New insight into the allosteric effect of L-tyrosine on mushroom tyrosinase during L-dopa production.

Kinetics studies of L-tyrosine (LTy) ortho-hydroxylation by mushroom tyrosinase (MT) confirmed that MT was severely, but not completely, inhibited at higher concentrations of LTy. Despite the availability of the crystal structure reports, no allosteric site has been identified on MT. To examine the assumption that a non-specific binding site works as a regulatory site, docking simulations were run for the second molecule of L-tyrosine (LTy2) on the complexes of the first L-tyrosine molecule (LTy1) with the heavy chain (H) of MT (LTy1/HMT) and its dimer with the light chain (Ty1/LHMT). In both, LTy2 occupied a non-specific binding site (MTPc). MD simulations revealed LTy2/HMT/LTy1 and LTy2/LHMT/LTy1 were stable. Binding free-energy analysis supported the formation of LTy2/HMT/LTy1 and LTy2/LHMT/LTy1 at higher concentrations of LTy and disclosed the importance of ΔEelec and ΔGpolar during binding of LTy2 to MTPc. Upon LTy2 binding to MTPc, the Cu-Cu distance remained unchanged while the spatial position of LTy1 in the active site (MTPa) changed so that it would not be able to participate in ortho-hydroxylation. This study suggests a tuning role for L chain during binding of the ligands to MTPa and MTPc. Given these results, a plausible mechanism was proposed for the MT substrate inhibition.

Spectroscopic, electrochemical, docking and molecular dynamics studies on the interaction of three oxovanadium (IV) Schiff base complexes with bovine serum albumin and their cytotoxicity against cancer.

This study was designed to investigate the interaction of three oxovanadium (IV) Schiff base complexes with bovine serum albumin (BSA) by means of various spectroscopic and electrochemical methods along with molecular docking study and molecular dynamics simulations. Binding constants were estimated by fluorescence and UV-Vis spectroscopy. The results indicated a good affinity of the complexes for BSA in which furyl derivative had more activity. Molecular docking study showed that these complexes have the similar binding modes and located within subdomain IB in site III of BSA. The supporting of molecular docking and molecular dynamics results by experimental data, confirms the validity of the interactions data obtained by these methods. Biological activity against cancer cell showed that furyl derivative has higher activity than other complexes. Pharmaceutical analysis also showed that, these complexes potentially can be used as anticancer agents.

Reactive molecular dynamic simulations on the gas separation performance of porous graphene membrane.

The separation of gases molecules with similar diameter and shape is an important area of research. For example, the major challenge to set up sweeping carbon dioxide capture and storage (CCS) in power plants is the energy requisite to separate the CO2 from flue gas. Porous graphene has been proposed as superior material for highly selective membranes for gas separation. Here we design some models of porous graphene with different sizes and shape as well as employ double layers porous graphene for efficient CO2/H2 separation. The selectivity and permeability of gas molecules through various nanopores were investigated by using the reactive molecular dynamics simulation which considers the bond forming/breaking mechanism for all atoms. Furthermore, it uses a geometry-dependent charge calculation scheme that accounts appropriately for polarization effect which can play an important role in interacting systems. It was found that H-modified porous graphene membrane with pore diameter (short side) of about 3.75 Å has excellent selectivity for CO2/H2 separation. The mechanism of gas penetration through the sub-nanometer pore was presented for the first time. The accuracy of MD simulation results validated by valuable DFT method. The present findings show that reactive MD simulation can propose an economical means of separating gases mixture.

Non-specific binding sites help to explain mixed inhibition in mushroom tyrosinase activities.

Inhibition and activation studies of tyrosinase could prove beneficial to agricultural, food, cosmetic, and pharmaceutical industries. Although non-competitive and mixed-inhibition are frequent modes observed in kinetics studies on mushroom tyrosinase (MT) activities, the phenomena are left unexplained. In this study, dual effects of phthalic acid (PA) and cinnamic acid (CA) on MT during mono-phenolase activity were demonstrated. PA activated and inhibited MT at concentrations lower and higher than 150 µM, respectively. In contrast, CA inhibited and activated MT at concentrations lower and higher than 5 µM. The mode of inhibition for both effectors was mixed-type. Complex kinetics of MT in the presence of a modulator could partly be ascribed to its mixed-cooperativity. However, to explain mixed-inhibition mode, it is necessary to demonstrate how the ternary complex of substrate/enzyme/effector is formed. Therefore, we looked for possible non-specific binding sites using MT tropolone-bound PDB (2Y9X) in the computational studies. When tropolone was in MTPa (active site), PA and CA occupied different pockets (named MTPb and MTPc, respectively). The close Moldock scores of PA binding posed in MTPb and MTPa suggested that MTPb could be a secondary binding site for PA. Similar results were obtained for CA. Ensuing results from 10 ns molecular dynamics simulations for 2Y9X-effector complexes indicated that the structures were gradually stabilized during simulation. Tunnel analysis by using CAVER Analyst and CHEXVIS resulted in identifying two distinct channels that assumingly participate in exchanging the effectors when the direct channel to MTPa is not accessible.