Hydrophobic Clusters Direct Folding of a Synthetic Chimeric Protein

Abstract

AbstractExtant proteins frequently share sub-domain sized fragments, suggesting that among other mechanisms, proteins evolved new structure and functions via recombination of existing fragments. While the role of protein fragments as evolutionary units is well-established, their biophysical features necessary for generating a well-folded and stable protein are not clearly understood. In order to probe how fragments determine foldability and stability of recombined proteins, we investigated the stability, folding and dynamics of a synthetic chimera created by fusion of fragments of the chemotactic response regulator protein CheY that belongs to the flavodoxin-like fold and imidazole glycerol phosphate synthase from histidine biosynthesis (HisF) which harbors the TIM-barrel fold. The chimera unfolds via an equilibrium intermediate. Mutation of a glycine residue present at the interface of the CheY and HisF fragments to a valine abrogates the equilibrium intermediate while mutation to isoleucine dramatically increases the native state kinetic stability without any significant change in the folding rate. Parts of the fragment interface in the chimera are found to be conformationally dynamic while hydrophobic mutations globally increase its conformational rigidity. We hypothesize that the hydrophobic mutation improves sidechain packing in a large cluster of isoleucine, leucine and valine (ILV) residues that spans the fragment interface. We also extrapolate that inheritance of large ILV clusters from parent proteins could be a key determinant of successful fragment recombination.