GreenMasterMix (2X) ohne ROX für die qPCR



Artikel-Nr.: M3023.0100

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Green qPCR Mastermix ohne ROX optimiert für die qPCR/realtime PCR in Blockgeräten. Der Green... mehr
Produktinformationen "GreenMasterMix (2X) ohne ROX für die qPCR"

Green qPCR Mastermix ohne ROX optimiert für die qPCR/realtime PCR in Blockgeräten. Der Green qPCR Mastermix ohne ROX enthält einen interkalierenden Fluoreszenzfarbstoff und alle notwendigen Komponenten in einer optimierten Menge, um eine quantitative PCR durchzuführen.

Vorteile der im Genaxxon GreenMasterMix eingesetzten chemisch modifizierten SuperHot Taq-Polymerase:

  • Hotstarttechnologie für das Setup bei Raumtemperatur
  • Kein Pipettieren auf Eis notwendig
  • Kein sofortiges Weiterbearbeiten (PCR) notwendig. Die pipettierten PCR-Ansätze können bis zu 3 Tagen bei RT stehengelassen werden.
  • Amplifikation auch von GC-reichen Templates
  • Hohe Ausbeute
  • Keine Primerdimerbildung

Die Genaxxon SuperHot Taq DNA-Polymerase bietet Komfort und Praktikabilität für konstante Effizienz und Spezifität:
1. Sie inhibiert die Polymerase bei niedrigen Temperaturen und verhindert so zuverlässig unspezifische PCR-Reaktionen. Daher muss das PCR Setup nicht auf Eis durchgeführt werden.
2. Dies führt dazu, dass der PCR-Ansatz bei RT (20°C bis 25°C) zusammengemischt und bis zu 3 Tage gelagert werden kann, ohne das Endergebnis zu beeinflussen (z.B. während der Mittagspause oder während des Wartens auf weitere Proben).

Der Green qPCR Mastermix ohne ROX enthält alle notwendigen Komponenten in einer optimierten Menge, um eine quantitative PCR durchzuführen.

  • chemisch modifizierte Taq DNA Polymerase
  • dATP, dCTP, dGTP, dTTP
  • interkalierender, grüner Fluoreszenzfarbstoff
  • optimierter Reaktionspuffer
  • Stabilisator und Enhancer, um sogar die Amplifikation von low copy number Targets zu ermöglichen
  • Die kleinen Aliquots von 1,25mL vereinfachen die Handhabung und die Lagerung (weniger Einfrier- und Auftauzyklen pro Aliquot).

Stabilität bei +2°C bis +8°C (Kühlschrank): Mindestens 8 Monate.

Speziell geeignet für: BioRad CFX96 Touch™, CFX384 Touch™, CFX Connect™, DNA Engine Opticon® 2, Chromo4™, iCycler iQ™ and My iQ™ , Roche LightCycler® 480, LightCycler® 1536, LightCycler® Nano, LightCycler® 96 and QuantStudio™ instruments, Thermo Scientific™ PikoReal™, Cepheid SmartCycler®, Bio Molecular Systems Mic qPCR cycler, Qiagen Rotor Gene Q, Rotor Gene 6000, MyGo Mini and MyGo Pro.

Andere realtime PCR Mastermixe von Genaxxon sind: M3023 - GreenMastermix No ROX >, M3045 - ProbeMastermix No ROX >, M3011 - GreenMastermix Low ROX >, M3031 - ProbeMastermix Low ROX >, M3052 - GreenMastermix High ROX >, M3010 - ProbeMastermix High ROX >.

Unsere Daten zeigen, dass der Genaxxon ProbeMastermix (M3045) > sowie der analoge GreenMastermix M3023 > (= M3045 mit grünem Fluoreszenzfarbstoff) vergleichbare Ergebnisse zu entsprechenden qPCR Mastermixen von Wettbewerbern liefert.

Testmuster zum Sonderpreis erhältlich! Keine Versandkosten bei Versand innerhalb Deutschlands! Der Testmusterpreis wird bei der ersten offiziellen Bestellung des Produkts zurückerstattet.

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High Sensitivity and Specifity, Optimised buffer system, Reproducibility over a wide range of template amounts, Broad dynamic range. Aliquot size: 1.25mL. This master mix is stable for at least 8 months at +2°C to +8°C.
Specifications: This realtime PCR master mix is a ready-to-use 2-time master mix that contains... mehr
 

Technische Daten:

Specifications:
This realtime PCR master mix is a ready-to-use 2-time master mix that contains no ROX™
Suited for FAST PCR with MIC Cycler

Aliquot size: 1.25mL. This master mix is stable for at least 8 months at +2°C to +8°C.

Applikation:

PCR Primer extension Multiplex PCR Low-copy targets PCR Real-time PCR Quantitative PCR

Einheitendefinition:

One unit is defined as the amount of enzyme which will convert 10 nmoles of dNTPs to an acid-insoluble form in 30 min at 72°C under the assay conditions (25 mM TAPS (tris-(hydroxymethyl)-methyl-amino-propanesulfonic acid, sodium salt) pH 9.3 (25°C); 50 mM KCl; 2 mM MgCl2; 1 mM b-mercaptoethanol; and activated calf thymus DNA as substrate.

Sicherheits Hinweise / Safety

Klassifizierungen / Classification

eclass-Nr: 32-16-05-02
Dokumente - Protokolle - Downloads mehr


Dokumente - Protokolle - Downloads

Hier finden Sie Informationen und weiterführende Literatur zu GreenMasterMix (2X) ohne ROX für die qPCR. Für weitere Dokumente (Zertifikate mit weiteren Lotnummern, Sicherheitsdatenblätter in anderer Sprache, weitere Produktinformationen) wenden Sie sich bitte an Genaxxon biosience unter: info@genaxxon.com oder Tel.: +49 731 3608 123.

 
 
 
Dokumente - Protokolle - Downloads mehr

Dokumente - Protokolle - Downloads

Fast PCR:

When performing fast real-time PCR, it is of high importance to consider primer design and target size. For efficient amplification during fast cycling conditions, target size between 70 bp and 200 bp is recommended. The shorter the target length,  the faster the total run time. For other targets and other primer sets, the annealing step has to be determined experimentally.

Please use the following protocol for inspiration as you need to optimize instruments settings according to yourr target size and applied instruments.

Fast real-time PCR results using Genaxxon Master Mixes (without ROX) on LightCycler® 96

GreenMasterMix (2X) without ROX or ProbeMasterMix (2X) without ROX was tested on LighCycler96 (Roche) using fast cycling real-time 2-step protocols; Fast PAH12 Green LC and Fast Pthr Probe LC, respectively.
qPCR Setup: GreenMasterMix (2X) (without ROX) or ProbeMasterMix (2X) (without ROX), primers targeting either PAH12 (203 bp) or Pthr (75 bp) and 4 concentrations of gDNA (40 ng, 20 ng, 10 ng and 5 ng) were used. All DNA concentrations were tested in quadruple replicates. See fig. 1 and 2. The PCR reaction mix was run on LightCycler® 96 (No requirements for ROX). Instrument settings, run times and quality criteria for the applied fast protocols; Fast PAH12 Green LC and Fast Pthr Probe LC, were compared to the standard protocol; Standard Pthr LC. See table 1.

Results: The standard Fast Pthr Probe LC protocol has a run time of 80.8 minutes. Fast PAH12 Green LC and Fast Pthr Probe LC protocols, resulted in run times of 47.5 and 40.8 minutes, respectively. All protocol times are inclusive ramping time and a15 minutes hot start. The determined criteria, as shown in table 1, for Fast PAH12 Green LC and Fast Pthr Probe LC protocols were satisfying. Furthermore, the melt curve analysis using Green 2x Master Mix without ROX the Fast PAH12 Green LC protocol confirmed high specificity.

 
 
 
Literatur .... mehr

Referenzen..

Hier finden Sie Artikel und Literaturzitate, in denen die Autoren auf die hohe Qualität dieses Genaxxonprodukts vertrauen.
Listed below are articles and references, in which the authors trust in the high quality of this Genaxxon product.

Quelle/Source: NCBI PubMed >

Keratinocyte-derived IκBζ drives psoriasis and associated systemic inflammation
Sebastian Lorscheid, Anne Müller, Jessica Löffler, Claudia Resch, Philip Bucher, Florian C. Kurschus, Ari Waisman, Knut Schäkel, Stephan Hailfinger, Klaus Schulze-Osthoff, Daniela Kramer
JCI Insight. 2019 Nov 14; 4(22): e130835. Published online 2019 Nov 14. doi: 10.1172/jci.insight.130835
PMCID: PMC6948851

Long Noncoding RNA SSR42 Controls Staphylococcus aureus Alpha-Toxin Transcription in Response to Environmental Stimuli
Jessica Horn, Maximilian Klepsch, Michelle Manger, Christiane Wolz, Thomas Rudel, Martin Fraunholz
J Bacteriol. 2018 Nov 15; 200(22): e00252-18. Prepublished online 2018 Aug 27. Published online 2018 Oct 23. doi: 10.1128/JB.00252-18
PMCID: PMC6199474

MiR-744-5p inducing cell death by directly targeting HNRNPC and NFIX in ovarian cancer cells
Michael Kleemann, Helga Schneider, Kristian Unger, Philip Sander, E. Marion Schneider, Pamela Fischer-Posovszky, René Handrick, Kerstin Otte
Sci Rep. 2018; 8: 9020. Published online 2018 Jun 13. doi: 10.1038/s41598-018-27438-6
PMCID: PMC5998049

miR-217-5p induces apoptosis by directly targeting PRKCI, BAG3, ITGAV and MAPK1 in colorectal cancer cells
Marion Flum, Michael Kleemann, Helga Schneider, Benjamin Weis, Simon Fischer, René Handrick, Kerstin Otte
J Cell Commun Signal. 2018 Jun; 12(2): 451–466. Published online 2017 Sep 14. doi: 10.1007/s12079-017-0410-x
PMCID: PMC5910322

 
 
 
FAQ
Fragen & Antworten zum Artikel ... mehr
Why do I need a Hot Start Polymerase for a qPCR?
The Hot Start-modification of the polymerase inhibits its enzymatic activity at low temperatures and prevents non-specific amplifications in the first PCR cycles, which can drastically affect the qPCR results.
What is the Ct or Cq value?
The Ct (Threshold Cycle) value in qPCR is a measure of gene expression and is determined based on the fluorescence curve. The 2nd derivative method is used to determine the maximum change in the second derivative of the fluorescence curve - i.e. the point at which the fluorescence change no longer increases - and thus the exponential amplification is terminated. The cycle in which this is the case is called the "quantification cycle (Cq)". Please note that the calculation of the Cq value can also be done by other methods. It is important that you always use the same method for your experiment.
What is ROX?
ROX (5-Carboxy-Rhodamin-X) is a fluorescent dye that some qPCR machines use as a passive reference dye. This is done to account for fluorescence variations between wells, which can result from factors like material inconsistencies or imprecise pipetting. In general, it's advisable to take advantage of this normalization option whenever possible. It's essential to determine whether your system requires a low (low ROX) or high (high ROX) concentration of ROX. However, if your cycler lacks a ROX option, there's no need to be concerned. A well-optimized qPCR typically doesn't require additional normalization through a passive dye. Genaxxon provides qPCR master mixes with ROX concentrations that range from none to low or high, catering to all your needs.
How can I calculate primer efficiency?
It's essential to determine primer efficiency for every gene you're analyzing. To do this, create a cDNA dilution series covering a range of 5-6 orders of magnitude and record Cq values for different primer concentrations. You can calculate the primer efficiency from the slope of the resulting line, aiming for it to be within the range of 85% to 110%.
Do qPCR plates and foils influence the assay performance?
Yes, the used plates and foils could influence the assay performance according to several scientific studies (e.g. Reiter and Pfaffl 2008: Effects of Plate Position, Plate Type and Sealing Systems on Real-Time PCR Results, Biotechnology & Biotechnological Equipment, 22:3, 824-828, DOI: 10.1080/13102818.2008.10817561). In general, white qPCR plates (e.g. Genaxxon’s I2017) have a lower light scattering and thus a higher signal strength than transparent qPCR plates (e.g. Genaxxon’s I2004, I2010, I2031). If you have a weakly expressed target or a only small amounts of sample material, we recommend using a white qPCR plate. Beside this, it is essential to use optically clear foils for your qPCR. We do not recommend using “normal” PCR foils as adhesive residues and transparency differences in the material may lead to inhomogeneity during your qPCR assay. Genaxxon offers different qPCR foils: a strongly adhesive foil (I2012) that securely seal the plate immediately, and a pressure-sensitive foil (I2248) that adheres to the plate by applying strong pressure.
What are TaqMan Probes?
TaqMan® probes are hydrolysis probes used in qPCR for measuring DNA levels. Hydrolysis probes are single-stranded DNA oligonucleotides labeled with a fluorescent marker at one end and a quencher at the other. The quencher is a molecule that suppresses the fluorescence of the marker when they are in close proximity. When the probe binds to the DNA target and the polymerase initiates amplification, its exonuclease activity cleaves both the fluorescent marker and the quencher. This action removes the quencher's inhibitory effect. Since this process repeats in every cycle, the strength of the fluorescence signal, measured after excitation, is directly proportional to the amount of amplified DNA.
When should I use TaqMan probes, and when should I opt for SYBRGreen?
Hydrolysis probes (TaqMan) excel in applications such as SNP genotyping, splice variant analysis, and mutation detection using qPCR. In contrast, SYBRGreen-based assays are ideal for gene expression or miRNA expression analysis and offer additional advantages, including quality metrics like melting curve analysis. Several scientific studies suggest that a properly optimized SYBRGreen assay is as effective as a hydrolysis probe (TaqMan) for gene expression analysis (e.g., Tajadini et. al. 2014: Comparison of SYBR Green and TaqMan® methods in quantitative real-time polymerase chain reaction analysis of four adenosine receptor subtypes, Advanced Biomedical Research, 3, 85, DOI: 10.4103/2277-9175.127998). Key factors for success in both cases include selecting appropriate primers, optimizing the qPCR master mix, and ensuring high-quality, non-fragmented cDNA, which is crucial for TaqMan® probes as well. Please not that the performance of a qPCR assay utilizing (TaqMan) probes is heavily influenced by the amplicon length, affecting its robustness, sensitivity, and specificity. In contrast, an assay with SYBRGreen demonstrates greater tolerance for variations in amplicon lengths.
How can I check the specificity of my qPCR assay?
To confirm specificity, you can perform post-qPCR analysis by either running the reaction mix on an agarose gel or, if you're using SYBRGreen, generating a melting curve. These methods will quickly indicate the presence of any unintended byproducts.
What controls are essential in qPCR?
Just like any experiment, it's crucial to include the right controls in every qPCR assay. Depending on the assay format, we recommend the following controls: 1. No Template Control (NTC): For every gene being analyzed, it's important to incorporate an NTC (simply using water instead of a template). NTCs play a critical role in detecting cross-contamination and should be a standard part of every qPCR. 2. Reference Genes (formerly known as Housekeeping Genes): To ensure a robust gene expression analysis, it's a good practice to include multiple reference genes for each sample. These reference genes should exhibit stable expression regardless of any treatment, serving as reference points for subsequent relative quantification. 3. Alternative Positive Control: In cases where you're performing absolute quantifications and not using reference genes, including an alternative positive control is recommended. This control should consistently yield a known result in all scenarios. 4. noRT Control: If you're using reverse transcription (RT) from mRNA as the template, it's advisable to have a noRT control with a sample that lacks the enzyme.
Do I need to do a melting curve analysis?
Please note that a melting curve analysis is only possible when doing a qPCR with intercalating dyes, e.g. SYBRGreen, but not with probes. The melting curve can be used to determine the specificity of a qPCR and to detect any by-products that may occur. It is therefore strongly recommended to perform a melting curve analysis for every qPCR when using an intercalating dye. To generate the melting curve, the qPCR cycler continuously increases the temperature and simultaneously measures the fluorescence. This drops as soon as the melting temperature of the amplicon produced during qPCR is exceeded. Why? When the product melts, the intercalating dye is released, causing the fluorescence signal to drop. Usually, the melting curve is not shown directly as a fluorescence curve, but as a function of the change in fluorescence. A large change in fluorescence is represented as a peak (amplicons denature in this area). Please note that a qPCR always shows only a single peak. Multiple peaks are - with the exception of multiplex assays! - a clear indication of unwanted by-products. These can, under certain circumstances, completely falsify the result and make it unusable. Please note: When changing your master mix, the peak of a melting curve may shift. Why? The melting temperature also depends on the buffer used in the master mix, especially on the salt concentration. As different master mixes may use different buffer, it is quite likely that the resulting melting curve differs.
What is the optimal primer concentration?
The concentration of primers plays a crucial role in qPCR performance and should be carefully optimized. Having a primer concentration that is too high or too low can negatively impact the calculation of the Cq value and may even encourage the formation of primer dimers (see e.g., Mikeska and Dobrovic 2009: Validation of a primer optimisation matrix to improve the performance of reverse transcription – quantitative real-time PCR assays, BMC Research Notes, 2, 112, DOI: 10.1186/1756-0500-2-112). As a general guideline, you can initiate with a primer concentration of 100-200 nM. However, it's important to conduct test assays with both higher and lower concentrations to identify the optimal range.
How can I calculate primer efficiency?
It's essential to determine primer efficiency for every gene you're analyzing. To do this, create a cDNA dilution series covering a range of 5-6 orders of magnitude and record Cq values for different primer concentrations. You can calculate the primer efficiency from the slope of the resulting line, aiming for it to be within the range of 85% to 110%.
How much template do I need for my qPCR?
The precise amount of template required for a specific qPCR is contingent on various factors. Excessive template can potentially inhibit the qPCR. In a typical qPCR, the range for template usage per reaction falls between 1 and 10 ng. Therefore, when initiating qPCR optimization, it's highly recommended to establish a template dilution series covering 5 to 6 orders of magnitude. This step is vital for determining the optimal template quantity. This dilution series assists in determining the primer efficiency, the potential for qPCR inhibition by the template, and the verification of whether the template quantity falls within the qPCR's linear range. Once these parameters are established, you can confidently select a template quantity that aligns with the linear range of the qPCR.
My qPCR assay is not as specific as it should be. What can I do?
The specificity of a qPCR assay depends on several factors, including primer concentration, the melting temperature of the primers, annealing temperature and time, and the potential formation of primer dimers. If your qPCR assay lacks the desired specificity, we recommend the following: 1. Reduce the primer concentration. 2. Increase the annealing temperature (while ensuring it doesn't exceed the melting temperature of the primers). 3. Shorten the annealing time. If none of these measures prove effective, consider redesigning the primers, exploring various options for length, melting temperature, and sequence.
When using SybrGreen as a fluorescent dye, my quantification is not accurate. What can I do?
SybrGreen has only a low specificity. It binds to double-stranded DNA during PCR cycles, even to potentially non-specific reaction products. This leads to inaccurate qPCR results with non-optimised protocols. To obtain more specific results, probe-based qPCR should be performed.
With the qPCR master mix from Genaxxon I get a different Ct value than with my previous master mix. What can I do?
The master mixes from different manufacturers have different compositions, including the buffers. Some assays react sensitively to these variations, so that different results are possible. Therefore, a calibration is always necessary when changing the master mix. If you have further questions, please contact our technical support: info@genaxxon.com.
The qPCR master mix does not work with the specified protocol. What can I do?
The protocols provided by Genaxxon are standard protocols. In order to obtain optimal specificity and amplification, individual optimisation of the experimental conditions is recommended. If you have further questions about this, please feel free to contact our technical support: info@genaxxon.com.
Do I need to add ROX when using Genaxxon’s qPCR master mixes?
Depending on the qPCR instrument you’re using, you may need to use a passive reference dye, typically ROX, to overcome variations between wells caused by the machine limitations. Therefore, Genaxxon offers qPCR master mixes with either no or low and high amounts of the passive reference dye RO to ensure compatibility with a variety of qPCR instruments. If you have any problems choosing the right master mix for your application, please contact our technical support: info@genaxxon.com.
Can I use a fast protocol of my instrument settings with Genaxxon’s qPCR master mixes?
Genaxxon offers different qPCR master mixes optimised for fast qPCR assays. Depending on your needs, Genaxxon offers master mixes for fast qPCR assays with (GreenMasterMix FAST) or without (ProbeMasterMix FAST) a fluorescence dye and with no (No ROX) or a passive reference dye with different concentrations (Low ROX or High ROX). If you have any problems choosing the right master mix for your application, please contact our technical support: info@genaxxon.com.
Can I easily switch to another qPCR master mix during my project?
Yes, you can switch to another qPCR master mix during your project or even in the middle of your experiment! You only need to perform a normalization of your qPCR beforehand. Please note that we generally recommend normalization for any qPCR. Also, check if you need to adjust the settings on your PCR cycler when changing the master mix.
Can I run multiplex reactions with the Genaxxon qPCR master mixes?
Yes, all qPCR master mixes from Genaxxon can be used for multiplex applications. However, for easy and fast optimization of your multiplex reaction, we recommend using one of our specially designed multiplex master mixes, e.g., 5X qPCR Multiplex MasterMix (M3024), Multiplex HS MasterMix (2X) (M3013) or the lyophilized LyoPlex Multiplex PCR master mix (M3005).