In Silico Insights into the Arsenic Binding Mechanism Deploying Application of Computational Biology-Based Toolsets.
Imran AhmadAnil Kumar SinghShayan MohdSudheer Kumar KatariRavina Madhulitha NalamoluAbrar AhmadOthman A BaothmanSalman A HosawiHisham N AltaybMuhammad Shahid NadeemVarish AhmadPublished in: ACS omega (2024)
An assortment of environmental matrices includes arsenic (As) in its different oxidation states, which is often linked to concerns that pose a threat to public health worldwide. The current difficulty lies in addressing toxicological concerns and achieving sustained detoxification of As. Multiple conventional degradation methods are accessible; however, they are indeed labor-intensive, expensive, and reliant on prolonged laboratory evaluations. Molecular interaction and atomic level degradation mechanisms for enzyme-As exploration are, however, underexplored in those approaches. A feasible approach in this case for tackling this accompanying concern of As might be to cope with undertaking multivalent computational methodologies and tools. This work aimed to provide molecular-level insight into the enzyme-aided As degradation mechanism. AutoDock Vina, CABS-flex 2.0, and Desmond high-performance molecular dynamics simulation (MDS) were utilized in the current investigation to simulate multivalent molecular processes on two protein sets: arsenate reductase (ArsC) and laccase (LAC) corresponding arsenate (ART) and arsenite (AST), which served as model ligands to comprehend binding, conformational, and energy attributes. The structural configurations of both proteins exhibited variability in flexibility and structure framework within the range of 3.5-4.5 Å. The LAC-ART complex exhibited the lowest calculated binding affinity, measuring -5.82 ± 0.01 kcal/mol. Meanwhile, active site residues ILE-200 and HIS-206 were demonstrated to engage in H-bonding with the ART ligand. In contrast to ArsC, the ligand binding affinity of this bound complex was considerably greater. Additional validation of docked complexes was carried out by deploying Desmond MDS of 100 ns to capture protein and ligand conformation behavior. The system achieved stability during the 100 ns simulation run, as confirmed by the average P-L RMSD, which was ∼1 Å. As a preliminary test of the enzyme's ability to catalyze As species, corresponding computational insights might be advantageous for bridging gaps and regulatory consideration.
Keyphrases
- molecular dynamics simulations
- public health
- molecular docking
- binding protein
- hiv infected
- single molecule
- heavy metals
- drinking water
- antiretroviral therapy
- dna binding
- dengue virus
- transcription factor
- computed tomography
- protein protein
- magnetic resonance
- molecular dynamics
- zika virus
- amino acid
- capillary electrophoresis
- nitric oxide
- visible light