Hydrogen bonding patterns and cooperativity in polyproline II helical bundles

Abstract

Hydrogen bond cooperativity (HBC) plays an important role in stabilizing protein assemblies built by α-helices and β-sheets, the most common secondary structures. However, whether HBC exists in other types of protein secondary structures such as polyproline II (PPII) helices remains unexplored. This is intriguing, since PPII systems as assembling blocks are continuously emerging across multiple fields. Here, using a combination of computational chemistry tools and molecular modeling corroborated by experimental observables, we characterize the distinct H-bonding patterns present in PPII helical bundles and establish that HBC stabilizes intermolecular PPII helices as seen in other protein assemblies such as amyloid fibrils. In addition to cooperative interactions in canonical CO···HN H-bonds, we show that analogous interactions in non-canonical CO···HαCα H-bonds are relevant in Gly-rich PPII bundles, thus compensating for the inability of glycine residues to create hydrophobic cores. Our results provide a mechanistic explanation for the assembly of these bundles. Hydrogen bond cooperativity (HBC) plays an important role in the stability of protein assemblies built by α-helices and β-sheets, however, it remains unknown whether HBC also exists in polyproline II (PPII) helices. Here, the authors show that HBC stabilizes intermolecular PPII helices using computational chemistry tools and molecular modeling corroborated by experimental observations.