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Exploring the binding potential of natural compounds to carbonic anhydrase of cyanobacteria through computer-based simulations

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Publicat a:SN Applied Sciences vol. 7, no. 3 (Mar 2025), p. 206
Publicat:
Springer Nature B.V.
Matèries:
Ribulose-bisphosphate carboxylase
Databases
Algicides
Carbon dioxide fixation
Paralytic shellfish poisoning
Shellfish
Binding
Biomass
Sulfonamides
Bicarbonates
Herbicides
Metabolism
Cyanobacteria
Carbon dioxide
Neurotoxicity
Drug development
Algae
Proteins
Water quality
Simulation
Poisoning
Molecular docking
Historic sites
Protein kinase C
Ciguatera
Free energy
Algorithms
Ligands
High temperature
Molecular dynamics
Enzymes
Natural products
Carbonic anhydrase
Software
Comparative analysis
Toxicity
Amnesic shellfish poisoning
Amino acids
Molecular modelling
Diarrhetic shellfish poisoning
Carbonic anhydrases
Hydrogen bonds
Inhibitors
Toxins
Historic buildings & sites
Environmental
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Resum:Cyanobacteria in water bodies cause harmful cyanobacterial blooms, releasing toxins that degrade water quality and cause health issues. Common Harmful Algal Bloom-related disorders (HABs) include neurotoxic shellfish poisoning, ciguatera poisoning, paralytic shellfish poisoning, diarrhetic shellfish poisoning, and amnesic shellfish poisoning. Adapting to high temperatures and humidity, cyanobacteria also colonize historical sites, causing staining erosion, and reducing their aesthetic value. In this context, we have chosen carbonic anhydrase which plays an essential role in the interconversion of water and carbon dioxide to bicarbonates and makes it available to RuBisCo that regulates the photosynthetic pathways leading to cyanobacterial biomass generation. This study employed the molecular modeling approach to identify the potential natural inhibitors to carbonic anhydrase from the COCONUT database. Strategically we explore the Structural-Activity Relationship (SAR) of natural compounds to the reported sulphonamide inhibitors. Further, prediction-based online web servers such as pkCSM and SwissADME were used to determine the ADMET properties of the SAR molecules. An FDA-approved compound, Ethoxzolamide was chosen for comparative analysis. Next, the In-silico methodologies such as molecular docking and molecular dynamic simulations, free energy landscape analysis, hydrogen bond analysis, and binding free energy calculations were performed using various algorithms under virtual physiological conditions to identify potential SAR molecules against carbonic anhydrase. Further, we perform molecular dynamic simulation for a time period of 100&#xa0;ns. It was evidenced from the molecular dynamic simulations and MM-PBSA calculations that some natural compounds outperform the Ethoxzolamide compound not only in stability but also in binding affinity. This study delves into the intricate interactions of natural compounds with the cyanobacteria carbonic anhydrase which plays a pivotal role in growth and development. Hence, we believe that our models could show extreme effectivity and might act as potent bio-algaecides.Article Highlights<list list-type="bullet"><list-item></list-item>The utilization of the COCONUT database, an open-source repository of natural products, provides a vast and diverse chemical space to explore potential drug candidates.<list-item>The integration of in-silico techniques, such as molecular docking and molecular dynamics simulations, offers a rapid and cost-effective approach to identify promising compounds.</list-item><list-item>By targeting carbonic anhydrase, a key enzyme in cyanobacterial CO2 fixation, this research aims to develop novel inhibitors that can effectively reduce biomass generation.</list-item>
ISSN:2523-3963
2523-3971
DOI:10.1007/s42452-025-06492-6
Font:Science Database