Bioinformatics analysis and molecular dynamics simulations of azoreductases (AzrBmH2) from Bacillus megaterium H2 for the decolorization of commercial dyes

The present study aimed to investigate the decolorization of various commercial dyes by azoreductases (AzrBmH21, AzrBmH22/3, and AzrBmH24/5) through bioinformatics means, comprising molecular docking, molecular dynamics simulation, and molecular mechanics Poisson–Boltzmann surface area (MM-PBSA). Th...

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Published in:Environmental sciences Europe 2024-12, Vol.36 (1), p.31-31, Article 31
Main Authors: Oyewusi, Habeebat Adekilekun, Wahab, Roswanira Abdul, Akinyede, Kolajo Adedamola, Albadrani, Ghadeer M., Al-Ghadi, Muath Q., Abdel-Daim, Mohamed M., Ajiboye, Basiru Olaitan, Huyop, Fahrul
Format: Article
Language:English
Subjects:
acid orange 7
Active sites
Algorithms
Amino acids
Azoreductases
Bacillus megaterium
Binding sites
Biocatalysts
Bioinformatics
Bioremediation
Biotechnology
Cresols
Decoloring
Decolorization
Degradation
Dyes
Earth and Environmental Science
Ecotoxicology
energy
Environment
hydrogen
Hydrogen bonding
Hydrogen bonds
Hydrophobicity
Ligands
Machine learning
Malachite green
mechanics
Methylene blue
Molecular docking
Molecular dynamics
Molecular dynamics simulation
Orange II
Pollution
prediction
Simulation
surface area
Synthetic dyes
Van der Waals forces
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Summary:The present study aimed to investigate the decolorization of various commercial dyes by azoreductases (AzrBmH21, AzrBmH22/3, and AzrBmH24/5) through bioinformatics means, comprising molecular docking, molecular dynamics simulation, and molecular mechanics Poisson–Boltzmann surface area (MM-PBSA). Therefore, four commercial dyes, namely acid orange 7, cresol red, methylene blue, and malachite green, were selected as potential targets for degradation by the above said azoreductases derived from Bacillus megaterium H2. The prediction of ligand binding or catalytic sites for AzrBmH21, AzrBmH22/3, and AzrBmH24/5 were performed using a machine learning algorithm based on the Prank Web and DeepSite chemoinformatic tool. This analysis revealed that several amino acids of AzrBmH2 interacted with the tested dyes, indicating the presence of distinct ligand-binding sites for AzrBmH2-dye complexes. Likewise, the binding affinity for AzrBmH21, AzrBmH22/3, and AzrBmH24/5 ranged from − 9.4 to − 5.5 kcal/mol, − 9.2 to − 5.4 kcal/mol, and − 9.0 to − 5.4 kcal/mol, respectively, with each complex stabilized at a minimum of 0–5 hydrogen bonds. MD simulations revealed stable AzrBmH2-dye complexes with RMSD and RMSF values ranging from 0.15 to 0.42 nm and 0.05 to 0.48 nm, respectively, with Rg values between 1.75 and 1.88 nm. MM-PBSA calculations indicated that the AzrBmH2–dye complexes, except for AzrBmH2–malachite green, exhibited the lowest binding energy (− 191.05 ± 7.08 to 314.19 ± 6.88 kcal/mol), with prevalent hydrophobic interactions (− 268.25 ± 12.25 to − 418.92 ± 29.45 kcal/mol) through van der Waals forces. Therefore, this study was able to highlight the potential role of enzymes, specifically azoreductases from Bacillus megaterium H2, in predicting the decolorization of commercial dyes. These findings could contribute to our understanding of the azoreductases’ mechanisms in bioremediation and for biotechnological applications.
ISSN:2190-4715
2190-4715
DOI:10.1186/s12302-024-00853-5