Ion-pairing interactions are important for protein stabilization. Despite the apparent electrostatic nature of these interactions, natural positively charged amino acids Lys and Arg have multiple methylenes linking the charged functionality to the backbone. Interestingly, the amino acids Lys and Orn have positively charged side chains that differ by only one methylene. However, only Lys is encoded and incorporated into proteins. To investigate the effect of side chain length of Lys on ion-pairing interactions, a series of 12 monomeric alpha-helical peptides containing potential Glu-Xaa (i, i+3), (i, i+4) and (i, i+5) (Xaa = Lys, Orn, Dab, Dap) interactions were studied by circular dichroism (CD) spectroscopy at pH 7 and 2. At pH 7, no Glu-Xaa (i, i+5) interaction was observed, regardless of the Xaa side chain length. Furthermore, only Lys was capable of supporting Glu-Xaa (i, i+3) interactions, whereas any Xaa side chain length supported Glu-Xaa (i, i+4) interactions. Side chain conformational analysis by molecular mechanics calculations showed that the side chain length of Lys enables the Glu-Xaa (i, i+3) interaction with lower energy conformations compared to residues with side chain lengths shorter than that of Lys. Furthermore, these calculated low energy conformers were consistent with conformations of intra-helical Glu-Lys salt bridges in a non-redundant protein structure database. Importantly, the CD spectra for peptides with Glu-Lys interactions did not alter significantly upon changing the pH because of a greater contribution to these interactions by forces other than electrostatics. Incorporating side chains just one methylene shorter (Orn) resulted in significant pH dependence or lack of interaction, suggesting that nature has chosen Lys to form durable interactions with negatively charged functional groups.
Arginine (Arg) has been used for recognizing negatively charged biological molecules, cell penetration, and oligosaccharide mass signal enhancement. The versatility of Arg has inspired the need to develop Arg analogs and to research the structural effects of incorporating Arg analogs. Accordingly, we investigated the effect of Arg side chain length on helix formation by studying 12 Ala-based peptides containing the Arg analogs (S)-2-amino-6-guanidino-hexanoic acid (Agh), (S)-2-amino-4-guanidinobutyric acid (Agb), and (S)-2-amino-3-guanidinopropionic acid (Agp). Solid phase guanidinylation with orthogonal protection strategies was necessary to synthesize Agb- and Agp-containing peptides using Fmoc-based chemistry. The fraction helix for the peptides was determined by circular dichroism spectroscopy, and used to derive the statistical mechanical parameters and energetics for N-capping, C-capping, and helix propagation (propensity). All four Arg analogs were unfavorable for N-capping. The C-cap parameter followed the trend Agp
Helix-coil equilibrium studies are important for understanding helix formation in protein folding, and for helical foldamer design. The quantitative description of a helix using statistical mechanical models is based on experimentally derived helix propensities and the assumption that helix propensity is position-independent. To investigate this assumption, we studied a series of 19-residue Ala-based peptides, to measure the helix propensity for Leu, Phe, and Pff at positions 6, 11, and 16. Circular dichroism spectroscopy revealed that substituting Ala with a given amino acid (Leu, Phe, or Pff) resulted in the following fraction helix trend: KXaa16 > KXaa6 > KXaa11. Helix propensities for Leu, Phe, and Pff at the different positions were derived from the CD data. For the same amino acid, helix propensities were similar at positions 6 and 11, but much higher at position 16 (close to the C-terminus). A survey of protein helices revealed that Leu/Phe-Lys (i, i + 3) sequence patterns frequently occur in two structural patterns involving the helix C-terminus; however, these cases include a left-handed conformation residue. Furthermore, no Leu/Phe-Lys interaction was found except for the Lys-Phe cation-π interaction in two cases of Phe-Ala-Ala-Lys. The apparent high helix propensity at position 16 may be due to helix capping, adoption of a 3₁₀-helix near the C-terminus perhaps with Xaa-Lys (i, i + 3) interactions, or proximity to the peptide chain terminus. Accordingly, helix propensity is generally position-independent except in the presence of alternative structures or in the proximity of either chain terminus. These results should facilitate the design of helical peptides, proteins, and foldamers.
Ion pairing interactions between oppositely charged amino acids are important for protein structure stability. Despite the apparent electrostatic nature of these interactions, the charged amino acids Lys, Arg, Glu, and Asp have a different number of hydrophobic methylenes linking the charged functionality to the backbone. To investigate the effect of Glu (and Asp) side chain length on ion pairing interactions, a series of 36 monomeric α-helical peptides containing Zbb-Xaa (i, i+3), (i, i+4), and (i, i+5) (Zbb = Aad, Glu, Asp; Xaa = Lys, Orn, Dab, Dap) sequence patterns were studied by circular dichroism (CD) spectroscopy at pH 7 and 2. Peptides with Glu and Aad exhibited similar helicity and pH dependence, whereas peptides with Asp behaved distinctly different. The side chain interaction energetics were derived from the CD data using the nesting block method coupled with modified Lifson-Roig theory. At pH 7, no Zbb-Xaa (i, i+5) interaction was observed, regardless of side chain length (consistent with the helix geometry). Interestingly, only Lys was capable of supporting Zbb-Xaa (i, i+3) interactions, whereas any Xaa side chain length supported Zbb-Xaa (i, i+4) interactions. In particular, the magnitude of both Zbb(-)-Lys (i, i+4) and Zbb(-)-Orn (i, i+4) interaction energies followed the trend Asp > Glu > Aad. Side chain conformational analysis by molecular mechanics calculations showed that the Zbb-Xaa (i, i+3) interactions involved the χ(1) dihedral combination (g+, g+) for the i and i+3 residues, whereas the Zbb-Xaa (i, i+4) interactions were supported by the χ(1) dihedral combination (t, g+) for the i and i+4 residues. These calculated low energy conformers were consistent with conformations of intrahelical Asp-Lys and Glu-Lys salt bridges in a nonredundant protein structure database. These results suggest that Asp and Glu provide natural variation, and lengthening the Glu side chain further to Aad does not furnish additional characteristics that Glu cannot supply.
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