Simple electrostatic model improves designed protein sequences
Open Access
- 1 August 2006
- journal article
- Published by Wiley in Protein Science
- Vol. 15 (8) , 2014-2018
- https://doi.org/10.1110/ps.062105506
Abstract
Electrostatic interactions are important for both protein stability and function, including binding and catalysis. As protein design moves into these areas, an accurate description of electrostatic energy becomes necessary. Here, we show that a simple distance-dependent Coulombic function parameterized by a comparison to Poisson-Boltzmann calculations is able to capture some of these electrostatic interactions. Specifically, all three helix N-capping interactions in the engrailed homeodomain fold are recovered using the newly parameterized model. The stability of this designed protein is similar to a protein forced by sequence restriction to have beneficial electrostatic interactions.Keywords
This publication has 29 references indexed in Scilit:
- Computational Design of a Biologically Active EnzymeScience, 2004
- Role of the protein side‐chain fluctuations on the strength of pair‐wise electrostatic interactions: Comparing experimental with computed pKasProteins-Structure Function and Bioinformatics, 2002
- The Protein Data BankNucleic Acids Research, 2000
- De Novo Protein Design: Fully Automated Sequence SelectionScience, 1997
- Automated design of the surface positions of protein helicesProtein Science, 1997
- Protein design automationProtein Science, 1996
- Conformational analysis of the backbone-dependent rotamer preferences of protein sidechainsNature Structural & Molecular Biology, 1994
- The dead-end elimination theorem and its use in protein side-chain positioningNature, 1992
- Dominant forces in protein foldingBiochemistry, 1990
- Destabilization of an alpha-helix-bundle protein by helix dipoles.Proceedings of the National Academy of Sciences, 1989