As follow-up of our past publication?[1], we propose that quinolones (as part of the pyridinone family) are capable to increase the number of interactions with HIV reverse transcriptase (RT) or integrase (IN) by addin...As follow-up of our past publication?[1], we propose that quinolones (as part of the pyridinone family) are capable to increase the number of interactions with HIV reverse transcriptase (RT) or integrase (IN) by adding a halogen in position C-8 of aromatic portion of the quinolones. This addition could help with the activity of dual inhibitors of RT and IN. In this work, we add a chlorine atom with the rationale to identify in the docking simulations a halogen interaction with the oxygen in the near aminoacids in the binding pockets of RT and IN enzymes. Our docking studies started with RT and 320 structures. Later, we took 73 structures with good results in docking with RT. The structures that we choose contain ester or acids groups in C-3 due the structural similarity with groups in charge to interact with the Mg++ ions in Elvitegravir. In conclusion, we obtained 14 structures that could occupy the allosteric pocket of RT and could inhibit the catalytic activity of IN, for this reason could be dual inhibitors. A major perspective of this work is the synthesis and testing of the potential dual inhibitors designed.展开更多
With the goal of suggesting dual inhibitors of HIV reverse transcriptase (RT) and integrase (IN), herein we report the molecular docking of an initial set of 556 compounds related to the pyridinone class. Docking with...With the goal of suggesting dual inhibitors of HIV reverse transcriptase (RT) and integrase (IN), herein we report the molecular docking of an initial set of 556 compounds related to the pyridinone class. Docking with multiple crystallographic structures of HIV-1 RT led to 160 potential binders of RT interacting with key amino acid residues at the enzyme’s allosteric site. Compounds selected from the docking with RT were further docked with a crystallographic structure of HIV-1 IN. A total of 31 structures had the potential to make contacts with Mg2+ ions located in a small space between DNA and IN. Interactions with Mg2+ ions are relevant because they participate in the stabilization of the IN-DNA complex. In conclusion, 31 compounds synthetically accessible are proposed as dual inhibitors of RT and IN. It is hypothesized that the suggested compounds will inhibit RT by occupying the allosteric site for NNRTIs and will inhibit the catalytic activity of IN by destabilizing the IN-DNA complex. The main perspective of this work is the synthesis and biological testing of the candidate molecules.展开更多
文摘As follow-up of our past publication?[1], we propose that quinolones (as part of the pyridinone family) are capable to increase the number of interactions with HIV reverse transcriptase (RT) or integrase (IN) by adding a halogen in position C-8 of aromatic portion of the quinolones. This addition could help with the activity of dual inhibitors of RT and IN. In this work, we add a chlorine atom with the rationale to identify in the docking simulations a halogen interaction with the oxygen in the near aminoacids in the binding pockets of RT and IN enzymes. Our docking studies started with RT and 320 structures. Later, we took 73 structures with good results in docking with RT. The structures that we choose contain ester or acids groups in C-3 due the structural similarity with groups in charge to interact with the Mg++ ions in Elvitegravir. In conclusion, we obtained 14 structures that could occupy the allosteric pocket of RT and could inhibit the catalytic activity of IN, for this reason could be dual inhibitors. A major perspective of this work is the synthesis and testing of the potential dual inhibitors designed.
文摘With the goal of suggesting dual inhibitors of HIV reverse transcriptase (RT) and integrase (IN), herein we report the molecular docking of an initial set of 556 compounds related to the pyridinone class. Docking with multiple crystallographic structures of HIV-1 RT led to 160 potential binders of RT interacting with key amino acid residues at the enzyme’s allosteric site. Compounds selected from the docking with RT were further docked with a crystallographic structure of HIV-1 IN. A total of 31 structures had the potential to make contacts with Mg2+ ions located in a small space between DNA and IN. Interactions with Mg2+ ions are relevant because they participate in the stabilization of the IN-DNA complex. In conclusion, 31 compounds synthetically accessible are proposed as dual inhibitors of RT and IN. It is hypothesized that the suggested compounds will inhibit RT by occupying the allosteric site for NNRTIs and will inhibit the catalytic activity of IN by destabilizing the IN-DNA complex. The main perspective of this work is the synthesis and biological testing of the candidate molecules.
