Intrinsic folding of the cysteine residue: competition between compact and extended forms mediated by the -SH group

A dual microwave and optical spectroscopic study of a capped cysteine amino acid isolated in a supersonic expansion, combined with quantum chemistry modelling, enabled us to characterize the conformational preferences of Cys embedded in a protein chain. IR/UV double resonance spectroscopy provided evidence for the coexistence of two conformers, assigned to folded and extended backbones (with classical C7 and C5 backbone H-bonding respectively), each of them additionally stabilized by specific main-chain/side-chain H-bonding, where the sulfur atom essentially plays the role of H-bond acceptor. The folded structure was confirmed by microwave spectroscopy, which demonstrated the validity of the DFT-D methods currently used in the field. These structural and spectroscopic results, complemented by a theoretical Natural Bond Orbital analysis, enabled us to document the capacity of the weakly polar –CH2–SH side chain of Cys to adapt itself to the intrinsic local preferences of the peptide backbone, i.e., a γ-turn or a β-sheet extended secondary structure. The corresponding local H-bonding bridges the side chain acceptor S atom to the backbone NH donor site of the same or the next residue along the chain, through a 5- or a 6-membered ring respectively.