Computational Structure Modeling, Functional Characterization, and Identification of Potential Inhibitors for the cyclic-di-GMP Mediated Biofilm Forming Membrane Protein in Vibrio cholerae

Cholera, caused by Vibrio cholerae , continues to pose a serious global public health challenge, with its impact worsened by rising antibiotic resistance associated with bacterial biofilm formation. This study reveals the role of the hypothetical protein (HP) TYC33605.1 in cyclic-di-GMP (c-di-GMP)-mediated biofilm regulation and identifies natural inhibitors that disrupt this mechanism. Functional annotation revealed TYC33605.1 as a membrane-associated diguanylate cyclase (DGC) with GGDEF and sensory domains, critical for c-di-GMP synthesis and biofilm persistence. Homology modelling and molecular dynamics (MD) simulations validated its stable 3D structure (C-score: −1.22, Ramachandran favoured regions: 91.1%) and dynamic behaviour (average RMSD: 8.55 Å). Virtual molecular docking screening of 1,092 natural compounds identified Luteolin (CID 5280445) and Sativanone (CID 13886678) as top candidates, exhibiting strong binding affinities (−9.1 and −9.0 kcal/mol, respectively) and forming hydrogen bonds, π-cation, and hydrophobic interactions with key residues (Glu293, Arg364, Ala176). MD simulations (100 ns) confirmed complex stability, with Luteolin and Sativanone showing lower RMSD fluctuations (7.78 Å and 8.13 Å) compared to the control and apoprotein. The ADME/Tox profiles highlighted favourable pharmacodynamics (PD), pharmacokinetics (PK), high gastrointestinal absorption, no hepatotoxicity, and drug-likeness (Lipinski compliance). Principal component, probability density function, and binding free energy analyses underscore ligand-induced conformational stability. This study proposes the molecular characterisation of the HP and the bioactive compounds Luteolin and Sativanone as promising inhibitors targeting TYC33605.1, offering a novel strategy to combat biofilm-mediated antibiotic resistance and a framework for analogous antimicrobial discovery in Vibrio cholerae .