Natural abenquines and synthetic analogues: Preliminary exploration of their cytotoxic activity

In this study, we explore the cytotoxic activity of four natural abenquines (2a–d) and fourteen synthetic analogues (2e–j and 3a–h) against a panel of six human cancer cell lines using a SRB assay. It was found that most of the compounds revealed higher levels of cytotoxic activities than naturally occurring abenquines. The analogues carrying ethylpyrrolidinyl and ethylpyrimidinyl with either an acetyl group (2 h–i) or a benzoyl group (3f–g), were the most potent against all human cancer cell lines and displayed EC₅₀ between a range of 0.6–3.4 μM. Notably, of the compounds tested, compound 2i proved the most cytotoxic against both ovarian (A2780) and breast (MCF7) cells, showing EC₅₀ = 0.6 and 0.8 μM respectively. Likewise, the analogues 2i, 3f and 3 g showed strong activity against cell HT29 with EC₅₀ = 0.9 μM for these compounds.     

Amino‐substituted para‐Benzoquinones as Potential Herbicides

Although quinones present a large array of biological activities, a few studies on the herbicidal potential of 2,5‐bis(alkyl/arylamino)‐1,4‐benzoquinones have been reported to date. In this work, starting from benzoquinone, 13 2,5‐bis(alkyl/arylamino)‐1,4‐benzoquinones were prepared in 46 – 93% yield. The products were fully characterized by spectroscopic analyses and their phytotoxicity against Cucumis sativus and Sorghum bicolor seedlings was investigated. At 100 ppm, compounds caused 10 – 88% growth inhibition of the dicotyledonous species, whereas the monocotyledon was less affected. Most compounds exerted little inhibitory effect on a cyanobacterial model strain. However, at 100 μm , compounds 8  –  10 caused about 50% inhibition of algal growth, and compounds 1 and 2 reduced cell viability in the 1 – 10 μm range. The ability of benzoquinone derivatives to interfere with the light‐driven ferricyanide reduction by isolated spinach chloroplasts was evaluated. Some substances showed a moderate effect as uncouplers, but no relationship was found between this property and their biological activity, indicating that the herbicidal effect is not associated with the inhibition of the photosynthetic electron transport chain. Phytotoxic compounds were not toxic to insects, strengthening the possibility that they may serve as lead for the development of eco‐friendly herbicides.     

Antiureolytic Activity of Substituted 2,5‐Diaminobenzoquinones

A series of 2,5‐bis(alkyl/arylamino)‐1,4‐benzoquinones ( 1 – 12 ) were investigated in vitro for their potential to inhibit the activity of jack bean urease. Compounds 1–6 , 8 , 9 , 11 and 12 effectively inhibited the jack bean urease activity by 90.8 % when tested at 5 μm , whereas 7 and 10 had relatively little effect. The IC₅₀ for most compounds was in the nanomolar range (31.4 nm and 36.0 nm for 2 and 8 , respectively). The mechanism of enzyme inhibition shown by 2 and 8 is typical of mixed‐type inhibitors, whose affinity for the active site is over 6‐ and 2‐fold higher (K_i=30.0 and 22.8 nm , for 2 and 8 , respectively) than that of an allosteric site. Molecular docking studies revealed that both 2 and 8 establish hydrogen bonds with the amino acids residues Asp494, Met588, His593 and Ala636 in the active site of jack bean urease. These results indicate that such aminoquinones are useful leads for the development of more efficient urease inhibitors of wider utility.