26345-73-3Relevant articles and documents
Interplay of the intermolecular and intramolecular interactions in stabilizing the thione-based copper(I) complexes and their significance in protecting the biomolecules against metal-mediated oxidative damage
Chalana, Ashish,Karri, Ramesh,Kumar Jha, Kunal,Kumar Rai, Rakesh,Kumar, Binayak,Roy, Gouriprasanna
supporting information, (2022/01/26)
The synthesis, characterization, and X-ray structure of a series of mono, tri, and polynuclear copper complexes of benzimidazole-based N-substituted thiones, BzMeSH (10) and BzOHSH (11), and N,N'-disubstituted, BzMeSMe (12) and BzOHSMe (13) are reported here. The X-ray structure analyses of the copper-thione complexes have revealed that the coordination behaviour and the geometry of the central metal ion in these complexes are significantly dependent on the type of the counter anion used in the reaction. For instance, the reactions of benzimidazole-based thiones with CuCl2 afforded mononuclear trigonal planar Cu(I) complexes 14, 15, 18, and 19. On contrast, upon reaction with CuSO4, 10 afforded the trinuclear copper complex 16, in which thione 10 acts as a bridging as well as terminal ligand, leading to the formation of a six-membered Cu3S3 cluster. The chair-form of six-membered Cu3S3 ring is further stabilized by six intramolecular H-bonding interactions, with overall stabilization energy of 19.28 kcal.mol?1, between the free NH group of 10 and O atom of the counter anion SO42–. Whereas, when thione 10 was reacted with CuI, a 1D-polymeric chain-like copper complex 17 was obtained as a thermodynamically stable product, in which both 10 and iodine act as bridging ligand. The 3D network of complexes has revealed that these copper-thione compounds are stabilized by the presence of various types of intermolecular and intramolecular H-bonding and π ? π stacking interactions in the solid state. NBO analysis of the crystal geometries revealed that the strength of these interactions ranging from 0.14 to 5.67 kcal.mol?1. We have also demonstrated that the N-substituted thiones have excellent reactive oxygen species (ROS) scavenging property and, thus, protect biomolecules including DNA and protein against Cu(I)-mediated oxidative damage.
Protection of Endogenous Thiols against Methylmercury with Benzimidazole-Based Thione by Unusual Ligand-Exchange Reactions
Banerjee, Mainak,Karri, Ramesh,Chalana, Ashish,Das, Ranajit,Rai, Rakesh Kumar,Rawat, Kuber Singh,Pathak, Biswarup,Roy, Gouriprasanna
supporting information, p. 5696 - 5707 (2017/04/28)
Organomercurials, such as methylmercury (MeHg+), are among the most toxic materials to humans. Apart from inhibiting proteins, MeHg+ exerts its cytotoxicity through strong binding with endogenous thiols cysteine (CysH) and glutathione (GSH) to form MeHgCys and MeHgSG complexes. Herein, it is reported that the N,N-disubstituted benzimidazole-based thione 1 containing a N?CH2CH2OH substituent converts MeHgCys and MeHgSG complexes to less toxic water-soluble HgS nanoparticles (NPs) and releases the corresponding free thiols CysH and GSH from MeHgCys and MeHgSG, respectively, in solution by unusual ligand-exchange reactions in phosphate buffer at 37 °C. However, the corresponding N-substituted benzimidazole-based thione 7 and N,N-disubstituted imidazole-based thione 3, in spite of containing a N?CH2CH2OH substituent, failed to convert MeHgX (X=Cys, and SG) to HgS NPs under identical reaction conditions, which suggests that not only the N?CH2CH2OH moiety but the benzimidazole ring and N,N-disubstitution in 1, which leads to the generation of a partial positive charge at the C2 atom of the benzimidazole ring in 1:1 MeHg-conjugated complex of 1, are crucial to convert MeHgX to HgS NPs under physiologically relevant conditions.
