Structural Mechanism Underlying Ligand Binding and Activation of PPARγ

Ligands bind to an occluded orthosteric pocket within the nuclear receptor (NR) ligand-binding domain (LBD). Molecular simulations have revealed several theoretical ligand entry/exit pathways to the orthosteric pocket, but experimentally it remains unclear whether ligand binding proceeds through induced fit or conformational selection mechanisms. Using NMR spectroscopy lineshape analysis, we show that ligand binding to the peroxisome proliferator-activated receptor gamma (PPARγ) LBD involves a two-step induced fit mechanism including an initial fast step followed by slow conformational change. Surface plasmon resonance and isothermal titration calorimetry heat capacity analysis support the fast kinetic binding step and the conformational change after binding step, respectively. The putative initial ligand binding pose is suggested in several crystal structures of PPARγ LBD where a ligand is bound to a surface pore formed by helix 3, the β-sheet, and the Ω-loop—one of several ligand entry sites suggested in previous targeted and unbiased molecular simulations. These findings, when considered with a recent NMR study showing the activation function-2 (AF-2) helix 12 exchanges in and out of the orthosteric pocket in apo/ligand-free PPARγ, suggest an activation mechanism whereby agonist binding occurs through an initial encounter complex with the LBD followed by transition of the ligand into the orthosteric pocket concomitant with a conformational change resulting in a solvent-exposed active helix 12 conformation.