In silico prediction suggests inhibitory effect of halogenated boroxine on human catalase and carbonic anhydrase

In silico prediction suggests inhibitory effect of halogenated boroxine on human catalase and carbonic anhydrase

Background This research work included bioinformatics modeling of the dipotassium-trioxohydroxytetrafluorotriborate-halogenated boroxine molecule, as well as simulation and prediction of structural interactions between the halogenated boroxine molecule, human carbonic anhydrase, and human catalase s...

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Bibliographic Details
Published in:Journal of Genetic Engineering and Biotechnology Vol. 20; no. 1; pp. 153 - 11
Main Authors: Corbo, Tarik, Kalajdzic, Abdurahim, Delic, Dzelila, Suleiman, Sumaia, Pojskic, Naris
Format: Journal Article
Language:English
Published: Cairo Springer 01-12-2022
Springer Nature B.V
Springer Berlin Heidelberg
Elsevier
Subjects:
Analysis
Apoptosis
Banks (Finance)
Binding sites
Bioinformatics
Carbonic anhydrase
Carbonic anhydrases
Catalase
Cell culture
Computer applications
Crystal structure
Crystals
Dipotassium-trioxohydroxytetrafluorotriborate
Enzymes
Halogenated boroxine
Human carbonic anhydrase
Human catalase
Hydrogen peroxide
In silico
Inhibitory
Ligands
Metastasis
Molecular docking
Molecular structure
Pharmacogenomics
Proteins
Structure
Tumors
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Summary:Background This research work included bioinformatics modeling of the dipotassium-trioxohydroxytetrafluorotriborate-halogenated boroxine molecule, as well as simulation and prediction of structural interactions between the halogenated boroxine molecule, human carbonic anhydrase, and human catalase structures. Using computational methods, we tried to confirm the inhibitory effect of halogenated boroxine on the active sites of these previously mentioned enzymes. The three-dimensional crystal structures of human catalase (PDB ID: 1DGB) and human carbonic anhydrase (PDB ID: 6FE2) were retrieved from RCSB Protein Data Bank and the protein preparation was performed using AutoDock Tools. ACD/ChemSketch and ChemDoodle were used for creating the three-dimensional structure of halogenated boroxine. Molecular docking was performed using AutoDock Vina, while the results were visualized using PyMOL. Results Results obtained in this research are showing evidence that there are interactions between the halogenated boroxine molecule and both previously mentioned proteins (human carbonic anhydrase and human catalase) in their active sites, which led us to the conclusion that the inhibitory function of halogenated boroxine has been confirmed. Conclusion These findings could be an important step in determining the exact mechanisms of inhibitory activity and will hopefully serve in further research purposes of complex pharmacogenomics studies.
ISSN:1687-157X
2090-5920
DOI:10.1186/s43141-022-00437-x