1. High-Throughput Thermal Scanning: A General, Rapid Dye-Binding Thermal Shift Screen for Protein Engineering
- Author
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Jason J. Lavinder, Brandon J. Sullivan, Sanjay B. Hari, and Thomas J. Magliery
- Subjects
Protein Denaturation ,Thermal shift assay ,Circular dichroism ,Fluorophore ,Protein Conformation ,Analytical chemistry ,Molecular Probe Techniques ,Calorimetry ,Protein Engineering ,Biochemistry ,Article ,Catalysis ,Fluorescence spectroscopy ,chemistry.chemical_compound ,Colloid and Surface Chemistry ,Protein structure ,Methods ,Transition Temperature ,Fluorescent Dyes ,Protein Stability ,Chemistry ,Proteins ,General Chemistry ,Protein engineering ,Biophysics - Abstract
The low stability of natural proteins often limits their use in therapeutic, industrial, and research applications. The scale and throughput of methods such as circular dichroism, fluorescence spectroscopy, and calorimetry severely limit the number of variants that can be examined. Here we demonstrate a high-throughput thermal scanning (HTTS) method for determining the approximate stabilities of protein variants at high throughput and low cost. The method is based on binding to a hydrophobic dye akin to ANS, which fluoresces upon binding to molten globules and thermal denaturation intermediates. No inherent properties of the protein, such as enzymatic activity or presence of an intrinsic fluorophore, are required. Very small sample sizes are analyzed using a real-time PCR machine, enabling the use of high-throughput purification. We show that the apparent T(M) values obtained from HTTS are approximately linearly related to those from CD thermal denaturation for a series of four-helix bundle hydrophobic core variants. We demonstrate similar results for a small set of TIM barrel variants. This inexpensive, general, and scaleable approach enables the search for conservative, stable mutants of biotechnologically important proteins and provides a method for statistical correlation of sequence-stability relationships.
- Published
- 2009