We previously reported the de novo design of an amphiphilic peptide [YGG(IEKKIEA)4] that forms a native-like, parallel triple-stranded coiled coil. Starting from this peptide, we sought to regulate the assembly of the peptide by a metal ion. The replacement of the Ile18 and Ile22 residues with Ala and Cys residues, respectively, in the hydrophobic positions disrupted of the triple-stranded α-helix structure. The addition of Cd(II), however, resulted in the reconstitution of the triple-stranded α-helix bundle, as revealed by circular dichroism (CD) spectroscopy and sedimentation equilibrium analysis. By titration with metal ions and monitoring the change in the intensity of the CD spectra at 222 nm, the dissociation constant Kd was determined to be 1.5 ± 0.8 μM for Cd(II). The triple-stranded complex formed by the 113Cd(II) ion showed a single 113Cd NMR resonance at 572 ppm whose chemical shift was not affected by the presence of Cl− ions. The 113Cd NMR resonance was connected with the βH protons of the cysteine residue by 1H–113Cd heteronuclear multiple quantum correlation spectroscopy. These NMR results indicate that the three cysteine residues are coordinated to the cadmium ion in a trigonal-planar complex. Hg(II) also induced the assembly of the peptide into a triple-stranded α-helical bundle below the Hg(II)/peptide ratio of 1/3. With excess Hg(II), however, the α-helicity of the peptide was decreased, with the change of the Hg(II) coordination state from three to two. Combining this construct with other functional domains should facilitate the production of artificial proteins with functions controlled by metal ions.

Several de novo designed ionic peptides that are able to undergo conformational change under the influence of temperature and pH were studied. These peptides have two distinct surfaces with regular repeats of alternating hydrophilic and hydrophobic side chains. This permits extensive ionic and hydrophobic interactions resulting in the formation of stable β-sheet assemblies. The other defining characteristic of this type of peptide is a cluster of negatively charged aspartic or glutamic acid residues located toward the N-terminus and positively charged arginine or lysine residues located toward the C-terminus. This arrangement of charge balances the α-helical dipole moment (C → N), resulting in a strong tendency to form stable α-helices as well. Therefore, these peptides can form both stable α-helices and β-sheets. They are also able to undergo abrupt structural transformations between these structures induced by temperature and pH changes. The amino acid sequence of these peptides permits both stable β-sheet and α-helix formation, resulting in a balance between these two forms as governed by the environment. Some segments in proteins may also undergo conformational changes in response to environmental changes. Analyzing the plasticity and dynamics of this type of peptide may provide insight into amyloid formation. Since these peptides have dynamic secondary structure, they will serve to refine our general understanding of protein structure.

A series of designed short helical peptides was used to study the effect of nonpolar interactions on conformational specificity. The consensus sequence was designed to obtain short helices (17 residues) and to minimize the presence of interhelical polar interactions. Furthermore, the sequence contained a heptad repeat (abcdefg), where positions a and d were occupied by hydrophobic residues Leu, Ile, or Val, and positions e and g were occupied by Ala. The peptides were named according to the identities of the residues in the adeg positions, respectively. The peptides llaa, liaa, ilaa, iiaa, ivaa, viaa, lvaa, vlaa, and vvaa were synthesized, and their characterization revealed marked differences in specificity. An experimental methodology was developed to study the nine peptides and their pairwise mixtures. These peptides and their mixtures formed a vast array of structural states, which may be classified as follows: helical tetramers and pentamers, soluble and insoluble helical aggregates, insoluble unstructured aggregates, and soluble unstructured monomers. The peptide liaa formed stable helical pentamers, and iiaa and vlaa formed stable helical tetramers. Disulfide cross-linking experiments indicated the presence of an antiparallel helix alignment in the helical pentamers and tetramers. Rates of amide proton exchange of the tetrameric form of vlaa were 10-fold slower than the calculated exchange rate for unfolded vlaa. In other work, the control of specificity has been attributed to polar interactions, especially buried polar interactions; this work demonstrated that subtle changes in the configuration of nonpolar interactions resulted in a large variation in the extent of conformational specificity of assemblies of designed short helical peptides. Thus, nonpolar interactions can have a significant effect on the conformational specificity of oligomeric short helices.

The effects of histidine residue placement in a de novo-designed four-α-helix bundle are investigated by placement of histidine residues at coiled coil heptad a positions in two distinct heptads and at each position within a single heptad repeat of our prototype heme protein maquette, [H10H24]2 [{Ac-CGGGELWKL·HEELLKK·FEELLKL·HEERLKK·L-CONH2}2]2 composed of a generic (α-SS-α)2 peptide architecture. The heme to peptide stoichiometry of variants of [H10H24]2 with either or both histidines on each helix replaced with noncoordinating alanine residues ([H10A24]2, [A10H24]2, and [A10A24]2) demonstrates the obligate requirement of histidine for biologically significant heme affinity. Variants of [A10A24]2, [{Ac-CGGGELWKL·AEELLKK·FEELLKL·AEERLKK·L-CONH2}2]2, containing a single histidine per helix in positions 9 to 15 were evaluated to verify the design based on molecular modeling. The bis-histidine site formed between heptad positions a at 10 and 10′ bound ferric hemes with the highest affinity, Kd1 and Kd2 values of 15 and 800 nM, respectively. Placement of histidine at position 11 (heptad position b) resulted in a protein that bound a single heme with moderate affinity, Kd1 of 9.5 μM, whereas the other peptides had no measurable apparent affinity for ferric heme with Kd1 values >200 μM. The bis-histidine ligation of heme to [H10A24]2 and [H11A24]2 was confirmed by electron paramagnetic resonance spectroscopy. The protein design rules derived from this study, together with the narrow tolerances revealed, are applicable for improving future heme protein designs, for analyzing the results of randomized heme protein combinatorial libraries, as well as for implementation in automated protein design.