Cervical cancer is the second largest form of cancer to infest the leading cause of death in women worldwide. There are many causes of cancer but viruses are the most common among them. Human papillomaviruses (HPVs) are found to be the causative organism in almost 99.7% of the cases. HPV16 is the most frequent HPV type in malignant neoplastic growth in about 60% of cervical carcinoma cases. There is limited success achieved in surgical removal or by immune modulation and more effective therapies are under investigation. Observing the mortality rate we theorize a need for alternative treatment approaches and propose a blueprint of compounds with desirable properties that may lead to the development of drugs to treat HPV-associated neoplasias. E6 oncoprotein of HPV16 has a potential zinc finger domain critical for binding to E6AP, causing p53 degradation and malignancy. Some azoics and disulfides were selected depending on their affinity towards E6 zinc finger and thereby preventing E6-E6AP complex formation. Combinatorial nontoxic derivatives of these azoics and disulfides were docked and validated against the oncoprotein to inhibit E6-E6AP interaction. Among these, two compounds (E)-N-(2-amino-2-oxoethyl)-N-(4-chlorophenyl) diazene-1,2-dicarboxamide and (E)-N-(2- amino-2-methylpropyl)-N-(thiophen-2-yl)diazene-1,2-dicarboxamide showed binding affinity of -23.70, -19.53 and -5.49, -4.65 Kcal/mol respectively in FlexX and Autodock4.2. These compounds are found more effective than those of the approved E6-E6AP binding inhibitors. Pharmacophores of these compounds were generated to confirm it with pharm mapping mechanism. The study may confer the way of design of new mechanism and new compounds to treat cervical cancer.
Growth suppression of many non-COX-2 expressing tumor cells can be exhibited by COX-2 inhibitors, where supplementation of cells with exogenous prostaglandins fails to rescue the cells from growth inhibition. It can, therefore, be speculated that anti-cancer properties of some COX-2 inhibitors may be contributed by the COX-2-independent effects also. Some of the derivatives obtained from certain COX-2 inhibitors which show non-COX-2 inhibitory mechanism have revealed some significant anti-cancer activities. From a COX-2 selective inhibitor nimesulide, an analog JCC76 is derived which is a non-COX-2 active compound and shows inhibition of SKBR-3 breast cancer cell growth. Other JCC76 derived inhibitors also played significant role in SKBR-3 cell inhibition. An analog-based study was done using pharmacophore modeling and 3D-QSAR to provide clues for potential lead compound designing. A five point pharmacophore ADHRR was generated using 39 JCC76-derived SKBR-3 inhibitors. The validated pharmacophore alignment was used for further 3D-QSAR analysis, which presented a good R 2 value of 0.562, 0.982, and 0.848 for atombased QSAR, CoMFA, and CoMSIA model, respectively. All the QSAR models presented good statistical significance and predictivity. The corresponding Q 2 values for each model are 0.513, 0.649, and 0.518, respectively. Both the pharmacophore and CoMSIA results displayed that the H-bond donor and acceptor sites are the key structural feature for JCC76-derived non-COX-2-dependent inhibitors with high activity.
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