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Quantitative characterization of affinity of intermolecular interactions is important in many areas of biomedical research. Binding dissociation constant (KD) is essential not only in drug discovery but is also an important parameter in characterization of any binary interaction in any biological system. Biochemical methods used for detection of protein-protein interactions, such as immunoprecipitation and yeast two-hybrid screens, do not inform us on how tight are those interactions, while affinity defines whether this particular complex exists under given conditions in vivo. In drug discovery process, binding assay development is one of the necessary and frequently the most time-consuming steps. Most commonly used methods of KD determination include fluorescence polarization,1 surface plasmon resonance (SPR) technology,2 radioligand binding,3 isothermal titration calorimetry,4 equilibrium dialysis (ED),5 ultrafiltration (UF),5 and ultracentrifugation (UC).6 All of them require significant quantities of purified target protein. Microscale thermophoresis (MST) is a rapidly developing method that detects directed movement of molecules in a microscopic temperature gradient. Any changes of the hydration shell of biomolecules result in a relative change of movement along the temperature gradient.7 MST is used to determine binding affinities and has been applied for studying ligand binding to fluorescently labeled proteins or fluorescent ligands to a target protein.8, 9 MST allows measurement of interactions directly in solution without the need of immobilization to a surface (immobilization-free technology). Practically, any binding is accompanied by a change in MST signal, although the size of the change differs from system to system significantly. For the detection of molecule motion by MST, they have to be fluorescent. This major limitation of the method can be turned into an advantage. If a protein is expressed as a GFP fusion in any system, it will be the only fluorescent molecule and thus can be studied without isolation from the cell lysate or cell-free expression system. Generation of cell lysates that allow for binding conditions with minimal artifacts is the major challenge. Here we describe a protocol of cell lysate preparation and MST experiment that can be used for many soluble and membrane proteins.
STAT proteins are latent cytoplasmic transcription factors activated by tyrosine phosphorylation in response to extracellular signals and are involved in many biological processes including immunity, hematopoiesis, inflammation, and development.10 In mammals, the STAT family consists of STAT 1, 2, 3, 4, 5A, 5B, and 6. All activated STATs are known to bind to the same DNA sequence, so called GAS motif, IFN-gamma activated sequence. However, the transcriptional effects of different STATs are very different.11 In spite of involvement in many pathological processes and extensive studies yielding over 17,000 publications, the KD of STAT interactions with different DNA sequences have not been determined. Only relative affinity of different STATs to variants of GAS motif has been characterized.11 Difficulties in protein expression and purification are the major impediments in characterization of STATs' DNA binding selectivity. Although the majority of the studies have focused on the role of "activated" STATs, which became synonymous to Tyr-phosphorylated transcription factor, the role of non-phosphorylated STATs (U-STATs) in regulation of transcription is emerging rapidly.12 However, these mechanisms are poorly understood, and it was unclear whether U-STATs actually bind to DNA or act through interactions with other transcription factors. We have recently shown that U-STAT3 can bind to DNA sequences different from GAS motifs with even higher affinity.13 The finding has significant implications for our understanding of the biological functions of this important protein. We have applied microscale thermophoresis to determine relative affinities of STAT3 to GAS and AT-rich oligonucleotide S+100 (Figure 4). Almost identical protocol has been used for KD determination for binding of a different STAT3 ligand, a lipopeptide inhibitor.14 No binding to a related transcription factor, GFP-STAT1 that was used as a negative control could be detected thus confirming selectivity of interaction.14