less than 70ºC?

If the extra peaks seem irregular or noisy, do not occur in all samples, and occur at temperatures less than 70 ºC, then these peaks may not represent real PCR products and instead may represent artifacts caused by instrument settings.

 

Usually extra peaks caused by secondary products are smooth and regular, occur reproducibly in most samples, and occur at temperatures greater than 70 ºC. Characterization of the product by agarose gel electrophoresis is the best way to distinguish between these cases. If only one band appears by agarose gel then the extra peaks in the dissociation curve are instrument artifacts and not real products. If this is the case, refer to the thermal cycler user manual, and confirm that all instrument settings (smooth factor, etc.) are set to their optimal values.

 

FAQ ID -90990
How do I quantify gene expression levels if the amplification efficiencies are different between the genes of interest and endogenous reference gene?

The REST 2009 (Relative Expression Software Tool) software applies mathematic models that compensate for the different PCR efficiencies of the gene of interest and reference genes. In addition, the software can use multiple reference gene normalization to improve the reliability of result, as well as provides statistical information suitable for robust comparison of expression in groups of treated and untreated. QIAGEN offers the REST 2009 software free of charge.

FAQ ID -9095
How important is the RNA purification process, for obtaining reliable qRT-PCR results?

The most important prerequisite for any gene expression analysis experiment is the preparation of consistently high-quality RNA from every experimental sample. Contamination by DNA, protein, polysaccharide, or organic solvents can jeopardize the success of an experiment.

Genomic DNA contamination in an RNA sample compromises the quality of gene expression analysis results. The contaminating DNA inflates the OD reading of the RNA concentration. It is also a source of false positive signals in RT-PCR experiments.

RNase contamination degrades RNA samples whichcauses low signal and false-negative results in PCR.

Residual polysaccharides, collagen, other macromolecules, and organic solvents in an RNA sample can inhibit the activity of DNase, which may interfere with DNase treatment for genomic DNA removal. These contaminants may also inhibit reverse transcriptase and DNA polymerase, leading to lower reverse transcription efficiency and reduced PCR sensitivity.

For fast purification of high-quality RNA we recommend QIAGEN’s RNeasy Kits like the RNeasy Mini Kit, the RNeasy Plus Universal Kit, or the RNeasy FFPE Kit.

FAQ ID -2655
What is the threshold cycle or Ct value?
The Ct or threshold cycle value is the cycle number at which the fluorescence generated within a reaction crosses the fluorescence threshold, a fluorescent signal significantly above the background fluorescence. At the threshold cycle, a detectable amount of amplicon product has been generated during the early exponential phase of the reaction. The threshold cycle is inversely proportional to the original relative expression level of the gene of interest.
FAQ ID -2682
What do I do if no fluorescent signal is detected in a real-time PCR assay?

Check the template quality and integrity by amplifying an endogenous control gene. Check the amplicon by QIAxcel Advanced system or agarose gel electrophoresis to show that amplification was successful.

 

Determine whether the gene of interest is expressed in your sample. See How can I find out if my gene of interest is express in a specific tissue type or cell line.  Ensure the assay setup and cycling conditions are correct, and that the data collection channel matches the emission wavelength of the fluorescent dye used. Use a control sample in which the gene of interest is definitely expressed.

 

If the issue persists, please send the original run file to QIAGEN Technical Services.

FAQ ID -9091
What is the detection limit of the Rotor-Gene and QuantiFast Multiplex RT-PCR Kits?

The Rotor-Gene and QuantiFast Multiplex RT-PCR Kits allow reliable detection down to 10 target copies. Detection of lower copy numbers down to single copy level may also be possible; however, this depends on the stochastics when working with highly diluted samples. Additional optimization of primer/probe design is usually required.

 

 

FAQ ID -2144
How do I select appropriate reporter and quencher combinations for multiplex PCR?

For duplex analysis, using non-fluorescent quenchers (e.g., Black Hole Quencher®) is preferred over fluorescent quenchers (e.g., TAMRA fluorescent dye). For triplex and 4-plex analysis, QIAGEN strongly recommends using non-fluorescent quenchers. Generally, use the green channel, the yellow channel, and the orange and crimson channels to detect the least abundant target, the second least abundant target, and the two most abundant targets, respectively. For instrument-specific recommendations, please see the handbooks for the QuantiTect Multiplex PCR kit, QuantiFast Multiplex kit or Rotor-Gene Multiplex kit.

 

FAQ ID -9094
Can I skip the gDNA wipeout buffer treatment step for the QuantiTect Reverse Transcription Kit?

The gDNA wipeout buffer incubation step can be skipped when the total RNA is free from genomic DNA. However, the gDNA wipeout buffer is still required to be added because the reverse transcription step is optimized in the presence of components in the gDNA wipeout buffer.

FAQ ID -9098
Why does my realtime PCR assay quality decrease over time?
Make sure that template, primers, probes, and amplification reagents are stored correctly and avoid multiple freeze–thaw cycles for oligonucleotides and template. Check the performance of your real-time instrument as some instruments require the halogen lamp to be frequently replaced. Lasers must also be replaced occasionally.
FAQ ID -589
How should I handle and store absolute quantitation standards for real-time experiments?
Store the standards at a high concentration in aliquots at -20oC to -70oC. If using low concentrations, stabilize standards with carrier nucleic acid. It is always best to use freshly diluted standards for each experiment. If possible, use siliconized tubes for standard (and target) dilutions. This will prevent any unspecific binding of nucleic acids to the plastic.
FAQ ID -9099
How do I ensure reliable results for High Resolution Melting (HRM) assays?

Reliable HRM analysis results depend on template quality, highly specific HRM PCR kit with a saturation dye, a real-time instrument with HRM capability, and powerful software package. Factors critical for successful HRM analysis are:

 

  • Use the same genomic DNA purification procedure for all samples being analyzed by HRM. This avoids variation due to differing composition of elution buffers.
  • DNA template concentrations should be normalized using the same dilution buffer. Ensure the CT values are below 30 and differ no more than 3 CT values across individual samples.
  • Design assays with amplicon length 70–350 bp. For SNP analysis, use amplicon length 70–150 bp.
  • Always start with 0.7 µM primer concentration

 

For more details, please refer to the HRM Technology – FAQs and the Critical Success Factor for HRM performance.

FAQ ID -9097
Why should DNA or cDNA targets be less than 250 bp long for real-time PCR?

Shorter amplification products facilitate high PCR efficiencies. Ideally, amplicon length should be less than 150 bp for optimal amplification efficiency. PCR efficiencies close to 100% are a crucial prerequisite for accurate quantification of target copy numbers in real-time PCR.

FAQ ID-751
What are the main differences between Rotor-Gene and QuantiTect or QuantiFast PCR Kits?

Rotor-Gene Kits are specifically developed for the Rotor-Gene Q PCR Cycler. The unique rotary system of the cycler combined with the kits’ proprietary buffer system enable ultrafast cycling. Rotor-Gene Kits do not contain ROX dye since no normalization to a passive reference is required. Also, Rotor-Gene Kits do not contain dUTP; therefore, UNG pretreatment is not possible.

 

FAQ ID -2119
How do I avoid collecting a fluorescence reading from primer-dimer with the QuantiTect SYBR Green PCR Kit?

Depending on primer design and copy number of target, primer-dimer may occur and its signal might be detected. Typical strategies against this are to optimize PCR conditions and/or redesign the assay.

 

Alternatively, an additional data-acquisition step can be added to the 3-step cycling protocol. First, determine the melting temperatures (Tm) for both the amplicon and the primer-dimer. Then, add a 15 second data-acquisition step with a temperature that is higher than the primer-dimer Tm, but approximately 3ºC lower than the specific amplicon Tm.

FAQ ID -9096