We designed a library of short peptides using standard rules for coiled-coil assembly. Depending on the composition of amino acids in the non-interacting region of the coiled coil (positions b, c, and f) these peptides are able to convert from α-helical to β-sheet secondary structure. This type of transition is observed in amyloid-like proteins and is a key feature associated with many types of neurodegenerative diseases. Studies on peptides that are 14 amino acids in length indicated that positioning hydrophobic amino acids at an f position within a heptad repeat accelerated the rate of conformational conversion as compared to that at a c position. We believe that this occurs because of the formation of a hydrophobic pocket that preferentially stabilizes β-sheets over α-helices. This effect was also observed in longer 21 amino acid peptides. Our study shows that the relative rates of structural conversion correlate with the formation of a continuous three-amino-acid hydrophobic patch consisting of amino acids in the d, f, and a positions and not on the secondary structure propensities of the individual amino acids. The sequence−structure relationship observed in this study will be used to help understand the mechanism of amyloid fiber formation and design future coiled-coil and β-sheet-forming peptide systems.