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 beta-lactam antibiotics. The increasing resistance to those antibiotics by bacterial pathogens generated the emergence of extended-spectrum beta-lactamases (ESBLs), an actual public health problem. This is due to rapid mutations of bacteria when exposed to antibiotics. In this case, beta-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 beta-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 beta-lactamase. Six 3D beta-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 beta-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 beta-lactamase inhibitors or as structural templates for new in-silico pharmaceutical designs, with the possibility of combatting beta-lactam resistanc

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 beta-lactam antibiotics. The increasing resistance to those antibiotics by bacterial pathogens generated the emergence of extended-spectrum beta-lactamases (ESBLs), an actual public health problem. This is due to rapid mutations of bacteria when exposed to antibiotics. In this case, beta-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 beta-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 beta-lactamase. Six 3D beta-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 beta-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 beta-lactamase inhibitors or as structural templates for new in-silico pharmaceutical designs, with the possibility of combatting beta-lactam resistanc

Vibrationally Induced Dissociation of Sulfuric Acid (H₂SO₄)

One of the important reactive steps in Earth’s atmosphere is the decomposition of H2SO4 to H2O and SO3. However, because the UV spectrum of H2SO4 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 ν9 (OH-stretching-) mode, photodissociation can occur on the picosecond time scale. With the potential energy surfaces used in the present work, ν9 = 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

Molecular orbital differentiation of agonist and antagonist activity in the Glycine_B-iGluR-NMDA receptor

We present various molecular electronic descriptors of agonists and antagonists for Glycine_B-iGluR-NMDA receptor with a view to identify computational measures that help differentiate between these two classes of biologically active compounds. We use as reference the glycine site in the NR1 subunit of the NMDA receptor (Glycine_B-iGluR-NMDA). GlycineB-iGluR-NMDA receptor is important in learning and memory, and it is involved in various neurodegenerative diseases such as Alzheimer, Parkinson, and Huntington as well as in neuropathies such as schizophrenia and depression. We carried out quantum calculations at two levels, (1) B3LYP Density Functional (6-311G**), and (2) PM3 Hamiltonian for 168 molecules, of which 22 are agonists and 146 are antagonists. Regardless of the quantum mechanical level used we found a consistent signature of agonists versus antagonist action, the energy of the lowest unoccupied molecular orbital (LUMO). Effective differentiation of agonists and antagonists by a single molecular descriptor is seldom seen. We present a plausible electronic structure argument to rationalize these results

Atomistic simulations of reactive processes in the gas- and condensed-phase

This review focuses on force-field-based approaches to investigate – through computer simulations – reactive processes in chemical and biological systems. Both, reactions in the gas-phase and in condensed-phase environments are discussed and opportunities and the potential for further developments are pointed out. Where available, results are compared with alternative methods and the advantages and drawbacks of the methods are compared. Particular applications include vibrationally and electronically induced (photo)dissociation of small molecules, proton transfer in the gas- and condensed phase and ligand un- and re-binding in proteins