Strong orbital interaction in a weak CH-π hydrogen bonding system

Li, Jianfu; Qi, Fei

doi:10.1038/srep22304

Cited by 21 publications

(12 citation statements)

References 49 publications

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“…Several molecular orbital energy gaps having the capacity to be a significant part of the theoretical model is also consistent with recent reports that the CH-π interaction involves strong interactions among multiple molecular orbitals of the interacting fragments. 39 , 40 This type of multivalent frontier molecular orbital interaction is compatible with the notion that CH-π interactions in the WW domain system may involve overlap between multiple CH antibonding orbitals (σ* CH ) of the sugar and bonding (π) orbitals of the aromatic interactor moieties that are overrepresented in the dataset. 47 Effects similar to this have been previously observed in interaction between methyl CHs and the π system of carbonyl groups in proteins.…”

Section: Resultssupporting

confidence: 75%

“…Inclusion of the frontier MO energy gaps in the descriptor set was motivated by the recent reports that CH-π interactions involve strong interactions among MOs of the CH and π system. 39 , 40 The probability of MOs being involved in interfragmentary dispersion and orbital interactions depends on the energy gap between the interacting MOs, among other factors. Accurate descriptions of dispersion interactions have been successfully calculated using models incorporating both occupied and unoccupied orbitals.…”

Section: Resultsmentioning

confidence: 99%

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Stereoelectronic effects in stabilizing protein–N-glycan interactions revealed by experiment and machine learning

2021

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The energetics of protein-carbohydrate interactions, central to many life processes, cannot yet be predictably manipulated. This is mostly due to an incomplete quantitative understanding of the enthalpic and entropic basis of these interactions in aqueous solution. Here, we show that stereoelectronic effects contribute significantly to stabilizing protein– N -glycan interactions in the context of a cooperatively folding protein. Double-mutant cycle analyses of the folding data from 52 electronically-varied N -glycoproteins demonstrate an enthalpy-entropy compensation depending on the electronics of the interacting side-chains. Linear and non-linear models obtained using quantum mechanical calculations and machine learning explain up to 79 and 97 % of the experimental interaction energy variability as inferred from the R 2 value of the respective models. Notably, protein-carbohydrate interaction energies strongly correlate with the molecular orbital energy gaps of the interacting substructures. This suggests that stereoelectronic effects must be given a greater weight than previously thought for accurately modelling the short-range dispersive van der Waals interactions between the N -glycan and the protein.

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Section: Resultssupporting

confidence: 75%

Section: Resultsmentioning

confidence: 99%

Stereoelectronic effects in stabilizing protein–N-glycan interactions revealed by experiment and machine learning

2021

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“…Obviously, d trans is much larger than d max , which means the C-H···π interaction cannot occur in trans -isomer while it is possible in cis -isomer. Moreover, the energy difference in Δ E a of AZO-GO before and after t c is about 1.38 Kcal/mol (0.06 eV), matching with the typical energy of C-H···π bonds 38 .…”

Section: Discussionmentioning

confidence: 52%

“…We would ascribe the origin of the two segments of linear dynamics during the trans -to- cis isomerization as a direct consequence of the existence of C-H···π interaction. When a cis -isomer comes into being, the C-H···π hydrogen bond makes the H atom of the AZO benzene moiety act like an electron donor, while the aromatic ring of the GO substrate beneath acts like an acceptor, which results in local electron-rich region in the GO surface 38 . The perturbations to the electronic structures of GO will enhance the polarizability of GO substrate.…”

Section: Discussionmentioning

confidence: 99%

A High Energy Density Azobenzene/Graphene Oxide Hybrid with Weak Nonbonding Interactions for Solar Thermal Storage

Pang

Xue

Pang

2019

Sci Rep

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Incorporating photochromic chromophores into polymer composites provides the possibility of a reversible photoswitch of the intrinsic properties of these materials. In this paper we report a route to attach azobenzene (AZO) moiety covalently to graphene oxide (GO) to create chromophore/graphene oxide (AZO-GO) hybrid, in which GO is both part of the chromophore and the template. Due to the high grafting density of AZO moiety and the low mass of the novel structure, the hybrid is a potential solar thermal storage material with high energy density of about 240 Wh·kg−1. It is found that C-H···π interaction between the cis-AZO chromophores and the aromatic rings of the substrate induces collective electronic modifications of GO at critical percentage of cis-isomers and reduce the thermal barrier of π-π* transition of the chromophores directly, which results in two sections of first-order reactions during the photoisomerization of trans- to cis-hybrid and also thermally stabilizes the cis-hybrid. Our findings demonstrate that high-performance AZO–GO hybrid can be manipulated by optimizing intermolecular nonbonding interactions.

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“…The investigation of the hydrogen-bonding interactions in mixtures of flavonoids and water/ethanol is particularly important to understand the mechanism of the extraction process and the physical essence of the mixture. Quantum chemical calculations have been widely and effectively used to study the intermolecular interactions theoretically 11 12 13 14 15 16 17 18 19 20 21 . In this work, the hydrogen-bonding interactions between ethanol/water and flavonoids were investigated from a theoretical perspective.…”

mentioning

confidence: 99%

Hydrogen-bonding Interactions between Apigenin and Ethanol/Water: A Theoretical Study

Zheng¹,

Zhou²,

Qin³

et al. 2016

Sci Rep

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In this work, hydrogen-bonding interactions between apigenin and water/ethanol were investigated from a theoretical perspective using quantum chemical calculations. Two conformations of apigenin molecule were considered in this work. The following results were found. (1) For apigenin monomer, the molecular structure is non-planar, and all of the hydrogen and oxygen atoms can be hydrogen-bonding sites. (2) Eight and seven optimized geometries are obtained for apigenin (I)–H2O/CH3CH2OH and apigenin (II)–H2O/CH3CH2OH complexes, respectively. In apigenin, excluding the aromatic hydrogen atoms in the phenyl substituent, all other hydrogen atoms and the oxygen atoms form hydrogen-bonds with H2O and CH3CH2OH. (3) In apigenin–H2O/CH3CH2OH complexes, the electron density and the E(2) in the related localized anti-bonding orbital are increased upon hydrogen-bond formation. These are the cause of the elongation and red-shift of the X−H bond. The sum of the charge change transfers from the hydrogen-bond acceptor to donor. The stronger interaction makes the charge change more intense than in the less stable structures. (4) Most of the hydrogen-bonds in the complexes are electrostatic in nature. However, the C4−O5···H, C9−O4···H and C13−O2···H hydrogen-bonds have some degree of covalent character. Furthermore, the hydroxyl groups of the apigenin molecule are the preferred hydrogen-bonding sites.

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Strong orbital interaction in a weak CH-π hydrogen bonding system

Cited by 21 publications

References 49 publications

Stereoelectronic effects in stabilizing protein–N-glycan interactions revealed by experiment and machine learning

Stereoelectronic effects in stabilizing protein–N-glycan interactions revealed by experiment and machine learning

A High Energy Density Azobenzene/Graphene Oxide Hybrid with Weak Nonbonding Interactions for Solar Thermal Storage

Hydrogen-bonding Interactions between Apigenin and Ethanol/Water: A Theoretical Study

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