ABSTRACT
Resumen El virus de la influenza A es el responsable de la gripe aviar, condición patológica que afecta principalmente aves, caballos y mamíferos marinos, sin embargo, el subtipo H5NI tiene la capacidad de infectar a los humanos de forma rápida, exponiéndolos a un posible evento pandémico. Por tanto, el objetivo de este estudio fue realizar el acoplamiento molecular y modelado tridimensional por homología de flavonoides derivados de amentoflavona con las neuraminidasas H1N1 y H5N1 del virus de gripe aviar. Inicialmente, se obtuvo por homología la estructura 3D de la neuraminidasa H1N1. Seguido, se realizó un acoplamiento molecular de H1N1 con seis ligandos (F36, Ginkgetin, 3S,3R, 5S,5R, 6S y 6R), y más adelante H5N1 y los ligandos F36, Ginkgetin, 5R y 6R. Finalmente, a los complejos obtenidos se les realizó un análisis de interacciones. Los resultados dejaron en evidencia una relación entre la actividad inhibitoria y las interacciones tipo puente de hidrógeno e hidrofóbicas formadas entre el sitio activo de las neuraminidasas y los ligandos. Además, se observó una mejora en la actividad inhibitoria de los ligandos para la estereoquímica tipo R y sustituyentes poco voluminosos. De ahí que se propongan la evaluación experimental de los ligandos 5R y 6R como potenciales inhibidores de H5N1.
Abstract The influenza A virus is responsible for bird flu; a pathological condition that mainly affects birds, horses, and marine mammals, however, the H5N' subtype can infect humans quickly; exposing them to a possible pandemic event. Therefore, the objective of this study was to carry out the molecular docking and three-dimensional homology modeling of flavonoids derived from amentoflavone with H'NI and H5NI neuraminidases of the avian influenza virus. Initially, the 3D structure of H1N1 neuraminidase was obtained by homology. Then, the molecular docking of H1N1 was carried out with six ligands (F36, Ginkgetin, 3S, 3R, 5S, 5R, 6S, and 6R), and subsequently H5N1 and F36, Ginkgetin, 5R, and 6R ligands. Finally, an interaction analysis of the proteinligand complex was performed. The results showed a relationship between the inhibitory activity of ligands and the hydrophobic and hydrogen bridge-type interactions. In addition, an improvement in the inhibitory activity of the ligands for R-type stereochemistry and small bulky substituents was observed. Thus, the experimental evaluation of the 5R and 6R ligands as potential H5N' inhibitors is proposed.
Resumo O vírus influenza A é responsável pela gripe aviária; condição patológica que afeta principalmente pássaros, cavalos e mamíferos marinhos, no entanto, o subtipo H5N' tem a capacidade de infectar humanos rapidamente; assim, expondo-os a um possível evento pandémico. Portanto, o objetivo deste estudo foi realizar o acoplamento e modelagem de homologia tridimensional de flavonóides derivados da amentoflavona com as neuraminidases H1N1 e H5N1 do vírus da influenza aviária. Inicialmente, a estrutura 3D da neuraminidase H1N1 foi obtida por homologia. Em seguida, o acoplamento molecular de H1N1 foi realizado com seis ligantes (F36, Ginkgetin, 3S, 3R, 5S, 5R, 6S e 6R) e, posteriormente, H5NI e os ligantes F36, Ginkgetin, 5R e 6R. Finalmente, uma análise de interação foi realizada nos complexos obtidos. Os resultados mostraram uma relação entre a atividade inibitória e as interações hidrofóbicas e do tipo ponte de hidrogénio formadas entre o sítio ativo das neuraminidases e os ligantes. Além disso, foi observada uma melhoria na atividade inibitória dos ligantes para a estereoquímica do tipo R e pequenos substituintes volumosos. Assim, é proposta a avaliação experimental dos ligantes 5R e 6R como potenciais inibidores do H5NI.
ABSTRACT
Background: Heat shock protein (Hsp90KDa) is a molecular chaperone involved in the process of cellular oncogenesis, hence its importance as a therapeutic target. Geldanamycin is an inhibitor of Hsp90 chaperone activity, which binds to the ATP binding site in the N-terminal domain of Hsp90. However, geldanamycin has shown hepatotoxic damage in clinical trials; for this reason, its use is not recommended. Taking advantage that geldanamycin binds successfully to Hsp90, many efforts have focused on the search for similar analogues, which have the same or better biological response and reduce the side effects of its predecessor; 17-AAG and 17-DMAG are examples of these analogues. Methods: In order to know the chemical factors influencing the growth or decay of the biological activity of geldanamycin analogues, different computational techniques such as docking, 3DQSAR and quantum similarity were used. Moreover, the study quantified the interaction energy between amino acids residues of active side and geldanamycin analogues, through hybrid methodology (Autodock-PM6) and DFT indexes. Results: The evaluation of interaction energies showed that the interaction with Lys58 residue is essential for the union of the analogues to the active site of Hsp90, and improves its biological activity. This union is formed through a substituent on C-11 of the geldanamycin macrocycle. A small and attractor group was found as the main steric and electrostatic characteristic that substituents on C11 need in order to interact with Lys 58; behavior was observed with hydroxy and methoxy series of geldanamycin analogues, under study. Conclusion: This study contributes with new hybrid methodology (Autodock-PM6) for the generation of 3DQSAR models, which to consider the interactions between compounds and amino acids residues of Hsp90´s active site in the alignment generation. Additionally, quantum similarity and reactivity indices calculations using DFT were performed to know the non-covalent stabilization in the active site of these compounds.
