Magne Olufsen

Electrostatic interactions play an essential role in DNA repair and cold-adaptation of Uracil DNA glycosylase

AbstractLife has adapted to most environments on earth, including low and high temperature niches. The increased catalytic efficiency and thermoliability observed for enzymes from organisms living in constantly cold regions when compared to their mesophilic and thermophilic cousins are poorly understood at the molecular level. Uracil DNA glycosylase (UNG) from cod (cUNG) catalyzes removal of uracil from DNA with an increased kcat and reduced Km relative to its warm-active human (hUNG) counterpart. Specific issues related to DNA repair and substrate binding/recognition (Km) are here investigated by continuum electrostatics calculations, MD simulations and free energy calculations. Continuum electrostatic calculations reveal that cUNG has surface potentials that are more complementary to the DNA potential at and around the catalytic site when compared to hUNG, indicating improved substrate binding. Comparative MD simulations combined with free energy calculations using the molecular mechanics-Poisson Boltzmann surface area (MM-PBSA) method show that large opposing energies are involved when forming the enzyme-substrate complexes. Furthermore, the binding free energies obtained reveal that the Michaelis-Menten complex is more stable for cUNG, primarily due to enhanced electrostatic properties, suggesting that energetic fine-tuning of electrostatics can be utilized for enzymatic temperature adaptation. Energy decomposition pinpoints the residual determinants responsible for this adaptation. FigureElectrostatic isosurfaces of cod uracil DNA glycosylase in complex with double stranded DNA

Ion pairs and their role in modulating stability of cold‐ and warm‐active uracil DNA glycosylase

MD simulations and continuum electrostatics calculations have been used to study the observed differences in thermostability of cold‐ and warm‐active uracil DNA glycosylase (UDG). The present study focuses on the role of ion pairs and how they affect the thermal stability of the two enzymes. Analysis of the MD generated structural ensembles show that cod UDG (cUDG) and human UDG (hUDG) have 11 and 12 ion pairs which are present in at least 30% of the conformations. The electrostatic contribution of the ion pairs, computed using continuum electrostatics, is slightly more favorable in cUDG at 298 K. This is primarily attributed to more optimized interactions between the ion pairs and nearby dipoles/charges in cUDG. More global salt bridges are found in hUDG and are more stabilizing when compared to cUDG, possibly playing a role in maintaining overall stability and reducing conformational entropy. Both enzymes contain one three‐member ionic network, but the one found in hUDG is far more stabilizing. Our results also suggest that care should be taken when performing statistical analysis of crystal structures with respect to ion pairs, and that crystallization conditions must be carefully examined when performing such analysis. Proteins 2008.