The properties of substituted 3D-aromatic neutral carboranes: the potential for σ-hole bonding

Lo, Rabindranath; Fanfrlík, Jindřich; Lepšı́k, Martin; Hobza, Pavel

doi:10.1039/c5cp03617h

Cited by 28 publications

(26 citation statements)

References 53 publications

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“…Recently, we studied the properties of halogenated carboranes using quantum mechanics (QM) methods. These calculations showed that halogenated carboranes had large and highly positive σ‐holes when an X atom was covalently attached to the C‐vertex of a neutral carborane molecule …”

Section: Figurementioning

confidence: 99%

Competition between Halogen, Hydrogen and Dihydrogen Bonding in Brominated Carboranes

et al. 2016

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Halogen bonds are a subset of noncovalent interactions with rapidly expanding applications in materials and medicinal chemistry. While halogen bonding is well known in organic compounds, it is new in the field of boron cluster chemistry. We have synthesized and crystallized carboranes containing Br atoms in two different positions, namely, bound to C- and B-vertices. The Br atoms bound to the C-vertices have been found to form halogen bonds in the crystal structures. In contrast, Br atoms bound to B-vertices formed hydrogen bonds. Quantum chemical calculations have revealed that halogen bonding in carboranes can be much stronger than in organic architectures. These findings open new possibilities for applications of carboranes, both in materials and medicinal chemistry.

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Section: Figurementioning

confidence: 99%

Competition between Halogen, Hydrogen and Dihydrogen Bonding in Brominated Carboranes

et al. 2016

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“…The strength of σ‐hole bonding can be inferred from the σ‐hole magnitude (V S,max ), which is defined as the most positive value of the ESP surface . The more positive the V S,max value, the stronger the X‐bond ,. The V S,max value depends on various characteristics of moieties appended to the X‐containing molecule, such as polarisability, electronegativity and electron‐withdrawing capability .…”

Section: Introductionmentioning

confidence: 99%

“…The more positive the V S,max value, the stronger the X‐bond ,. The V S,max value depends on various characteristics of moieties appended to the X‐containing molecule, such as polarisability, electronegativity and electron‐withdrawing capability . The properties of a σ‐hole (such as the V S,max value) can thus be modulated by substituting certain moieties on the molecule of interest.…”

Section: Introductionmentioning

confidence: 99%

Chalcogen Bonding in Protein−Ligand Complexes: PDB Survey and Quantum Mechanical Calculations

2018

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A chalcogen bond is a nonclassical noncovalent interaction which can stabilise small-molecule crystals as well as protein structures. Here, we systematically explore the stabilising potential of chalcogen bonding in protein-ligand complexes in the Protein Data Bank (PDB). We have found that a large fraction (23 %) of complexes with a S/Se-containing ligand feature close S/Se⋅⋅⋅O/N/S contacts. Eleven non-redundant representative potential S/Se⋅⋅⋅O chalcogen-bond motifs were selected and truncated to model systems and seven more model systems were prepared by S-to-Se substitution. These systems were then subjected to analysis by quantum chemical (QM) methods-electrostatic potential, geometry optimisation or interaction energy calculations, including solvent effects. The QM calculations indicate that chalcogen bonding does indeed play a dominant role in stabilising some of the interaction motifs studied. We thus advocate further exploration of chalcogen bonding with the aim of potential future use in structure-based drug design.

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“…Therefore, in YBs, as well as in other non-covalent interactions, the importance of the electrostatic interaction term is uppermost [426,437]. Several works have been carried out regarding the tunability of the mentioned σ -holes in different types of interactions, including halogen, chalcogen, and pnicogen [438,439,440,441]. In particular, the effect on the σ -hole upon substitution on aromatic rings has been previously studied [438,442,443,444].…”

Section: The Importance In Drug Design Of Similar To Hb Bondsmentioning

confidence: 99%

It Is Important to Compute Intramolecular Hydrogen Bonding in Drug Design?

Yunta¹

2017

AJMO

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The effect of weak intermolecular interactions on the binding affinity between ligand-protein complexes plays an important role in stabilizing a ligand at the interface of a protein structure. In this review article, we will explore the different ways of taking into account these interactions, mainly intramolecular hydrogen bonds, in docking calculations. Their possible limitations and their suitable application domains are highlighted. Inspection of the outliers of this study probed very stimulating, as it provides opportunities and inspiration to medicinal chemists, being a reminder of the impact that minimal chemical modifications can have on biological activities.

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The properties of substituted 3D-aromatic neutral carboranes: the potential for σ-hole bonding

Cited by 28 publications

References 53 publications

Competition between Halogen, Hydrogen and Dihydrogen Bonding in Brominated Carboranes

Competition between Halogen, Hydrogen and Dihydrogen Bonding in Brominated Carboranes

Chalcogen Bonding in Protein−Ligand Complexes: PDB Survey and Quantum Mechanical Calculations

It Is Important to Compute Intramolecular Hydrogen Bonding in Drug Design?

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