Structural Criteria for the Design of Anion Receptors:  The Interaction of Halides with Electron-Deficient Arenes

Berryman, Orion B.; Bryantsev, Vyacheslav S.; Stay, David; Johnson, Darren W.; Hay, Benjamin P.

doi:10.1021/ja063460m

Cited by 306 publications

(325 citation statements)

References 47 publications

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“…This off-center geometry, which has been interpreted as a weak s motif, appears to be the preferred binding mode for the interaction of Br À with strongly electron-deficient aromatic rings. [6,9,40,41] This structural feature also characterizes the TNB-Br À complex (6) with an elongated CÀBr bond of 2.67 .…”

Section: Kj Molmentioning

confidence: 87%

“…[38,39] Insights into the structural features of the anion interaction with an aromatic ring in an isolated state have been obtained in recent theoretical work. [6,[40][41][42][43][44][45][46][47] Besides covalent bonding, noncovalent interactions have also been recognized. [6,44,48,49] Indeed, a variety of different complexes with different binding motifs are found, depending on the nature of the substituents on the aromatic or heteroaromatic ring and the nature of the anion, which have been classified as delivering: 1) strongly covalent s adducts (Meisenheimer complexes), 2) weakly covalent donor-p-acceptor complexes, and 3) noncovalent anion-p complexes.…”

Section: Introductionmentioning

confidence: 99%

“…[6,44,48,49] Indeed, a variety of different complexes with different binding motifs are found, depending on the nature of the substituents on the aromatic or heteroaromatic ring and the nature of the anion, which have been classified as delivering: 1) strongly covalent s adducts (Meisenheimer complexes), 2) weakly covalent donor-p-acceptor complexes, and 3) noncovalent anion-p complexes. [40,41] Furthermore, whenever feasible, complexes bound by hydrogen bonds also have to be taken into account. To identify the prevailing binding motif in an isolated complex, mass spectrometric means alone may not be adequate.…”

Section: Introductionmentioning

confidence: 99%

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Molecular Complexes of Simple Anions with Electron‐Deficient Arenes: Spectroscopic Evidence for Two Types of Structural Motifs for Anion–Arene Interactions

Chiavarino

Crestoni

Fornarini

et al. 2009

Chemistry A European J

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Anion-pi interactions between a pi-acidic aromatic system and an anion are gaining increasing recognition in chemistry and biology. Herein, the binding features of an electron-deficient aromatic system (1,3,5-trinitrobenzene (TNB)) and selected anions (OH-, Br-, and I-) are examined in the gas phase by using the combined information derived from collision-induced dissociation experiments at variable energy, infrared multiple-photon dissociation spectroscopy, and quantum chemical calculations. We provide spectroscopic evidence for two different structural motifs of anion-arene complexes depending on the nature of the anion. The TNB-OR- complexes (R=H, or alkyl groups which were studied earlier) adopt an anionic sigma-complex structure whereby RO- attacks the aromatic ring with covalent bond formation, and develops a tetrahedral ring carbon bound to H and OR. The halide complexes rather conform to a structure in which the TNB moiety is hardly altered, and the halogen is placed on an unsubstituted carbon atom over the periphery of the ring at a C-X distance that is appreciably longer than a typical covalent bond length. The ensuing structural motif, previously characterized in the solid state and named weak sigma interaction, is now confirmed by an IR spectroscopic assay in the gas phase, in which the sampled species are unperturbed by crystal packing or solvation effects.

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Section: Kj Molmentioning

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Molecular Complexes of Simple Anions with Electron‐Deficient Arenes: Spectroscopic Evidence for Two Types of Structural Motifs for Anion–Arene Interactions

Chiavarino

Crestoni

Fornarini

et al. 2009

Chemistry A European J

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“…An anion can interact with a p system through hydrogen bonding, noncovalent anion-p interactions and covalent r interactions. [59] For instance, chloride and azide anions interact with p system of striazine and trifluorotriazine molecules (anion-p interaction) while fluoride forms a covalent bond with an aryl carbon of these molecules (via covalent r interaction). [16] Interaction of simple anions with p electronic cloud of aromatics is enthalpically less favorable than that with aryl hydrogens.…”

Section: Anion-p Interactionmentioning

confidence: 99%

Functional molecules and materials by π‐Interaction based quantum theoretical design

Tehrani

Kim

2016

Int J of Quantum Chemistry

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The intermolecular and intramolecular noncovalent interactions involving p-aromatic compounds have attracted increasing attention over the last decades in chemistry, biology and material sciences. In this review, we discuss contemporary computational studies on the nature and strength of H-p, p-p, and anion-p interactions. We emphasize how modern quantum theoretical approaches ahead of experiment can provide insight into the design of new materials and devices by tuning the p-interactions in cooperative and competitive manners. Usefulness of such approaches towards designing new materials is demonstrated with some examples of molecular recognition/sensing, self-assembly/engineering, receptors, catalysts, supramolecules, graphene, and other two-dimensional (2D) materials/devices.

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“…These binding forces have been defined between negatively charged species and electron-deficient aromatic rings [93,94]. The C 60 -protein complexes presented herein, reveal high number of glutamic acid and aspartic acid residues in observed binding sites (~14% of all residues), and additionally, glutamic acid is the most numerous amino acid residue of all (see Fig.…”

Section: Characterization Of the Observed Fullerene C 60 -Protein Intmentioning

confidence: 63%

Rapid insight into C60 influence on biological functions of proteins

et al. 2017

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Experimental methods of investigations of nanoparticle (NP)-protein interactions are limited, because they require a high amount of samples and the NPs tend to interfere with spectral results. Therefore, molecular modeling is a commonly accepted tool in such kind of investigations. Examining the molecule toxicity on the molecular level, we usually want to know, mainly, the location of the ligand on the protein surface and what is an influence of such a contact on the biological functions of the protein. In the presented work, we demonstrate that multiple-docking of the ligand from a random start and with large grid volume, to let the ligand search the whole protein surface, allows to find the best binding sites and gives reliable results considering ligand-protein interactions. In the present work, we have constructed six models of bronchoalveolar lavage fluids proteins: α1-antitripsin, albumin, ceruloplasmin, lactoferrin, lysozyme, and transferrin with fullerene, C 60 utilizing molecular docking methods. The most probable results were examined with steered molecular dynamics (SMD) to see, if the simple docking method is able to predict the fullerene binding affinity. Albumin and lysozyme were already widely investigated and literature data is available for their complexes with fullerene C 60 and/or its derivatives. Thus, we used these two models as a reference set to validate the used molecular modeling methods. With our best knowledge, interactions of the remaining four proteins with NPs have never been investigated in detail before. Our results indicate that fullerene C 60 readily interacts with all studied proteins and may have a large impact on their biological functions.

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Structural Criteria for the Design of Anion Receptors: The Interaction of Halides with Electron-Deficient Arenes

Cited by 306 publications

References 47 publications

Molecular Complexes of Simple Anions with Electron‐Deficient Arenes: Spectroscopic Evidence for Two Types of Structural Motifs for Anion–Arene Interactions

Molecular Complexes of Simple Anions with Electron‐Deficient Arenes: Spectroscopic Evidence for Two Types of Structural Motifs for Anion–Arene Interactions

Functional molecules and materials by π‐Interaction based quantum theoretical design

Rapid insight into C60 influence on biological functions of proteins

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