Conformational flexibility of the catalytic domain of Cdc25B phosphatase

Cdc25B phosphatase acts on the progression of cell cycle through the activation of Cdk/Cyclin complexes. Currently, the proposed structural models of Cdc25B catalytic domain lack the last 16 residues from the C-terminal region. This segment is important for protein substrate recognition and might be involved in small molecule binding to Cdc25B. Thus, the main goal of this thesis was to evaluate the conformational flexibility of the complete catalytic domain from Cdc25B through computer simulations and experimental nuclear magnetic resonance (NMR) measurements. Similarity between crystal and in solution structures was confirmed by the prediction of backbone φ/ψ dihedral angles from chemical shifts (CS) and by the agreement between observed and back-calculated residual dipolar couplings (RDC). 15N relaxation and RDC measurements pointed to the conformational disorder of the C-terminal region, in agreement with the X-ray diffraction experiment where this segment showed no electronic density. Comparison between experimental and predicted CS from long molecular dynamics (MD) simulations (6µs total running time) pointed to the presence of crystallographic artifacts, possible deficiencies in simulation force fields, inaccurate composition of the simulated system and conformational states visited by Cdc25B in solution that were not observed in the crystallographic geometry. Generally, CS predicted from simulations for the structural fluctuation of the disordered C-terminal region were in agreement with experimental values, suggesting that the simulations sampled the conformational states populated by this segment reasonably well. In particular, a cation-π contact not observed in the crystal structure between side chains of residue 550W from the disordered C-terminal tail and residue 482R from the protein core might be important in solution. This contact is also in agreement with experimental chemical shift perturbations (CSP) measured between complete and truncated constructs of Cdc25B catalytic domain. Therefore, the joint use of computer simulations and experimental measurements allowed the achievement of a more complete and realistic representation of the conformational flexibility of the Cdc25B catalytic domain in solution, including intramolecular contacts between the disordered C-terminal region and the protein core. This information might be used to obtain a conformational ensemble of Cdc25B. (AU)