Synthesis, Urease Inhibition and Molecular Modelling Studies of Novel Derivatives of the Naturally Occurring β-Amyrenone.
Jean Jules Kezetas BankeuHira SattarYannick S F FongangSyeda W MuhammadiConrad V SimobenFidele Ntie-KangGuy R T FeuyaMarthe A T TchuenmogneMehreen LateefBruno N LentaMuhammad S AliAugustin S NgouelaPublished in: Natural products and bioprospecting (2018)
Urease enzyme (UE) has been reported to be a potent virulence factor for Helicobacter pylori (HP) bacteria indicated to be responsible for various gastrointestinal diseases. Therefore, the spread of HP, currently regarded by the World Health Organization as a class 1 carcinogen, could be better controlled by targeting UE. It is in this line that we have synthesized three new derivatives (2-4) of the naturally occurring olean-12-en-3-one (1), which was previously isolated from the figs of Ficus vallis-choudae Delile (Moraceae). Among the synthesized compounds, 3 and 4 contain an indole moiety. Their structures were unambiguously assigned by spectroscopic and spectrometric techniques (1D-NMR, 2D-NMR and MS). The starting material and the synthesized compounds were screened for UE inhibition activity, and showed significant activities with IC50 values ranging from 14.5 to 24.6 μM, with compound (1) being the most potent as compared to the positive control thiourea (IC50 = 21.6 μM). Amongst the synthetic derivatives, compound 4 was the most potent (IC50 = 17.9 μM), while the others showed activities close to that of the control. In addition, molecular docking study of target compounds 2-4 was performed in an attempt to explore their binding mode for the design of more potent UE inhibitors.
Keyphrases
- molecular docking
- helicobacter pylori
- high resolution
- anti inflammatory
- magnetic resonance
- molecular dynamics simulations
- helicobacter pylori infection
- escherichia coli
- mass spectrometry
- staphylococcus aureus
- pseudomonas aeruginosa
- structure activity relationship
- ms ms
- high performance liquid chromatography
- liquid chromatography
- single molecule
- biofilm formation
- binding protein
- oxide nanoparticles
- cystic fibrosis