PMID: 22061265
Title: Computational design of high affinity epitope scaffolds by backbone grafting of a linear epitope
Abstract: Computational grafting of functional motifs onto scaffold proteins is a promising way to engineer novel proteins with pre-specified functionalities. Typically, protein grafting involves the transplantation of protein side chains from a functional motif onto structurally homologous regions of scaffold proteins. Using this approach, we previously transplanted the human immunodeficiency virus 2F5 and 4E10 epitopes onto heterologous proteins to design novel 'epitope-scaffold' antigens. However, side-chain grafting is limited by the availability of scaffolds with compatible backbone for a given epitope structure and offers no route to modify backbone structure to improve mimicry or binding affinity. To address this, we report here a new and more aggressive computational method-backbone grafting of linear motifs-that transplants the backbone and side chains of linear functional motifs onto scaffold proteins. To test this method, we first used side-chain grafting to design new 2F5 epitope scaffolds with improved biophysical characteristics. We then independently transplanted the 2F5 epitope onto three of the same parent scaffolds using the newly developed backbone grafting procedure. Crystal structures of side-chain and backbone grafting designs showed close agreement with both the computational models and the desired epitope structure. In two cases, backbone grafting scaffolds bound antibody 2F5 with 30- and 9-fold higher affinity than corresponding side-chain grafting designs. These results demonstrate that flexible backbone methods for epitope grafting can significantly improve binding affinities over those achieved by fixed backbone methods alone. Backbone grafting of linear motifs is a general method to transplant functional motifs when backbone remodeling of the target scaffold is necessary.
Date: 1970-08-21
Year: 2012
Journal: J. Mol. Biol.
PMID Author: Azoitei ML, Ban YE, Julien JP, Bryson S, Schroeter A, Kalyuzhniy O, Porter JR, Adachi Y, Baker D, Pai EF, Schief WR
Computational design of high-affinity epitope scaffolds by backbone grafting of a linear epitope. J. Mol. Biol. 2012;415(1):175-92 doi: 10.1016/j.jmb.2011.10.003

Media Contacts

Africa

Ethel Makila
+254 71 904 3142
EMakila@iavi.org

 

Europe

Hester Kuipers
+31 20 521 0343
HKuipers@iavi.org 

 

Global

Anita Kawatra
+1 212 847 1055
AKawatra@iavi.org 

 

India

Saif ul Hadi
+91 11 4737 6032
SulHadi@iavi.org 

 

United States

Rose Catlos
+1 212 847 1049
RCatlos@iavi.org