Helically Chiral Peptides That Contain Ferrocene‐1,1′‐diamine Scaffolds as a Turn Inducer

A series of peptides that contain homo‐ and heterochiral Ala−Pro sequences attached to the turn‐inducing ferrocene‐1,1′‐diamine scaffold were synthesized. The effects of the backbone chirality and the N‐terminal group (Boc/Ac) on the conformational properties of the novel peptidomimetics were thoroughly explored by IR, NMR, and CD spectroscopy and the experimental observations were corroborated by DFT studies in solution. The most stable conformers of the homochiral peptides adopted the interstrand hydrogen‐bond patterns, realized through ten‐ and thirteen‐membered rings. The common feature of the most stable conformers of the heterochiral peptides was the adoption of the turn‐like structures that feature the simultaneous intra‐ (seven‐membered) and interstrand (sixteen‐membered) hydrogen‐bonded rings. An exchange of two N‐terminal groups had a somewhat larger influence on the distribution of the hydrogen‐bond patterns in homochiral than in heterochiral derivatives. The homochiral peptides that contain pyridine moieties as metal coordination sites formed 1:1 complexes with divalent metal ions, which included Zn2+, Cd2+, Cu2+ and Fe2+. Turn a different corner: The effects of the backbone chirality and N‐terminal group (Boc/Ac) on the conformational properties of peptides that contain homo‐ and heterochiral Ala−Pro sequences attached to the turn‐inducing ferrocene‐1,1′‐diamine scaffold are thoroughly explored by IR, NMR, and CD spectroscopy and single‐crystal X‐ray analysis; the experimental observations are corroborated by DFT studies in solution (see figure).