AI Article Synopsis
- - The study investigates various bis-substituted tetrandrine derivatives and their binding properties to double-stranded DNA (dsDNA) using techniques like UV-vis and fluorescence, revealing their high affinity for dsDNA, especially the bis(methyl)anthraquinone (BAqT) and bis(ethyl)indole (BInT) derivatives, with binding constants around 10^-10 M.
- - Utilizing viscometry, ethidium displacement assays, and molecular modeling, researchers identified that these compounds interact with dsDNA through a dual mechanism involving intercalation and major groove binding.
- - Cytotoxicity tests showed low toxicity for most derivatives against various cell lines, except for the bis(methyl)pyrene (
Article Abstract
A series of bis--substituted tetrandrine derivatives carrying different aromatic substituents attached to both nitrogen atoms of the natural alkaloid were studied with double-stranded model DNAs (dsDNAs) to examine the binding properties and mechanism. Variable-temperature molecular recognition studies using UV-vis and fluorescence techniques revealed the thermodynamic parameters, Δ, Δ, and Δ, showing that the tetrandrine derivatives exhibit high affinity toward dsDNA ( ≈ 10-10 M), particularly the bis(methyl)anthraquinone (BAqT) and bis(ethyl)indole compounds (BInT). Viscometry experiments, ethidium displacement assays, and molecular modeling studies enabled elucidation of the possible binding mode, indicating that the compounds exhibit a synergic interaction mode involving intercalation of one of the -aryl substituents and interaction of the molecular skeleton in the major groove of the dsDNA. Cytotoxicity tests of the derivatives with tumor and nontumor cell lines demonstrated low cytotoxicity of these compounds, with the exception of the bis(methyl)pyrene (BPyrT) derivative, which is significantly more cytotoxic than the remaining derivatives, with IC values against the LS-180, A-549, and ARPE-19 cell lines that are similar to natural tetrandrine. Finally, complementary electrochemical characterization studies unveiled good electrochemical stability of the compounds.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC9118212 | PMC |
| http://dx.doi.org/10.1021/acsomega.2c00225 | DOI Listing |
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