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Title
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Structure-based Protocol for Identifying Mutations that Enhance Protein-Protein Binding Affinities.
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Authors
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D.W.Sammond,
Z.M.Eletr,
C.Purbeck,
R.J.Kimple,
D.P.Siderovski,
B.Kuhlman.
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Ref.
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J Mol Biol, 2007,
371,
1392-1404.
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PubMed id
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Abstract
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The ability to manipulate protein binding affinities is important for the
development of proteins as biosensors, industrial reagents, and therapeutics. We
have developed a structure-based method to rationally predict single mutations
at protein-protein interfaces that enhance binding affinities. The protocol is
based on the premise that increasing buried hydrophobic surface area and/or
reducing buried hydrophilic surface area will generally lead to enhanced
affinity if large steric clashes are not introduced and buried polar groups are
not left without a hydrogen bond partner. The procedure selects affinity
enhancing point mutations at the protein-protein interface using three criteria:
(1) the mutation must be from a polar amino acid to a non-polar amino acid or
from a non-polar amino acid to a larger non-polar amino acid, (2) the free
energy of binding as calculated with the Rosetta protein modeling program should
be more favorable than the free energy of binding calculated for the wild-type
complex and (3) the mutation should not be predicted to significantly
destabilize the monomers. The performance of the computational protocol was
experimentally tested on two separate protein complexes; Galpha(i1) from the
heterotrimeric G-protein system bound to the RGS14 GoLoco motif, and the E2,
UbcH7, bound to the E3, E6AP from the ubiquitin pathway. Twelve single-site
mutations that were predicted to be stabilizing were synthesized and
characterized in the laboratory. Nine of the 12 mutations successfully increased
binding affinity with five of these increasing binding by over 1.0 kcal/mol. To
further assess our approach we searched the literature for point mutations that
pass our criteria and have experimentally determined binding affinities. Of the
eight mutations identified, five were accurately predicted to increase binding
affinity, further validating the method as a useful tool to increase
protein-protein binding affinities.
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