A comparative study of the impact of small, medium-sized, and bulky α,β-dehydroamino acids (ΔAAs) on the structure and stability of Balaram's incipient 310-helical peptide (1) is reported. Replacement of the N-terminal Aib residue of 1 with a ΔAA afforded peptides 2a-c that maintained the 310-helical shape of 1. In contrast, installation of a ΔAA in place of Aib-3 yielded peptides 3a-c that preferred a β-sheet-like conformation. The impact of the ΔAA on peptide structure was independent of size, with small (ΔAla), medium-sized (Z-ΔAbu), and bulky (ΔVal) ΔAAs exerting similar effects. The proteolytic stabilities of 1 and its analogs were determined by incubation with Pronase. Z-ΔAbu and ΔVal increased the resistance of peptides to proteolysis when incorporated at the 3-position and had negligible impact on stability when placed at the 1-position, whereas ΔAla-containing peptides degraded rapidly regardless of position. Exposure of peptides 2a-c and 3a-c to the reactive thiol cysteamine revealed that ΔAla-containing peptides underwent conjugate addition at room temperature, while Z-ΔAbu- and ΔVal-containing peptides were inert even at elevated temperatures. These results suggest that both bulky and more accessible medium-sized ΔAAs should be valuable tools for bestowing rigidity and proteolytic stability on bioactive peptides.
A comparative study of the impact of small, medium-sized, and bulky α,β-n class="Chemical">dehydroamino acids (ΔAAs) on the structure and stability of Balaram's incipient 310-helical peptide (1) is reported. Replacement of the N-terminal Aib residue of 1 with a ΔAA afforded peptides 2a-c that maintained the 310-helical shape of 1. In contrast, installation of a ΔAA in place of Aib-3 yielded peptides 3a-c that preferred a β-sheet-like conformation. The impact of the ΔAA on peptide structure was independent of size, with small (ΔAla), medium-sized (Z-ΔAbu), and bulky (ΔVal) ΔAAs exerting similar effects. The proteolytic stabilities of 1 and its analogs were determined by incubation with Pronase. Z-ΔAbu and ΔVal increased the resistance of peptides to proteolysis when incorporated at the 3-position and had negligible impact on stability when placed at the 1-position, whereas ΔAla-containing peptides degraded rapidly regardless of position. Exposure of peptides 2a-c and 3a-c to the reactive thiol cysteamine revealed that ΔAla-containing peptides underwent conjugate addition at room temperature, while Z-ΔAbu- and ΔVal-containing peptides were inert even at elevated temperatures. These results suggest that both bulky and more accessible medium-sized ΔAAs should be valuable tools for bestowing rigidity and proteolytic stability on bioactive peptides.
Authors: Matthew P Sarnowski; Chang Won Kang; Yassin M Elbatrawi; Lukasz Wojtas; Juan R Del Valle Journal: Angew Chem Int Ed Engl Date: 2017-01-20 Impact factor: 15.336
Authors: Nikolaj L Villadsen; Bente K Hansen; Esben B Svenningsen; Katrine H Jørgensen; Thomas Tørring; Thomas B Poulsen Journal: J Org Chem Date: 2018-05-18 Impact factor: 4.354
Authors: G Pagani Zecchini; M Paglialunga Paradisi; I Torrini; G Lucente; E Gavuzzo; F Mazza; G Pochetti; M Paci; M Sette; A Di Nola Journal: Biopolymers Date: 1993-03 Impact factor: 2.505
Authors: Daniel Joaquin; Michael A Lee; David W Kastner; Jatinder Singh; Shardon T Morrill; Gracie Damstedt; Steven L Castle Journal: J Org Chem Date: 2019-11-25 Impact factor: 4.354
Authors: Diego A Moyá; Michael A Lee; Joseph C Chanthakhoun; Austin K LeSueur; Daniel Joaquin; Jaden D Barfuss; Steven L Castle Journal: Tetrahedron Lett Date: 2021-05-10 Impact factor: 2.032
Authors: Peter J Jervis; Carolina Amorim; Teresa Pereira; José A Martins; Paula M T Ferreira Journal: Int J Mol Sci Date: 2021-03-03 Impact factor: 5.923