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PDBsum entry 2zl1
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Protein binding
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PDB id
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2zl1
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References listed in PDB file
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Key reference
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Title
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Molecular dynamics-Solvated interaction energy studies of protein-Protein interactions: the mp1-P14 scaffolding complex.
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Authors
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Q.Cui,
T.Sulea,
J.D.Schrag,
C.Munger,
M.N.Hung,
M.Naïm,
M.Cygler,
E.O.Purisima.
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Ref.
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J Mol Biol, 2008,
379,
787-802.
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PubMed id
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Abstract
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Using the MP1-p14 scaffolding complex from the mitogen-activated protein kinase
signaling pathway as model system, we explored a structure-based computational
protocol to probe and characterize binding affinity hot spots at protein-protein
interfaces. Hot spots are located by virtual alanine-scanning consensus
predictions over three different energy functions and two different
single-structure representations of the complex. Refined binding affinity
predictions for select hot-spot mutations are carried out by applying
first-principle methods such as the molecular mechanics generalized Born surface
area (MM-GBSA) and solvated interaction energy (SIE) to the molecular dynamics
(MD) trajectories for mutated and wild-type complexes. Here, predicted hot-spot
residues were actually mutated to alanine, and crystal structures of the mutated
complexes were determined. Two mutated MP1-p14 complexes were investigated, the
p14(Y56A)-mutated complex and the MP1(L63A,L65A)-mutated complex. Alternative
ways to generate MD ensembles for mutant complexes, not relying on crystal
structures for mutated complexes, were also investigated. The SIE function,
fitted on protein-ligand binding affinities, gave absolute binding affinity
predictions in excellent agreement with experiment and outperformed standard
MM-GBSA predictions when tested on the MD ensembles of Ras-Raf and Ras-RalGDS
protein-protein complexes. For wild-type and mutant MP1-p14 complexes, SIE
predictions of relative binding affinities were supported by a yeast two-hybrid
assay that provided semiquantitative relative interaction strengths. Results on
the MP1-mutated complex suggested that SIE predictions deteriorate if mutant MD
ensembles are approximated by just mutating the wild-type MD trajectory. The SIE
data on the p14-mutated complex indicated feasibility for generating mutant MD
ensembles from mutated wild-type crystal structure, despite local structural
differences observed upon mutation. For energetic considerations, this would
circumvent costly needs to produce and crystallize mutated complexes. The
sensitized protein-protein interface afforded by the p14(Y56A) mutation
identified here has practical applications in screening-based discovery of
first-generation small-molecule hits for further development into specific
modulators of the mitogen-activated protein kinase signaling pathway.
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