Vanadium–Flavonoid Complexes: A Promising Class of Molecules for Therapeutic Applications

Selvaraj, Stalin; Krishnan, Uma Maheswari

doi:10.1021/acs.jmedchem.1c00405

Cited by 32 publications

(17 citation statements)

References 137 publications

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“…There is currently a large research effort in the identification of the biological mechanisms of action of food compounds from a molecular point of view in order to find novel nutraceuticals and scaffolds for drug design, − as well as understanding the beneficial or harmful effects of foods on human health. − A paradigm of this is caffeine, which has been applied as a template to develop adenosine receptor antagonists and cyclic nucleotide phosphodiesterase inhibitors, among other biological targets . For that aim, biochemical and/or biological (cellular) assays directed toward different biological targets (typically proteins) are being conducted, allowing specific protein-food compound interactions to be identified.…”

Section: Introductionmentioning

confidence: 99%

Systematic Analysis and Prediction of the Target Space of Bioactive Food Compounds: Filling the Chemobiological Gaps

Sánchez-Ruiz

Colmenarejo

2022

J. Chem. Inf. Model.

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Food compounds and their molecular interactions are crucial for health and provide new chemotypes and targets for drug and nutraceutic design. Here, we retrieve and analyze the complete set of published interactions of food compounds with human proteins using the FooDB as a compound set and ChEMBL as a source of interactions. The data are analyzed in terms of 19 target classes and 19 compound classes, showing a small fraction of target assignment for the compounds (1.6%) and unraveling multiple gaps in the chemobiological space for these molecules. By using well-established cheminformatic approaches [similarity ensemble approach (SEA) combined with the maximum Tanimoto coefficient to the nearest bioactive, “SEA + TC”], we achieve a much enhanced target assignment (64.2%), filling many of the gaps with target hypothesis for fast focused testing. By publishing these data sets and analyses, we expect to provide a set of resources to speed up the full clarification of the chemobiological space of food compounds, opening new opportunities for drug and nutraceutic design.

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Section: Introductionmentioning

confidence: 99%

Systematic Analysis and Prediction of the Target Space of Bioactive Food Compounds: Filling the Chemobiological Gaps

Sánchez-Ruiz

Colmenarejo

2022

J. Chem. Inf. Model.

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“…In recent years, the coordination chemistry of vanadium has drawn a lot of interest, mainly due to its biological, medicinal and catalytic applications. − Vanadium exhibits a wide variety of oxidation states (−III to + V), with the oxidation states of +III to +V mainly found in molecular systems of biological relevance. Enzymes, such as the vanadium-dependent haloperoxidases found in algae, are able to utilize vanadium’s wide range of oxidation states in order to oxidize halides in nature .…”

Section: Introductionmentioning

confidence: 99%

A Combined Experimental and Theoretical Investigation of Oxidation Catalysis by cis-[V^IV(O)(Cl/F)(N₄)]⁺ Species Mimicking the Active Center of Metal-Enzymes

et al. 2022

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Reaction of VIVOCl2 with the nonplanar tetradentate N4 bis-quinoline ligands yielded four oxidovanadium(IV) compounds of the general formula cis-[VIV(O)(Cl)(N4)]Cl. Sequential treatment of the two nonmethylated N4 oxidovanadium(IV) compounds with KF and NaClO4 resulted in the isolation of the species with the general formula cis-[VIV(O)(F)(N4)]ClO4. In marked contrast, the methylated N4 oxidovanadium(IV) derivatives are inert toward KF reaction due to steric hindrance, as evidenced by EPR and theoretical calculations. The oxidovanadium(IV) compounds were characterized by single-crystal X-ray structure analysis, cw EPR spectroscopy, and magnetic susceptibility. The crystallographic characterization showed that the vanadium compounds have a highly distorted octahedral coordination environment and the d(VIV–F) = 1.834(1) Å is the shortest to be reported for (oxido)(fluorido)vanadium(IV) compounds. The experimental EPR parameters of the VIVO2+ species deviate from the ones calculated by the empirical additivity relationship and can be attributed to the axial donor atom trans to the oxido group and the distorted VIV coordination environment. The vanadium compounds act as catalysts toward alkane oxidation by aqueous H2O2 with moderate ΤΟΝ up to 293 and product yields of up to 29% (based on alkane); the vanadium(IV) is oxidized to vanadium(V), and the ligands remain bound to the vanadium atom during the catalysis, as determined by 51V and 1H NMR spectroscopies. The cw X-band EPR studies proved that the mechanism of the catalytic reaction is through hydroxyl radicals. The chloride substitution reaction in the cis-[VIV(O)(Cl)(N4)]+ species by fluoride and the mechanism of the alkane oxidation were studied by DFT calculations.

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“…The redox potential of V(V) to V(IV) or V(IV) to V(III) have made vanadium a versatile metal in the biological and medicinal applications. [86][87][88][89][90] Under in vitro conditions, vanadium compounds stimulate glucose uptake and inhibit lipid breakdown, in a way remarkably suggestive of insulin's effects. Under in vivo conditions, vanadium improves insulin's plasma glucose and lipid-lowering properties, leading to normalization of diabetic symptoms in the presence of only minimal endogenous insulin.…”

Section: Tetravalent Metal Complexes As Aglucosidase Inhibitorsmentioning

confidence: 99%

A review on α-glucosidase inhibitory activity of first row transition metal complexes: a futuristic strategy for treatment of type 2 diabetes

et al. 2022

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Vanadium–Flavonoid Complexes: A Promising Class of Molecules for Therapeutic Applications

Cited by 32 publications

References 137 publications

Systematic Analysis and Prediction of the Target Space of Bioactive Food Compounds: Filling the Chemobiological Gaps

Systematic Analysis and Prediction of the Target Space of Bioactive Food Compounds: Filling the Chemobiological Gaps

A Combined Experimental and Theoretical Investigation of Oxidation Catalysis by cis-[V^IV(O)(Cl/F)(N₄)]⁺ Species Mimicking the Active Center of Metal-Enzymes

A review on α-glucosidase inhibitory activity of first row transition metal complexes: a futuristic strategy for treatment of type 2 diabetes

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Vanadium–Flavonoid Complexes: A Promising Class of Molecules for Therapeutic Applications

Cited by 32 publications

References 137 publications

Systematic Analysis and Prediction of the Target Space of Bioactive Food Compounds: Filling the Chemobiological Gaps

Systematic Analysis and Prediction of the Target Space of Bioactive Food Compounds: Filling the Chemobiological Gaps

A Combined Experimental and Theoretical Investigation of Oxidation Catalysis by cis-[VIV(O)(Cl/F)(N4)]+ Species Mimicking the Active Center of Metal-Enzymes

A review on α-glucosidase inhibitory activity of first row transition metal complexes: a futuristic strategy for treatment of type 2 diabetes

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A Combined Experimental and Theoretical Investigation of Oxidation Catalysis by cis-[V^IV(O)(Cl/F)(N₄)]⁺ Species Mimicking the Active Center of Metal-Enzymes