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Overexpression of histone deacetylase (HDAC) enzymes is linked to a wide variety of illnesses, including malignancies and neurological disorders, which makes HDAC inhibitors potentially therapeutic. However, most HDAC inhibitors lack subclass or isoform selectivity, which can be dangerous. Featuring both enhanced selectivity and toxicity profiles, slow-binding HDAC inhibitors offer promising treatment options for a variety of disorders. Diseases like cardiac, neurodegenerative disorders and diabetes are mainly associated with the HDAC1, HDAC2 and HDAC3 enzymes. The AI-based virtual screening tool PyRMD is implemented to identify the potential inhibitors from ∼2 million compounds. Based on the IC50 values, the top 10 compounds were selected for molecular docking. From the docking and ADMET study, the top-ranked three compounds were selected for molecular dynamics (MD) simulations. Further, to get more insights into the binding/unbinding mechanism of the ligand, we have employed the steered molecular dynamics (SMD) simulations. This study assists in developing Amber force field parameters for the HDAC1, HDAC2 and HDAC3 proteins and sheds light on the discovery of a potent drug. Our study suggests that hydroxamic acid derivative (i.e. referred to as Comp-1, CHEMBL600072) is the potential inhibitor for the series of HDAC-related diseases.Communicated by Ramaswamy H. Sarma.

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Matrix metalloproteinase-9 (MMP-9) is an attractive target for anticancer therapy. In the present study ligand based pharmacophore modeling was performed to elucidate the structural elements for a diverse class of MMP-9 inhibitors. The pharmacophore model was validated through Güner-Henry (GH) scoring method. The final pharmacophore model consisted of three hydrogen bond acceptors (HBA), and two ring aromatic regions (RA). This model was utilized to screen the natural compound database to seek novel compounds as MMP-9 inhibitors. The identified hits were validated using molecular docking and molecular dynamics simulation studies. Finally, one compound named Hinokiflavone from Juniperus communis had high binding free energy of -26.54kJ/mol compared with the known inhibitors of MMP-9. Cytotoxicity for hinokiflavone was evaluated by MTT assay. Inhibition of MMP-9 in the presence of hinokiflavone was detected by gelatin zymography and gelatinolytic inhibition assay. Results revealed that the natural compounds derived based on the developed pharmacophore model would be useful for further design and development of MMP-9 inhibitors.

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Although several models have been proposed for the interaction of collagen with gelatinase-A (matrix metalloproteinases-2 (MMP-2)), the extensive role of each domain of gelatinase A in hydrolyzing the collagens with and without interruptions is still elusive. Molecular docking, molecular dynamics (MD) simulation, normal mode analysis (NMA) and framework rigidity optimized dynamics algorithm (FRODAN) based analysis were carried out to understand the function of various domains of MMP-2 upon interaction with collagen like peptides. The results reveal that the collagen binding domain (CBD) binds to the C-terminal of collagen like peptide with interruption. CBD helps in unwinding the loosely packed interrupted region of triple helical structure to a greater extent. It can be possible to speculate that the role of hemopexin (HPX) domain is to prevent further unwinding of collagen like peptide by binding to the other end of the collagen like peptide. The catalytic (CAT) domain then reorients itself to interact with the part of the unwound region of collagen like peptide for further hydrolysis. In conclusion the CBD of MMP-2 recognizes the collagen and aids in unwinding the collagen like peptide with interruptions, and the HPX domain of MMP-2 binds to the other end of the collagen allowing CAT domain to access the cleavage site. This study provides a comprehensive understanding of the structural basis of collagenolysis by MMP-2.

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The active site geometry of cytochrome (Cyt) c(551) and its mutated form containing Fe(II) and Fe(III) ions have been calculated using density functional theory (DFT)-based Becke's three-parameter hybrid exchange and Lee-Yang-Parr correlation (B3LYP) method. In addition, calculations have also been carried out using hybrid meta DFT-based M06 functional. The effect of the protein milieu on the active site geometry has also been probed using two-layer via our own N-layered integrated molecular orbital + molecular mechanics (ONIOM) method. Evidence from the calculations reveal that the active site geometry is not significantly affected by the oxidation state of metal ion. The difference in the geometry of the active site and that of the same with the entire protein environment is only minimal, which shows that the protein milieu does not influence the structure of the active site. The calculated electronic transition energies from the time-dependent DFT (TDDFT) calculations are in close agreement with the experimental values. Although there are no significant variations in the active site geometry upon oxidation, the changes in the electronic transition energies have been attributed to the reduction in the overlap of metal ion with the ligand orbitals. In addition, it is found that mutation does not influence the active site geometry and the electronic transition energies. Nevertheless, mutation leads to the formation of more compact structure than the native Cyt c(551).

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Harmonic force field (FF) parameters for the active site of native azurin (AZ) have been developed using density functional theory (DFT)-based Becke's three-parameter hybrid exchange functional and the Lee-Yang-Parr correlation functional (B3LYP) method. The same computational protocol has also been applied to derive the FF parameters for the metal ion-substituted [Co(II) and Ni(II)] AZs. To validate the new set of FF parameters for the metal sites, molecular dynamics (MD) simulations on native, loop-contracted, and metal ion-substituted AZs have been carried out for 10 ns using AMBER parameters for the remaining part of the proteins. The average structure obtained from the MD simulation for native protein is akin to that of X-ray diffraction studies. Results from the in silico loop variation reveal that the active site of AZ is almost unaffected by the loop contraction in accordance with the previous experimental findings. However, the inherent hydrogen-bonded network of the metal site of AZ is affected by the loop contraction. Comparison of the average structures obtained from the MD simulations for the metal ion-substituted proteins with the corresponding X-ray diffraction structures shows that there are no major differences between two systems. Nevertheless, the metal ion binding site undergoes significant changes due to metal ion-substitution. Results clearly demonstrate the usefulness of a new set of FF parameters in the engineering and redesign of blue copper proteins.

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In this study an attempt has been made to investigate the effect of metal ion substitution on the structure and spectra of azurin using two-layer ONIOM (our own N-layered integrated molecular orbital + molecular mechanics) approach. It is evident from the results that the overall structure of the protein is not altered by metal ion substitution; nevertheless, the metal ion binding site undergoes noticeable changes. The present study highlights the importance of protein milieu in the prediction of structure, electronic, and spectral properties of native and substituted azurins and illustrates the usefulness of ONIOM approach in the designing and engineering of metalloproteins.

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