In-vitro biological evaluation of 3,3',5,5'-tetramethoxy-biphenyl-4,4'-diol and molecular docking studies on trypanothione reductase and Gp63 from Leishmania amazonensis demonstrated anti-leishmania potential.
Jéseka G SchirmannBruna Taciane da Silva BortoletiManoela Daiele GonçalvesFernanda Tomiotto-PellissierPriscila Goes CamargoMilena Menegazzo Miranda-SaplaCamilo Henrique da Silva LimaMarcelle de Lima Ferreira BispoIdessania Nazareth da CostaIvete Conchon CostaWander Rogério PavanelliRobert F H DekkerAneli de Melo Barbosa-DekkerPublished in: Scientific reports (2023)
Available treatments for leishmaniasis have been widely used since the 1940s but come at a high cost, variable efficacy, high toxicity, and adverse side-effects. 3,3',5,5'-Tetramethoxy-biphenyl-4,4'-diol (TMBP) was synthesized through laccase-catalysis of 2,6-dimethoxyphenol and displayed antioxidant and anticancer activity, and is considered a potential drug candidate. Thus, this study aimed to evaluate the anti-leishmanial effect of TMBP against promastigote and amastigote forms of Leishmania (L.) amazonensis and investigated the mechanisms involved in parasite death. TMBP treatment inhibited the proliferation (IC 50 0.62-0.86 µM) and induced the death of promastigote forms by generating reactive oxygen species and mitochondrial dysfunction. In intracellular amastigotes, TMBP reduced the percentage of infected macrophages, being 62.7 times more selective to the parasite (CC 50 53.93 µM). TMBP did not hemolyze sheep erythrocytes; indicative of low cytotoxicity. Additionally, molecular docking analysis on two enzyme targets of L. amazonensis: trypanothione reductase (TR) and leishmanolysin (Gp63), suggested that the hydroxyl group could be a pharmacophoric group due to its binding affinity by hydrogen bonds with residues at the active site of both enzymes. TMBP was more selective to the Gp63 target than TR. This is the first report that TMBP is a promising compound to act as an anti-leishmanial agent.
Keyphrases
- molecular docking
- reactive oxygen species
- molecular dynamics simulations
- oxidative stress
- plasmodium falciparum
- drug induced
- toxoplasma gondii
- trypanosoma cruzi
- diabetic rats
- high glucose
- signaling pathway
- emergency department
- life cycle
- high resolution
- adverse drug
- atomic force microscopy
- climate change
- replacement therapy
- high speed