Interactions of a Novel Anthracycline with Oligonucleotide DNA and Cyclodextrins in an Aqueous Environment.
Georgios MikaelianGrigorios MegariotisDoros N TheodorouPublished in: The journal of physical chemistry. B (2024)
Berubicin, a chemotherapy medication belonging to the class of anthracyclines, is simulated in double-stranded DNA sequences and cyclodextrins in an aqueous environment via full-atom molecular dynamics simulations on the time scale of microseconds. The drug is studied in both the neutral and protonated states so as to better comprehend the role of its charge in the formed complexes. The noncovalent berubicin-DNA and berubicin-cyclodextrin complexes are investigated in detail, paying special attention to their thermodynamic description by employing the double decoupling method, the solvent balance method, the weighted solvent accessible surface model, and the linear interaction energy method. A novel approach for extracting the desolvation thermodynamics of the binding process is also presented. Both the binding and desolvation Gibbs energies are decomposed into entropic and enthalpic contributions so as to elucidate the nature of complexation and its driving forces. Selected structural and geometrical properties of all the complexes, which are all stable, are analyzed. Both cyclodextrins under consideration are widely utilized for drug delivery purposes, and a comparative investigation between their bound states with berubicin is carried out.
Keyphrases
- molecular dynamics simulations
- ionic liquid
- circulating tumor
- cell free
- drug delivery
- capillary electrophoresis
- single molecule
- nucleic acid
- binding protein
- healthcare
- molecular docking
- solar cells
- magnetic resonance
- molecular dynamics
- computed tomography
- dna binding
- squamous cell carcinoma
- emergency department
- cancer therapy
- circulating tumor cells
- drug release
- electronic health record