Methyl Effects on Protein–Ligand Binding

Abstract

The effects of addition of a methyl group to a lead compound on biological activity are examined. A literature analysis of >2000 cases reveals that an activity boost of a factor of 10 or more is found with an 8% frequency, and a 100-fold boost is a 1 in 200 event. Four cases in the latter category are analyzed in depth to elucidate any unusual aspects of the protein-ligand binding, distribution of water molecules, and changes in conformational energetics. The analyses include Monte Carlo/free-energy perturbation (MC/FEP) calculations for methyl replacements in inhibitor series for p38α MAP kinase, ACK1, PTP1B, and thrombin. Methyl substitutions ortho to an aryl ring can be particularly effective at improving activity by inducing a propitious conformational change. The greatest improvements in activity arise from coupling the conformational gain with the burial of the methyl group in a hydrophobic region of the protein.

References

Page 1

	Year	Citations
Comparison of simple potential functions for simulating liquid water William L. Jorgensen, Jayaraman Chandrasekhar, Jeffry D. Madura, The Journal of Chemical Physics EngineeringLiquid-liquid FlowFluid MechanicsComputational ChemistryChemistry	1983	41.1K
Development and Testing of the OPLS All-Atom Force Field on Conformational Energetics and Properties of Organic Liquids William L. Jorgensen, David S. Maxwell, Julian Tirado‐Rives Journal of the American Chemical Society Organic MoleculesEngineeringConformational EnergeticsPhysicsGas Phase	1996	15K
Potential energy functions for atomic-level simulations of water and organic and biomolecular systems William L. Jorgensen, Julian Tirado‐Rives Proceedings of the National Academy of Sciences EngineeringComputational ChemistryChemistryMolecular DynamicsMolecular Design	2005	1.5K
Role of the Active-Site Solvent in the Thermodynamics of Factor Xa Ligand Binding Robert Abel, Tom Young, Ramy Farid, Journal of the American Chemical Society	2008	667
Free energy calculations: a breakthrough for modeling organic chemistry in solution William L. Jorgensen Accounts of Chemical Research EngineeringAltmetric Attention ScoreBibliometricsOrganic ChemistryComputational Chemistry	1989	632
Functional group contributions to drug-receptor interactions Peter R. Andrews, David J. Craik, Jennifer L. Martin Journal of Medicinal Chemistry Molecular DockingMedicinal ChemistryDrug TargetPolar GroupsBiochemistry	1984	531
Perspective on Free-Energy Perturbation Calculations for Chemical Equilibria William L. Jorgensen, Laura L. Thomas Journal of Chemical Theory and Computation	2008	359
Energetics of Displacing Water Molecules from Protein Binding Sites: Consequences for Ligand Optimization Julien Michel, Julian Tirado‐Rives, William L. Jorgensen Journal of the American Chemical Society EngineeringProtein AssemblyOrdered MoleculeComputational ChemistryWater Molecules	2009	260
Contribution of Conformer Focusing to the Uncertainty in Predicting Free Energies for Protein−Ligand Binding Julian Tirado‐Rives, William L. Jorgensen Journal of Medicinal Chemistry	2006	259
Torsional Barriers and Equilibrium Angle of Biphenyl: Reconciling Theory with Experiment Mikael P. Johansson, Jeppe Olsen Journal of Chemical Theory and Computation Flexible Basis SetsEngineeringPhysicsNatural SciencesApplied Physics	2008	219

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