Design, Synthesis, Molecular Docking, and Molecular Dynamics Simulation Studies of Novel 3-Hydroxypyridine-4-one Derivatives as Potential Acetylcholinesterase Inhibitors.

Researchers have focused on inhibiting acetylcholinesterase for Alzheimer's disease treatment. In this study, some novel AChE inhibitors were synthesized using hydroxypyridin-4-one plus benzylpiperidine scaffolds which were evaluated using Ellman's method. Accordingly, ((1-(4-methoxyphenethyl)piperidin-4-yl)amino)methyl)-5-hydroxy-1-methylpyridin-4(1H)-one (VIId ) showed weaker but promising AChE inhibition compared to donepezil (IC50 =143.090 nM). The average RMSD values of VIId was found to be 2.25 indicated less structural changes in the active site residues. The phenyl group of the phenyl-ethyl-N-piperidine moiety of VIId formed hydrophobic interactions with Trp285 and Tyr340. There was a π-cation interaction between nitrogen atom of piperidine ring and Phe294. Another π-cation interaction was found between type 2 amine of linker and Trp85. Piperidine ring interacted with Tyr336, Tyr123, and Phe337 through hydrophobic interactions. Indeed, the VIId was predicted to be absorbed across the gastrointestinal tract, though it may be pumped out by P-gp. Indeed, VIId can permeate through the blood brain barrier. MD simulation studies revealed that benzyloxy moiety plays a role similar to benzylpiperidine moiety of donepezil in binding to the active site residues. Also, carbonyl group functioned similar to indanone ketone group. Overall; further research on VIId may lead to introduction of a novel class of AChE inhibitors.

Synthesis of Some Benzothiazole Derivatives Based on 3-Hydroxypyridine-4-one and Benzaldehyde and Evaluation of Their ß-Amyloid Aggregation Inhibition Using both Experimental Methods and Molecular Dynamic Simulation.

Some novel inhibitors based on the (benzo[d]thiazol-2-yl)-1-phenylmethanimine derivatives were designed to reduce the aggregation process in Alzheimer's disease. These structures seem to mimic stilbene-like scaffold, while the benzothiazole moiety "locks" the thioflavin T binding site. Other inhibitors were designed based on 2-((benzo[d]thiazol-2-ylimino)methyl)-5-(benzyloxy)-1-methylpyridin-4(H)-one derivatives. Benzo[d]thiazol-2-amine derivatives were prepared by the reaction of aniline derivatives with ammonium thiocyanate in the presence of bromine/acetic acid. Then, the reaction of amines with benzaldehyde derivatives and 5-(benzyloxy)-1-methyl-4-oxo-1,4-dihydropyridine-2-carbaldehyde gave the desired compounds. The plate reader-based fibrillation assay was done to evaluate the inhibition of Aß aggregation. Also, molecular dynamic simulation was carried out to clarify the interaction manner of the designed compounds with Aß formation. The biological evaluation proved 5a and 7e as the best inhibitor of the Aß aggregation. compound 5a in the concentration of 50 µM inhibited Aß fibril formation better than 7e. MD simulation elucidated that the Aß aggregation inhibitors in different concentrations represented different binding conformations throughout the entire or in one area of Aß. MD showed the ligands in lower concentrations accumulate in an area of Aß aggregations and separate one fibril from the aggregated Aß. On the contrary, in higher concentrations, the ligands tend to be located through the entire Aß.

Theoretical Evaluation of Oleocanthal Reactive Centers.

BACKGROUND: Decarboxymethyl ligstroside aglycone (Oleocanthal) is an essential component of olive oil. It is therefore interesting to study its metabolism in the human body. In order to find the best possible starting point for this metabolism, a theoretical study was carried out using DFT calculations and docking studies. METHODS: The DFT, B3LYP/6-311++G** and the PCM solvation model calculations were used to study the initial process of Oleocanthal metabolism by the CYP1A2 enzyme. Structures of radicals formed by homolytic dissociation of hydrogen atoms from the Oleocanthal structure were obtained and their properties were studied. Several parameters such as HOMO and LUMO energy gaps, Bond Dissociation Energy (BDE), hardness, and spin density of possible Oleocanthal radicals were taken into account. Docking of Oleocanthal into an enzyme binding pocket was also performed to locate the most probably metabolic site. Detailed analysis of the theoretical results allows the determination of the most likely reaction sites in Oleocanthal. The mode of binding of Oleocanthal to the CYP1A2 enzyme was also predicted. RESULTS: The results of the molecular docking studies are in agreement with the calculated quantum parameters. The theoretical predictions were compared with experimental data available in the scientific literature. A high correlation between theoretical calculations and experimental data was observed. The most likely site of Oleocanthal metabolism was identified. CONCLUSION: The results of our research support the usefulness of theoretical calculations in predicting metabolic pathways.

The effect of various compounds on the COVID mechanisms, from chemical to molecular aspects.

The novel coronavirus that caused COVID-19 pandemic is SARS-CoV-2. Although various vaccines are currently being used to prevent the disease's severe consequences, there is still a need for medications for those who become infected. The SARS-CoV-2 has a variety of proteins that have been studied extensively since the virus's advent. In this review article, we looked at chemical to molecular aspects of the various structures studied that have pharmaceutical activity and attempted to find a link between drug activity and compound structure. For example, designing of the compounds which bind to the allosteric site and modify hydrogen bonds or the salt bridges can disrupt SARS-CoV2 RBD-ACE2 complex. It seems that quaternary ammonium moiety and quinolin-1-ium structure could act as a negative allosteric modulator to reduce the tendency between spike-ACE2. Pharmaceutical structures with amino heads and hydrophobic tails can block envelope protein to prevent making mature SARS-CoV-2. Also, structures based on naphthalene pharmacophores or isosteres can form a strong bond with the PLpro and form a π-π and the Mpro's active site can be occupied by octapeptide compounds or linear compounds with a similar fitting ability to octapeptide compounds. And for protein RdRp, it is critical to consider pH and pKa so that pKa regulation of compounds to comply with patients is very effective, thus, the presence of tetrazole, phenylpyrazole groups, and analogs of pyrophosphate in the designed drugs increase the likelihood of the RdRp active site inhibition. Finally, it can be deduced that designing hybrid drug molecules along with considering the aforementioned characteristics would be a suitable approach for developing medicines in order to accurate targeting and complete inhibition this virus.

Density functional theory studies of the antioxidants-a review.

The following review article attempts to compare the antioxidant activity of the compounds. For this purpose, density functional theory/Becke three-parameter Lee-Yang-Parr (DFT/B3LYP) methodology was carried out instead of using pharmacological methodologies because of economic benefits and high accuracy. This methodology filtrates the compounds with the lowest antioxidant activity. At first, the Koopmans' theorem was carried out to calculate some descriptors to compare antioxidants. The energy of the highest occupied molecular orbitals (HOMO) was accepted as the best indicator, and then some studies confirmed that the highest occupied molecular orbital/lowest unoccupied molecular orbital (HOMO-LUMO) energy gap is the more precise descriptor. Although it would be better to compare spin density distribution (SDD) on the oxygen of the corresponding radical in the polarizable continuum model (PCM) to evaluate their capability to chain reaction inhibition. Next, it was mentioned that in the multi-target directed ligands (MTDLs), the antioxidant is connected to other moieties in para positions to create better antioxidants or novel hybrid compounds. Indeed, SDD was introduced as a descriptor for MTDL antioxidant effectiveness. Then, the relation between antioxidants and aromaticity was investigated. The more the aromaticity of an antioxidant, the more stable the corresponding radical is. Subsequently, in preferred antioxidant activity, it was defined that the hydrogen atom transfer (HAT) mechanism is more favored in metabolism phase I. It has been seen that the solvent model can change the antioxidant mechanism. Therefore, the solvent model is more important than the chemical structure of antioxidants, and an ideal antioxidant should be evaluated in PCM for pharmacological evaluations.