Divalent sulfur (S) forms a chalcogen bond (Ch-bond) via its σ-holes and a hydrogen bond (H-bond) via its lone pairs. The relevance of these interactions and their interplay for protein structure and function is unclear. Based on the analyses of the crystal structures of small organic/organometallic molecules and proteins and their molecular electrostatic surface potential, we show that the reciprocity of the substituent-dependent strength of the σ-holes and lone pairs correlates with the formation of either Ch-bond or H-bond. In proteins, cystines preferentially form Ch-bonds, metal-chelated cysteines form H-bonds, while methionines form either of them with comparable frequencies. This has implications for the positioning of these residues and their role in protein structure and function. Computational analyses reveal that the S-mediated interactions stabilise protein secondary structures by mechanisms such as helix capping and protecting free β-sheet edges by negative design. The study highlights the importance of S-mediated Ch-bond and H-bond for understanding protein folding and function, the development of improved strategies for protein/peptide structure prediction and design and structure-based drug discovery.
Divalent sulfur (S) form chalcogen bond (Ch-bond) via its σ-holes and hydrogen bond (H-bond) via its lone-pairs. Relevance of these interactions and their interplay for protein structure and function is unclear. Based on the analyses of the crystal structures of small organic/organometallic molecules and proteins, and their Molecular Electrostatic Surface Potential, we show that the reciprocity of the substituent-dependent strength of the σ-holes and lone-pairs correlate with the formation of either Ch-bond or H-bond. In proteins, disulfide-bonded cystine preferentially forms Ch-bond, metal-chelated cysteine forms H-bond, while methionine forms either of them with comparable frequencies. This has implications to the positioning of these residues and their role in protein structure and function. Computational analyses reveal that the S-mediated interactions stabilize protein secondary structures by mechanisms such as helix capping, protecting free β-sheet edges by negative-design, and augmenting the stability of β-turns. We find that Ch-bond can be as strong as H-bond. The study highlights the importance of S-mediated Ch-bond and H-bond for understanding protein folding and function, development of improved strategies for protein/peptide structure prediction and design, and structure-based drug discovery.
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