Electrostatic origin of a stabilizing synergistic interaction among b‐, c‐, and f‐residues in a trimeric coiled coil

Abstract

AbstractCoiled coils are one of most common protein quaternary structures and represent the best understood relationship between amino acid sequence and protein conformation. Whereas the roles of residues at the canonical heptad positions the a, d, e, and g are understood in precise detail, conventional approaches often assume that the solvent‐exposed b‐, c‐, and f‐positions can be varied broadly for application‐specific purposes with minimal consequences. However, a growing body of evidence suggests that interactions among these b, c, and f residues can contribute substantially to coiled‐coil conformational stability. In the trimeric coiled coil described here, we find that b‐position Glu10 engages in a stabilizing long‐range synergistic interaction with c‐position Lys18 (ΔΔΔGf = −0.65 ± 0.02 kcal/mol). This favorable interaction depends strongly on the presence of two nearby f‐position residues: Lys 7 and Tyr14. Extensive mutational analysis of these residues in the presence of added salt versus denaturant suggests that this long‐range synergistic interaction is primarily electrostatic in origin, but also depends on the precise location and acidity of a side‐chain hydrogen‐bond donor within f‐position Tyr14.