TY - JOUR
T1 - Computational Design of a PAK1 Binding Protein
AU - Jha, Ramesh K.
AU - Leaver-Fay, Andrew
AU - Yin, Shuangye
AU - Wu, Yibing
AU - Butterfoss, Glenn L.
AU - Szyperski, Thomas
AU - Dokholyan, Nikolay V.
AU - Kuhlman, Brian
N1 - Funding Information:
Computational services were provided in part by Renaissance Computing Institute, University of North Carolina at Chapel Hill. The work was supported by the Defense Advanced Research Projects Agency and National Institutes of Health (to B.K.). This work is supported by the National Institutes of Health Grant R01GM080742 and the ARRA supplement 3R01GM080742-03S1 (to N.V.D.) Spider Roll protein was selected as a community outreach target by the Northeast Structural Genomics Consortium ( http://www.nesg.org ; NESG ID OR24). We thank Dr. Ashutosh Tripathy from University of North Carolina Macromolecular Interactions Facility and Dr. Greg Young from University of North Carolina Biomolecular NMR Lab for their help during the experiments. We also thank Dr. Yi Wu and Dr. Klaus Hahn for PAK1 clones and useful discussions about PAK1.
PY - 2010/7
Y1 - 2010/7
N2 - We describe a computational protocol, called DDMI, for redesigning scaffold proteins to bind to a specified region on a target protein. The DDMI protocol is implemented within the Rosetta molecular modeling program and uses rigid-body docking, sequence design, and gradient-based minimization of backbone and side-chain torsion angles to design low-energy interfaces between the scaffold and target protein. Iterative rounds of sequence design and conformational optimization were needed to produce models that have calculated binding energies that are similar to binding energies calculated for native complexes. We also show that additional conformation sampling with molecular dynamics can be iterated with sequence design to further lower the computed energy of the designed complexes. To experimentally test the DDMI protocol, we redesigned the human hyperplastic discs protein to bind to the kinase domain of p21-activated kinase 1 (PAK1). Six designs were experimentally characterized. Two of the designs aggregated and were not characterized further. Of the remaining four designs, three bound to the PAK1 with affinities tighter than 350 μM. The tightest binding design, named Spider Roll, bound with an affinity of 100 μM. NMR-based structure prediction of Spider Roll based on backbone and 13Cβ chemical shifts using the program CS-ROSETTA indicated that the architecture of human hyperplastic discs protein is preserved. Mutagenesis studies confirmed that Spider Roll binds the target patch on PAK1. Additionally, Spider Roll binds to full-length PAK1 in its activated state but does not bind PAK1 when it forms an auto-inhibited conformation that blocks the Spider Roll target site. Subsequent NMR characterization of the binding of Spider Roll to PAK1 revealed a comparably small binding 'on-rate' constant (≪105 M-1 s-1). The ability to rationally design the site of novel protein-protein interactions is an important step towards creating new proteins that are useful as therapeutics or molecular probes.
AB - We describe a computational protocol, called DDMI, for redesigning scaffold proteins to bind to a specified region on a target protein. The DDMI protocol is implemented within the Rosetta molecular modeling program and uses rigid-body docking, sequence design, and gradient-based minimization of backbone and side-chain torsion angles to design low-energy interfaces between the scaffold and target protein. Iterative rounds of sequence design and conformational optimization were needed to produce models that have calculated binding energies that are similar to binding energies calculated for native complexes. We also show that additional conformation sampling with molecular dynamics can be iterated with sequence design to further lower the computed energy of the designed complexes. To experimentally test the DDMI protocol, we redesigned the human hyperplastic discs protein to bind to the kinase domain of p21-activated kinase 1 (PAK1). Six designs were experimentally characterized. Two of the designs aggregated and were not characterized further. Of the remaining four designs, three bound to the PAK1 with affinities tighter than 350 μM. The tightest binding design, named Spider Roll, bound with an affinity of 100 μM. NMR-based structure prediction of Spider Roll based on backbone and 13Cβ chemical shifts using the program CS-ROSETTA indicated that the architecture of human hyperplastic discs protein is preserved. Mutagenesis studies confirmed that Spider Roll binds the target patch on PAK1. Additionally, Spider Roll binds to full-length PAK1 in its activated state but does not bind PAK1 when it forms an auto-inhibited conformation that blocks the Spider Roll target site. Subsequent NMR characterization of the binding of Spider Roll to PAK1 revealed a comparably small binding 'on-rate' constant (≪105 M-1 s-1). The ability to rationally design the site of novel protein-protein interactions is an important step towards creating new proteins that are useful as therapeutics or molecular probes.
KW - CS-Rosetta
KW - Computational protein design
KW - Protein docking
KW - Protein-protein interactions
KW - Rosetta molecular modeling program
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U2 - 10.1016/j.jmb.2010.05.006
DO - 10.1016/j.jmb.2010.05.006
M3 - Article
C2 - 20460129
AN - SCOPUS:77953808264
SN - 0022-2836
VL - 400
SP - 257
EP - 270
JO - Journal of Molecular Biology
JF - Journal of Molecular Biology
IS - 2
ER -