Abstract
The stability of IFN-γ as a therapeutic protein can play a key role on its anticancer effects. Herein, we explored the thermodynamic parameters and conformational stability of IFN-γ in the presence of calycosin, the main active compound of Radix astragali, by different biophysical and theoretical analysis. Afterwards, the improved anticancer effects of IFN-γ-calycosin interaction relative to IFN-γ alone were assessed on hepatocellular carcinoma (HepG2) cell line by MTT and caspase assays. ITC data indicated that upon interaction of calycosin with IFN-γ the binding and thermodynamic parameters were as follows: Kd = 1.9 μM, ΔG° = -32.45 kJ/mol, ΔH° = -11.91 kJ/mol, and TΔS° = 20.54 kJ/mol. ANS/synchronous fluorescence, CD and UV-Vis spectroscopy studies indicated that the interaction between calycosin and IFN-γ caused the folding of the IFN-γ backbone in to a more packed structure with enhanced α-helix content and higher melting temperature (Tm) value. The spectroscopic outcomes were then verified by molecular docking and molecular dynamic analysis. It was also shown that after incubation of the IFN-γ samples at 50 °C for 60 min in the presence of calycosin (5 μM), the IFN-γ-calycosin system showed a significant antiproliferative effects against hepatocellular carcinoma (HepG2) cells through caspase-9/3 activation and this anticancer effect was more pronounced than free IFN-γ. This data may provide useful information about the development of IFN-γ-based therapeutic platforms.
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