Probing the Directionality of S···O/N Chalcogen Bond and Its Interplay with Weak C–H···O/N/S Hydrogen Bond Using Molecular Electrostatic Potential

Adhav, Vishal Annasaheb; Balanarayan, P.; Saikrishnan, K.

doi:10.1021/acs.jpcb.2c03745

Cited by 5 publications

(7 citation statements)

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“…We believe that the revolutionary improvement in the resolution of 3D structural data of proteins determined using cryoEM will aid in the identification of unconventional noncovalent interactions in proteins and reveal new roles of these interactions in protein function. With many more protein structures being determined at very- and ultra-high resolution, use of charge-density analysis combined with detailed quantum chemical calculations, such as Atoms In Molecule analysis, will provide unprecedented insights into the nature and function of noncovalent interactions in proteins. ,, We believe that with newer and improved experimental and computational techniques being used for probing noncovalent interactions in small molecules and proteins, our understanding of the nature of these interactions, their role, and significance is only on the rise.…”

Section: Discussionmentioning

confidence: 99%

“…A more comprehensive analysis revealed that the divalent S preferred to approach the π region over the lone pair region of carbonyl O, indicating the importance of directionality for the formation of the interaction in proteins . A recent study showed that this directional selectivity originates from the electrostatic and cooperative nature of the Ch-bond . Also, 1.3% and 8.9% of methionine and cysteine in proteins could participate in Ch-bond formation, respectively, suggesting their role in stabilizing protein structures .…”

Section: σ-Hole Interactionmentioning

confidence: 99%

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The Realm of Unconventional Noncovalent Interactions in Proteins: Their Significance in Structure and Function

Adhav

Saikrishnan

2023

ACS Omega

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Proteins and their assemblies are fundamental for living cells to function. Their complex three-dimensional architecture and its stability are attributed to the combined effect of various noncovalent interactions. It is critical to scrutinize these noncovalent interactions to understand their role in the energy landscape in folding, catalysis, and molecular recognition. This Review presents a comprehensive summary of unconventional noncovalent interactions, beyond conventional hydrogen bonds and hydrophobic interactions, which have gained prominence over the past decade. The noncovalent interactions discussed include low-barrier hydrogen bonds, C5 hydrogen bonds, C–H···π interactions, sulfur-mediated hydrogen bonds, n → π* interactions, London dispersion interactions, halogen bonds, chalcogen bonds, and tetrel bonds. This Review focuses on their chemical nature, interaction strength, and geometrical parameters obtained from X-ray crystallography, spectroscopy, bioinformatics, and computational chemistry. Also highlighted are their occurrence in proteins or their complexes and recent advances made toward understanding their role in biomolecular structure and function. Probing the chemical diversity of these interactions, we determined that the variable frequency of occurrence in proteins and the ability to synergize with one another are important not only for ab initio structure prediction but also to design proteins with new functionalities. A better understanding of these interactions will promote their utilization in designing and engineering ligands with potential therapeutic value.

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Section: Discussionmentioning

confidence: 99%

Section: σ-Hole Interactionmentioning

confidence: 99%

The Realm of Unconventional Noncovalent Interactions in Proteins: Their Significance in Structure and Function

Adhav

Saikrishnan

2023

ACS Omega

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“…Hence, we conclude that S-mediated Ch- and H-bonds, like other weak interactions, are an essential aspect of the energy landscape in protein folding that compensates for unfavourable conformational entropy changes through favourable interactions (Grantcharova et al, 2001 ; Dobson, 2003 ). Furthermore, we envisage that cooperativity among S-mediated and other weak interactions is likely to modulate their strengths with direct implications for protein function, which remains to be studied (Adhav et al, 2022 ). For example, we speculate that the propensity and strength of Ch-bonds would increase upon the delocalisation of lone-pair electron density of Cys-S γ to form an n → π* interaction with a vicinal carbonyl group (Kilgore and Raines, 2018 ).…”

Section: Discussionmentioning

confidence: 99%

Sulfur-mediated chalcogen versus hydrogen bonds in proteins: a see-saw effect in the conformational space

et al. 2023

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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.

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“…interactions, first studied by Rosenfield, involve a weak coordination bond between a lone pair of the heteroatom X and a σ-hole on the divalent S atom (Scheme ). − The use of the S···X interaction as a driving force for organic supramolecular chromophore assembly in the solution phase has not been explored previously, although these interactions have been exploited in the assembly of organic semiconductors in the solid state, , supramolecular capsules, , and polymers in solution and to enhance intramolecular electron transfer rates in dye-sensitized solar cells …”

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confidence: 99%

“…We hypothesize that the sulfide group in P-S plays a key role in inducing π-stacking in the excited state. Given that divalent sulfide is known to engage in noncovalent interactions (S···X) by coordinating with heteroatoms X such as O, N, or S, − an intermolecular S···X interaction is proposed to occur between P-S molecules. This intermolecular S···X interaction can be a factor contributing to the supramolecular organization of P-S .…”

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confidence: 99%

Light-Controlled Switching of Perylene Bisimide Assemblies

Bahng,

Ertl,

Yuan

et al. 2023

J. Phys. Chem. Lett.

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Light-driven changes in supramolecular interactions in perylene bisimides (PBIs) with pendant sulfur-containing functional groups at the bay position are demonstrated. In the ground state, a noncovalent S•••X interaction between the σ-hole on sulfur and a heteroatom, X (X = O, N, S), of a neighboring molecule is the main driving force for intermolecular interactions, while in the excited state it is the π−π interaction between PBI scaffolds which drives assembly. The presence of heteroatoms in the solvent results in acceleration of the π-stacking process via the formation of a PBI−solvent complex. The excited-state dynamics involved in the assembly process were revealed via time-resolved fluorescence and transient absorption spectroscopies, while steadystate spectroscopy was used to evaluate the structure of the supramolecular assembly.

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Probing the Directionality of S···O/N Chalcogen Bond and Its Interplay with Weak C–H···O/N/S Hydrogen Bond Using Molecular Electrostatic Potential

Cited by 5 publications

References 84 publications

The Realm of Unconventional Noncovalent Interactions in Proteins: Their Significance in Structure and Function

The Realm of Unconventional Noncovalent Interactions in Proteins: Their Significance in Structure and Function

Sulfur-mediated chalcogen versus hydrogen bonds in proteins: a see-saw effect in the conformational space

Light-Controlled Switching of Perylene Bisimide Assemblies

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