The Inhibitory Effects of the Herbals Secondary Metabolites (7α-acetoxyroyleanone, Curzerene, Incensole, Harmaline, and Cannabidiol) on COVID-19: A Molecular Docking Study.

BACKGROUND: Since the COVID-19 outbreak in early 2020, researchers and studies are continuing to find drugs and/or vaccines against the disease. As shown before, medicinal plants can be very good sources against viruses because of their secondary compounds which may cure diseases and help in survival of patients. There is a growing trend in the filed patents in this field. AIMS: In the present study, we test and suggest the inhibitory potential of five herbal based extracts including 7α-acetoxyroyleanone, Curzerene, Incensole, Harmaline, and Cannabidiol with antivirus activity on the models of the significant antiviral targets for COVID-19 like spike glycoprotein, Papain-like protease (PLpro), non-structural protein 15 (NSP15), RNA-dependent RNA polymerase and core protease by molecular docking study. METHODS: The Salvia rythida root was extracted, dried, and pulverized by a milling machine. The aqueous phase and the dichloromethane phase of the root extractive were separated by two-phase extraction using a separatory funnel. The separation was performed using the column chromatography method. The model of the important antivirus drug target of COVID-19 was obtained from the Protein Data Bank (PDB) and modified. TO study the binding difference between the studied molecules, the docking study was performed. RESULTS: These herbal compounds are extracted from Salvia rhytidea, Curcuma zeodaria, Frankincense, Peganum harmala, and Cannabis herbs, respectively. The binding energies of all compounds on COVID-19 main targets are located in the limited area of 2.22-5.30 kcal/mol. This range of binding energies can support our hypothesis for the presence of the inhibitory effects of the secondary metabolites of mentioned structures on COVID-19. Generally, among the investigated herbal structures, Cannabidiol and 7α- acetoxyroyleanone compounds with the highest binding energy have the most inhibitory potential. The least inhibitory effects are related to the Curzerene and Incensole structures by the lowest binding affinity. CONCLUSION: The general arrangement of the basis of the potential barrier of binding energies is in the order below: Cannabidiol > 7α-acetoxyroyleanone > Harmaline> Incensole > Curzerene. Finally, the range of docking scores for investigated herbal compounds on the mentioned targets indicates that the probably inhibitory effects on these targets obey the following order: main protease> RNA-dependent RNA polymerase> PLpro> NSP15> spike glycoprotein.

Analysis of medicinal and therapeutic potential of Withania somnifera derivatives against COVID-19.

Apart from chemical and allopathic drugs, several medicinal plants contain phytochemicals that are potentially useful to counter the COVID-19 pandemic. Withania somnifera (Ashwagandha), which has a good effect on some viral infections, can be considered as a candidate against the virus. In the present study, thirty-nine natural compounds of Ashwagandha were investigated in terms of their binding to the important drug targets to treat the COVID-19. Although the molecular docking calculations reveal the binding affinities of the compounds to Mpro, TMPRSS2, NSP15, PLpro, Spike RBD + ACE2, RdRp and NSP12 as targets in controlling the coronavirus enzymes, Withanoside II is expected to be the most effective compound due to the high affinity in binding with many of considered targets. Furthermore, the Withanoside III, IV, V, X, and XI have favorable binding affinities as ligands with respect to the MM/GBSA calculations. The molecular dynamics simulations MD explore a stable hydrogen bond network between ligands and the active sites residues. Also, the dynamic fluctuations of the binding site residues verify their tight binding to ligands. Moreover, the stability of ligand-protein complexes is approved by the RMSD ranges lower than 0.5 Å in equilibration zone for all mentioned complexes. The TMPRSS2-Withanolide Q and Mpro-Withanoside IV complexes are the most stable pairs using the MM/GBSA calculations and MD simulation.Communicated by Ramaswamy H. Sarma.

TMPRSS2 receptor in terms of human relative proteins and Mpro and NSP15 receptors on coronavirus itself target are the effective target for inhibitory effects of Withania somnifera compounds.The highest binding affinity is related for WithanolideD, WithanolideQ, WithanosideIV, WithanosideIII, WithanosideV, WithanosideII, and 2,3-Didehydrosomnifericin ligands on the Spike RBD + ACE2, TMPRSS2, Mpro, PLpro, RdRp, NSP15, and NSP12 receptors, respectively.Withanolide compounds on human related proteins targets and Withanoside structures on coronavirus itself receptors have the highest inhibitory potential.Withanoside II ligand is expected to be the most effective compound due to the high affinity to bind to many considered targets.The stability of ligand-protein complexes is approved by the RMSD ranges lower than 0.5 Å in equilibration zone for WithanolideQ-TMPRSS2 and WithanosideIV-Mpro complexes.

Study of tyramine-binding mechanism and insecticidal activity of oil extracted from Eucalyptus against Sitophilus oryzae.

The rice weevil, Sitophilus oryzae (L.), is a major pest of stored grains throughout the world, which causes quantitative and qualitative losses of food commodities. Eucalyptus essential oils (EOs) possess insecticidal and repellent properties, which make them a potential option for insect control in stored grains with environmentally friendly properties. In the current study, the binding mechanism of tyramine (TA) as a control compound has been investigated by funnel metadynamics (FM) simulation toward the homology model of tyramine1 receptor (TyrR) to explore its binding mode and key residues involved in the binding mechanism. EO compounds have been extracted from the leaf and flower part of Eucalyptus camaldulensis and characterized by GC/MS, and their effectiveness has been evaluated by molecular docking and conventional molecular dynamic (CMD) simulation toward the TyrR model. The FM results suggested that Asp114 followed by Asp80, Asn91, and Asn427 are crucial residues in the binding and the functioning of TA toward TyrR in Sitophilus Oryzae. The GC/MS analysis confirmed a total of 54 and 31 constituents in leaf and flower, respectively, where most of the components (29) are common in both groups. This analysis also revealed the significant concentration of Eucalyptus and α-pinene in leaves and flower EOs. The docking followed by CMD was performed to find the most effective compound in Eucalyptus EOs. In this regard, butanoic acid, 3-methyl-, 3-methyl butyl ester (B12) and 2-Octen-1-ol, 3,7-dimethyl- (B23) from leaf and trans- ß-Ocimene (G04) from flower showed the maximum dock score and binding free energy, making them the leading candidates to replace tyramine in TyrR. The MM-PB/GBSA and MD analysis proved that the B12 structure is the most effective compound in inhibition of TyrR.

The influence of 5-fluorouracil anticancer drug on the DNA base pairs; a quantum chemical study.

In the present study, various hydrogen bonded complexes between five-fluorouracil (FU) with AT and GC base pairs were studied. First, to determine the affinity of different sites of the parent structures (FU, AT, and GC) for the hydrogen bond formation, their molecular electrostatic potentials are explored. The complexation energies and the strength of individual HBs of the plausible complexes were evaluated by energetic, geometric, spectroscopic, topologic, and molecular orbital descriptors. Our results reveal that, the FU-GC complexes (34.76-44.42 kcal mol-1) are more stable than the FU-AT ones (21.00-30.35 kcal mol-1). Among the complexes, the FU3-AT1 and FU3-GC3 are the most stable structures in the both series, which can be related to the sites with the highest affinity. Second, a detail analysis of the hydrogen bond descriptors were performed to elucidate the effect of FU on the strength of HB interactions within the base pairs. Interestingly, due to the formation of various interactions between the active sites of basic molecules, the strength of HB within the base pairs in the most cases increase about +2.75 and +.57 kcal mol-1 for the GC and AT nucleobases, respectively. Finally, several aromatic indices (HOMA, FLU, NICS (0) and NICS (1)) were applied to evaluate the significance of π-electron delocalization (π-ED) of 5/6 membered rings. These results clearly show that the π-ED of the benchmark systems increase with the formation or strengthening of the HB, which is in line with the resonance assisted hydrogen bond theory.