We have extended our studies of Trp/Trp to other Aryl/Aryl through-space interactions that stabilize hairpins and other small polypeptide folds. Herein we detail the NMR and CD spectroscopic features of these types of interactions. NMR data remains the best diagnostic for characterizing the common T-shape orientation. Designated as an edge-to-face (EtF or FtE) interaction, large ring current shifts are produced at the edge aryl ring hydrogens and, in most cases, large exciton couplets appear in the far UV circular dichroic (CD) spectrum. The preference for the face aryl in FtE clusters is W≫Y≥F (there are some exceptions in the Y/F order); this sequence corresponds to the order of fold stability enhancement and always predicts the amplitude of the lower energy feature of the exciton couplet in the CD spectrum. The CD spectra for FtE W/W, W/Y, Y/W, and Y/Y pairs all include an intense feature at 225–232 nm. An additional couplet feature seen for W/Y, W/F, Y/Y and F/Y clusters, is a negative feature at 197–200 nm. Tyr/Tyr (as well as F/Y and F/F) interactions produce much smaller exciton couplet amplitudes. The Trp-cage fold was employed to search for the CD effects of other Trp/Trp and Trp/Tyr cluster geometries: several were identified. In this account, we provide additional examples of the application of cross-strand aryl/aryl clusters for the design of stable β-sheet models and a scale of fold stability increments associated with all possible FtE Ar/Ar clusters in several structural contexts.
Many factors influence the stability of hairpins that could appear as foldons in partially folded states of proteins; of these, the propensity of certain amino acid sequences to favor conformations that serve to align potential β-strands for antiparallel association is likely the dominant feature. Quantitating turn propensities is viewed as the first step in developing an algorithm for locating nascent hairpins in protein sequences. Such nascent hairpins can serve to accelerate protein folding or, if they represent structural elements that differ from the final folded state, as kinetic traps. We have measured these "turn propensities" for the two most common turn types using a series of model peptide hairpins with four- and six-residue loops connecting the associated β-strands. Loops of four to six residues with specific turn sequences containing only natural l-amino acids and glycine can provide as much as 15 kJ/mol of hairpin stabilization versus loops lacking the defined turn loci. Single-site mutations within some of the optimal connecting loops can have ΔΔG effects as large as 9-10 kJ/mol on hairpin stability. In contrast to the near universal II'/I' turns of model hairpins, a number of hairpin-supporting XZZG sequence β-turns with α and/or γ configurations at the ZZ unit were found. A series of turn replacements (four-residue β-turns replaced by sequences that favor five- and six-residue reversing loops) using identical strands in our model systems have confirmed that several sequences have intrinsic turn propensities that could favor β-strand association in a non-native strand register and thus serve as kinetic traps. These studies also indicate that aryl residues immediately flanking a turn sequence can alter relative turn propensities by as much as 9-11 kJ/mol and will need to be a part of any nascent hairpin recognition algorithm.
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