Energetics of Charge-charge Interactions in Proteins

Overview

Journal Proteins

Date 1988 Jan 1

PMID 3287370

Citations 71

Authors

M K Gilson

B H Honig

Affiliations

Soon will be listed here.

Abstract

Electrostatic interactions between pairs of atoms in proteins are calculated with a model based on the linearized Poisson-Boltzmann equation. The equation is solved accurately by a method that takes into account the detailed shape of the protein. This paper presents applications to several systems. Experimental data for the interaction of ionized residues with an active site histidine in subtilisin BPN' allow the model to be tested, using various assumptions for the electrical properties of the protein and solvent. The electrostatic stabilization of the active site thiolate of rhodanese is analyzed, with attention to the influence of alpha-helices. Finally, relationships between electrostatic potential and charge-charge distance are reported for large and small globular proteins. The above results are compared with those of simpler electrostatic models, including Coulomb's law with both a distance-dependent dielectric constant (epsilon = R) and a fixed dielectric constant (epsilon = 2), and Tanford-Kirkwood theory. The primary conclusions are as follows: 1) The Poisson-Boltzmann model agrees with the subtilisin data over a range of ionic strengths; 2) two alpha-helices generate a large potential in the active site of rhodanese; 3) epsilon = R overestimates weak electrostatic interactions but yields relatively good results for strong ones; 4) Tanford-Kirkwood theory is a useful approximation to detailed solutions of the linearized Poisson-Boltzmann equation in globular proteins; and 5) the modified Tanford-Kirkwood theory over-screens the measured electrostatic interactions in subtilisin.

Citing Articles

The 419th Aspartic Acid of Neural Membrane Protein Enolase 2 Is a Key Residue Involved in the Axonal Growth of Motor Neurons Mediated by Interaction between Enolase 2 Receptor and Extracellular Pgk1 Ligand.

Lee B, Tsai J, Huang Y, Wang C, Lee H, Tsai H Int J Mol Sci. 2024; 25(19).

PMID: 39409082 PMC: 11477227. DOI: 10.3390/ijms251910753.

Connecting Gas-Phase Computational Chemistry to Condensed Phase Kinetic Modeling: The State-of-the-Art.

Edeleva M, Van Steenberge P, Sabbe M, Dhooge D Polymers (Basel). 2021; 13(18).

PMID: 34577928 PMC: 8467432. DOI: 10.3390/polym13183027.

Comparative Analysis of Electrostatic Models for Ligand Docking.

Sartori G, Nascimento A Front Mol Biosci. 2019; 6:52.

PMID: 31334248 PMC: 6624376. DOI: 10.3389/fmolb.2019.00052.

Towards a critical evaluation of an empirical and volume-based solvation function for ligand docking.

Muniz H, Nascimento A PLoS One. 2017; 12(3):e0174336.

PMID: 28323889 PMC: 5360343. DOI: 10.1371/journal.pone.0174336.

Investigating the effects of tropomyosin mutations on its flexibility and interactions with filamentous actin using molecular dynamics simulation.

Zheng W, Hitchcock-DeGregori S, Barua B J Muscle Res Cell Motil. 2016; 37(4-5):131-147.

PMID: 27376658 DOI: 10.1007/s10974-016-9447-3.