Background: The cyclic, disulfide-containing peptide, cyclo-Ac-[Cys-His-Pro-Gln-Gly-Pro-Pro-Cys]-NH2, binds to streptavidin with high affinity. In streptavidin-peptide cocrystals of space group I222, cyclic peptide monomers are bound on adjacent streptavidin tetramers related by a crystallographic two-fold symmetry axis. We set out to determine whether the disulfide bonds of the peptide, presented close to one another in the crystal, could undergo disulfide interchange to form a dimer.
Results: When juxtaposed, the disulfides of neighboring peptides undergo disulfide interchange, breaking and forming covalent disulfide bonds, to produce a peptide dimer adopting the symmetry of the crystal. This is the first example of a chemical transformation mediated by a protein crystal lattice. The structure of the streptavidin-bound monomer, and that of the dimer that was eventually produced from it in the crystal, were both determined from the same single crystal studied at different times. The two-fold symmetric peptide dimer was independently synthesized and shown to form crystals of dimerized streptavidin.
Conclusions: We have shown that formation of a covalently linked peptide dimer can be mediated by a protein crystal lattice. The dimer thus produced dimerizes its target, streptavidin, suggesting that solid-state (or topochemical) reactions of this kind may be broadly useful for the preparation of ligands that can dimerize other protein targets.