Figure 6.
Effect of mutations on thermal stability of STAT3 protein monomers and homodimers. (A) Bacterially expressed and purified WT and mutant STAT3 proteins were examined for thermal stability using the differential scanning fluorimetry assay; change in fluorescence (dF) is recorded with increasing temperature (dT). The first derivative of each melting curve (dF/dT) is shown for WT and mutants organized into mutant categories and examined as monomers (right panels) or as homodimers (left panels). The inflection point or Tm for WT STAT3 monomers and homodimers is indicated by the vertical dashed line in each panel. (B-D) The calculated Tm of each mutant monomer, the primary Tm (Tm1) and secondary Tm (Tm2) of each GOF SH2D mutant homodimer, and the differences between the Tm, Tm1, or Tm2 of each mutant and the corresponding Tm of WT STAT3 (ΔTm) are shown in tabular form (B) and graphically (C-D).

Effect of mutations on thermal stability of STAT3 protein monomers and homodimers. (A) Bacterially expressed and purified WT and mutant STAT3 proteins were examined for thermal stability using the differential scanning fluorimetry assay; change in fluorescence (dF) is recorded with increasing temperature (dT). The first derivative of each melting curve (dF/dT) is shown for WT and mutants organized into mutant categories and examined as monomers (right panels) or as homodimers (left panels). The inflection point or Tm for WT STAT3 monomers and homodimers is indicated by the vertical dashed line in each panel. (B-D) The calculated Tm of each mutant monomer, the primary Tm (Tm1) and secondary Tm (Tm2) of each GOF SH2D mutant homodimer, and the differences between the Tm, Tm1, or Tm2 of each mutant and the corresponding Tm of WT STAT3 (ΔTm) are shown in tabular form (B) and graphically (C-D).

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