Unravelling novel congeners from acetyllysine mimicking ligand targeting a lysine acetyltransferase PCAF bromodomain

<p>p300/CBP Associated Factor (PCAF) bromodomain (BRD), a lysine acetyltransferases, has emerged as a promising drug target as its dysfunction is linked to onset and progression of several diseases like cancer, diabetes, AIDS, etc. In this study, a three featured E-Pharmacophore (ARR) was generated based on acetyllysine mimicking inhibitor of PCAF BRD which is available as co-crystal structure (PDB ID: 5FDZ). It was used for filtering small molecule databases followed by molecular docking and consequently validated using enrichment calculation. The resulted hits were found to be congeners which show the predictive power of E-Pharmacophore hypothesis. Further, Induced Fit Docking method, Binding energy calculation, ADME prediction, Single Point Energy calculation and Molecular Dynamics simulation were performed to find better hits against PCAF BRD. Based on the results, it was concluded that Asn803, Tyr809 and Tyr802 along with a water molecule (HOH1001) plays crucial role in binding with inhibitor. It is also proposed that four hits from Life Chemicals database namely, F2276-0099, F2276-0008, F2276-0104 and F2276-0106 could act as potent drug molecules for PCAF BRD. Thus, the present study is strongly believed to have bright impact on rational drug design of potent and novel congeners of PCAF BRD inhibitors.</p

Molecular docking and structure-based virtual screening studies of potential drug target, CAAX prenyl proteases, of <i>Leishmania donovani</i>

<p>Targeting CAAX prenyl proteases of <i>Leishmania donovani</i> can be a good approach towards developing a drug molecule against Leishmaniasis. We have modeled the structure of CAAX prenyl protease I and II of <i>L. donovani</i>, using homology modeling approach. The structures were further validated using Ramachandran plot and ProSA. Active site prediction has shown difference in the amino acid residues present at the active site of CAAX prenyl protease I and CAAX prenyl protease II. The electrostatic potential surface of the CAAX prenyl protease I and II has revealed that CAAX prenyl protease I has more electropositive and electronegative potentials as compared CAAX prenyl protease II suggesting significant difference in their activity. Molecular docking with known bisubstrate analog inhibitors of protein farnesyl transferase and peptidyl (acyloxy) methyl ketones reveals significant binding of these molecules with CAAX prenyl protease I, but comparatively less binding with CAAX prenyl protease II. New and potent inhibitors were also found using structure-based virtual screening. The best docked compounds obtained from virtual screening were subjected to induced fit docking to get best docked configurations. Prediction of drug-like characteristics has revealed that the best docked compounds are in line with Lipinski’s rule. Moreover, best docked protein–ligand complexes of CAAX prenyl protease I and II are found to be stable throughout 20 ns simulation. Overall, the study has identified potent drug molecules targeting CAAX prenyl protease I and II of <i>L. donovani</i> whose drug candidature can be verified further using biochemical and cellular studies.</p