Docking and Molecular Dynamic of Microalgae Compounds as Potential Inhibitors of Beta-Lactamase.

Bacterial resistance is responsible for a wide variety of health problems, both in children and adults. The persistence of symptoms and infections are mainly treated with ß-lactam antibiotics. The increasing resistance to those antibiotics by bacterial pathogens generated the emergence of extended-spectrum ß-lactamases (ESBLs), an actual public health problem. This is due to rapid mutations of bacteria when exposed to antibiotics. In this case, ß-lactamases are enzymes used by bacteria to hydrolyze the beta-lactam rings present in the antibiotics. Therefore, it was necessary to explore novel molecules as potential ß-lactamases inhibitors to find antibacterial compounds against infection caused by ESBLs. A computational methodology based on molecular docking and molecular dynamic simulations was used to find new microalgae metabolites inhibitors of ß-lactamase. Six 3D ß-lactamase proteins were selected, and the molecular docking revealed that the metabolites belonging to the same structural families, such as phenylacridine (4-Ph), quercetin (Qn), and cryptophycin (Cryp), exhibit a better binding score and binding energy than commercial clinical medicine ß-lactamase inhibitors, such as clavulanic acid, sulbactam, and tazobactam. These results indicate that 4-Ph, Qn, and Cryp molecules, homologous from microalgae metabolites, could be used, likely as novel ß-lactamase inhibitors or as structural templates for new in-silico pharmaceutical designs, with the possibility of combatting ß-lactam resistance.

Searching Hit Potential Antimicrobials in Natural Compounds Space against Biofilm Formation.

Biofilms are communities of microorganisms that can colonize biotic and abiotic surfaces and thus play a significant role in the persistence of bacterial infection and resistance to antimicrobial. About 65% and 80% of microbial and chronic infections are associated with biofilm formation, respectively. The increase in infections by multi-resistant bacteria instigates the need for the discovery of novel natural-based drugs that act as inhibitory molecules. The inhibition of diguanylate cyclases (DGCs), the enzyme implicated in the synthesis of the second messenger, cyclic diguanylate (c-di-GMP), involved in the biofilm formation, represents a potential approach for preventing the biofilm development. It has been extensively studied using PleD protein as a model of DGC for in silico studies as virtual screening and as a model for in vitro studies in biofilms formation. This study aimed to search for natural products capable of inhibiting the Caulobacter crescentus enzyme PleD. For this purpose, 224,205 molecules from the natural products ZINC15 database, have been evaluated through molecular docking and molecular dynamic simulation. Our results suggest trans-Aconitic acid (TAA) as a possible starting point for hit-to-lead methodologies to obtain new inhibitors of the PleD protein and hence blocking the biofilm formation.

Influence of Mg2+ ions on the interaction between 3,5-dicaffeoylquinic acid and HTLV-I integrase / Influencia de los iones Mg+2 sobre la interacción entre el ácido 3,5- dicafeoilquínico y la integrasa del HTLV-I / Influência dos íons Mg2+ sobre a interação entre o ácido 3,5-dicafeoilquínico e a integrase do HTLV-I

Objective. Using molecular simulation, we studied the influence of Mg2+ ions on the binding mode of HTLV-I Integrase (IN) catalytic domain (modeled by homology) with the 3,5- Dicaffeoylquinic Acid (DCQA). HTLV-I Integrase homology model was built using template-like crystallographic data of the IN catalytic domain solved for Avian Sarcoma Virus (VSA, pdb: 1VSD). Materials and methods. In order to analyze the role of Mg2+ in the interaction or coupling between 3,5-DCQA and Integrase, three models were created: i) in the absence of Mg2+ ions, ii) with a Mg2+ ion coordinated at Asp15 and Asp72 and iii) model with two Mg2+ ions coordinated at Asp15-Asp72 and Asp72-Glu108. Coupling force and binding free energy between 3,5-DCQA and HTLV-I IN were assessed in the three models. Results. The lowest docking score and free energy binding were obtained for the second model. Mg2+ ion strongly affected the coupling of the inhibitor 3,5-DCQA with HTLV-I catalytic domain of Integrase, thus revealing a strong interaction in the ligand-protein complex regardless of the ligand-catalytic interaction sites for all three models. Conclusion. Altogether, these results strengthen the hypothesis that the presence of one Mg2+ ion could enhance the interaction in the complex by decreasing free energy, therefore increasing the affinity. Moreover, we propose 3,5-DCQA as an important pharmacophore in the rational design of new antiretroviral drugs.

Objetivo: Usando simulación molecular, estudiamos la influencia de los iones Mg2+ en la interacción del dominio catalítico de la integrasa HTLV-I (IN) (modelado por homología) con el ácido 3,5-Dicafeoilquínico (DCQA). Materiales y métodos. El modelo por homología de la HTLV-I IN fue construido usando como molde la estructura cristalina de la IN del virus del sarcoma aviar (VSA, pdb: 1VSD). Para analizar el rol de los iones Mg2+ en la interacción con el DCQA y la integrasa, tres modelos fueron creados: i) en ausencia de iones Mg2+, ii) con un ion Mg2+ coordinado con Asp15 y Asp72 y iii) con dos iones Mg2+ coordinados con Asp15-Asp72 y Asp72-Glu108. Las fuerzas de interacción y la energía libre de unión entre el DCQA y la HTLV-I IN fueron calculadas en los tres modelos. Resultados. El puntaje más bajo en el docking y la menor energía libre fueron obtenidos para el modelo con un solo ion de Mg2+. El Mg2+ afecta fuertemente el acoplamiento del inhibidor DCQA con el dominio catalítico de la HTLV-I IN, revelando una fuerte interacción entre el complejo ligando-proteína que es independiente del sitio catalítico de los tres modelos usados. Conclusión. Los resultados sugieren que la presencia de un ion de Mg² + podría incrementar la interacción en el complejo debido a la disminución de la energía libre, intensificando así la afinidad. Por lo que, proponemos al DCQA como farmacóforo para el diseño de drogas antiretrovirales.

Objetivo. Usando simulação molecular, estudamos a influência dos íons Mg2+ na interação do domínio catalítico da integrase HTLV-I (IN) (modelado por homologia) com o ácido 3,5-dicafeoilquínico (3,5-diCQA). Materiais e métodos. O modelo de homologia da HTLV-I IN foi construído utilizando como fôrma a estrutura cristalina da IN de vírus do sarcoma aviário (VSA, pdb: 1VSD). Para analisar o papel dos íons Mg2+ na interação com o 3,5-diCQA e a integrase, três modelos foram criados: i) na ausência de íons Mg2+, ii) com um íon Mg2+ coordenado com Asp15 e Asp72 e, iii) com dois íons Mg2+ coordenados com Asp15-Asp72 e Asp72-Glu108. As forças de interação e a energia livre de ligação entre o 3,5-diCQA e a HTLV-I IN foram calculadas nos três modelos. Resultados. A pontuação mais baixa no docking e a menor energia livre foram obtidas para o modelo com um único íon de Mg2+. O Mg2+ afeta fortemente o acoplamento do inibidor 3,5-diCQA com o domínio catalítico da HTLV-I IN, revelando uma forte interação entre o complexo ligando-proteína que é independente do sítio catalítico dos três modelos utilizados. Conclusão. Os resultados sugerem que a presença de um íon Mg2+ poderia aumentar a interação no complexo devido à diminuição da energia livre, aumentando assim a afinidade. Assim, propomos ao 3,5-diCQA como farmacóforo para a fabricação de medicamentos antirretrovirais.

Vibrationally induced dissociation of sulfuric acid (H2SO4).

One of the important reactive steps in Earth's atmosphere is the decomposition of H(2)SO(4) to H(2)O and SO(3). However, because the UV spectrum of H(2)SO(4) was not found up to 140 nm, alternative mechanisms, including vibrationally induced dissociation, were proposed. Using adiabatic reactive molecular dynamics (ARMD) simulations with validated force fields for the product and educt channels, it is shown through explicit atomistic simulation that by exciting the ν(9) (OH-stretching-) mode, photodissociation can occur on the picosecond time scale. With the potential energy surfaces used in the present work, ν(9) = 4 is sufficient for this process. From a statistically significant number of trajectories (several thousands), vibrationally induced dissociation times are found to follow Gamma-distributions with most likely reaction times between 40 and 200 ps by depositing energies ranging from 40 to 60 kcal/mol, corresponding to 4 and 6 vibrational quanta in the OH stretching vibration. Because ARMD simulations allow multiple and long-time simulations, both nonstatistical, impulsive H-transfer and statistical, IVR-regimes of the decomposition reaction can be discussed in detail at an atomistic level.