Protein Thermal Shift™ Software v1.4
Protein Thermal Shift™ Software v1.4
Applied Biosystems™

Protein Thermal Shift™ Software v1.4

The Protein Thermal Shift Software v1.4 was developed to analyze protein melt fluorescent readings directly from Applied Biosystems™ real-time PCRRead more
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Catalog NumberIncludes
4466038
4466037
Catalog number 4466038
Price (USD)
2,690.00
Each
Add to cart
Price (USD)
2,690.00
Each
Add to cart

The Protein Thermal Shift Software v1.4 was developed to analyze protein melt fluorescent readings directly from Applied Biosystems™ real-time PCR instrument files. Different proteins will have different Protein Thermal Shift profiles, each with a unique protein melt curve shape, slope, signal-to-noise ratio, and temperature melt range (see figure at right for an example). The Protein Thermal Shift Software generates one or multiple melting temperature values (Tm) from these curves by two methods: the Boltzmann-derived Tm and the Derivative Curve-determined Tm, to serve as points of comparison between the curves and represent the relative thermal stability of the protein under different testing conditions.

Two Methods for Generating Tm Value
The Boltzmann method fits the data within an automatic (or manually) identified melt region to the two-state Boltzmann model to generate the Tm. Typically, for proteins with a single melt domain, the Boltzmann method is used. However, for proteins with multiple melt domains, the Derivative Curve method can be used. The Derivative Curve method uses a numerically-computed second derivative of the raw data to estimate the temperatures where up to six peaks (local maxima) may occur in the derivative profile. An empirically-derived threshold on the signal-to-noise ratio is used to determine which local maxima will be detected.

Compatible with our Real-Time PCR Systems
The Protein Thermal Shift analysis software is compatible with run files generated from these real-time PCR systems: QuantStudio 1, 3, 5, 6 Flex, 6 Pro, 7 Flex, 7 Pro, and 12K Flex, StepOne, StepOnePlus, 7500, 7500 Fast, and ViiA 7.

Prepare Your Samples Using our Protein Thermal Shift™ Kits
Prepare your samples for analysis using our Protein Thermal Shift Starter Kit or Protein Thermal Shift Dye Kit (available separately). These kits allow users to employ a dye that binds to exposed hydrophobic residues to monitor the thermal stability of proteins using a real-time PCR instrument to identify buffer conditions that stabilize the protein of interest or screen libraries of ligands for compounds that bind the protein of interest.

For Research Use Only. Not for use in diagnostic procedures.
Specifications
For Use With (Equipment)7500 Fast System, 7500 System, QuantStudio™ 12 k Flex, QuantStudio™ 1, QuantStudio™ 3, QuantStudio™ 5, QuantStudio™ 6 Flex, QuantStudio™ 7 Flex, StepOne™, StepOnePlus™, ViiA™ 7 System, QuantStudio™ 6 Pro, QuantStudio™ 7 Pro
Product LineProtein Thermal Shift™
Software TypeProtein Thermal Shift Analysis Software
Product TypeSoftware
For Use With (Application)Real Time PCR (qPCR)
Operating SystemWindows 7 (Service Pk. 2)
LicenseStatic
Unit SizeEach
Contents & Storage
License

Frequently asked questions (FAQs)

In the Protein Thermal Shift Assay, my replicates have different levels of fluorescence. Is this a problem?

We recommend looking at the spread in Tm, which is more important than the relative fluorescence.

What can I do for a protein that starts out high and then shows a region of melt (flattening of the curve, but no real rise in signal) when performing a Protein Thermal Shift assay?

Some proteins have hydrophobic residues on the surface and the dye binds to these residues. Heating results in unfolding of the protein causing more hydrophobic residues to be exposed. The dyes bind preferentially to these inner locations and so there is a flattening (or a very low rise) of the melt discernable in the melt profile. If there is no positive slope, you will not get a Boltzmann Tm, but you should still get a derivative one. And you can always draw a manual region to get a Tm out. Some proteins will not work with this technology if the hydrophobic residues are already exposed on the surface and the dye binds strongly to it. Please contact Technical Support at techsupport@thermofisher.com about the possibility of other dyes being available for this issue.

I am getting an error message when I try to open my *.eds data file in the Protein Thermal Shift Software? What should I do?

Make sure that you first open the file in the corresponding instrument software, click “Analyze”, and then save the file, before trying to open with the Protein Thermal Shift Software. The file must first be analyzed before it can be used in the Protein Thermal Shift Software.

The software allows for data from different plates to be analyzed together, what should be considered when mixing data from multiple plates?

The software will allow for ≥100 plates per study. We allow the user this flexibility but do not recommend you mix data from multiple plates unless they have validated their results in advance. At a minimum, we recommend researchers include a reference assay in each plate to ensure reproducibility.

Which analysis method should I choose? The Boltzmann fit or the derivative method?

We provide two independent methods because they each have unique things to offer in terms of the analysis. The two-state Boltzmann model has a physical meaning and appeal. It also provides a great way to normalize across noisy undulations in the signal. However, those undulations may be of actual interest and not noise, such as for multi-domain proteins where they may correspond to different domains coming apart in stages. Here the two-state model is inappropriate. The derivative method can help get a temperature at which the local peaks occur. These are two completely unrelated approaches. If the two-state model is a great fit for your data, the results should be in close agreement.

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