Pyrazole, imidazole and triazole: In silico, docking and ADMET studies against SARS-CoV-2.

The Coronavirus pandemic, Covid-19 and SARS-Cov-2 put multidisciplinary research by chemists, biologists, pharmacists and theorists necessary and primordial task to find new active biomolecules which will be beneficial for all humanity. The azoles drugs are electronic rich, they should be used with caution, and an understanding of their pharmacokinetic profile, safety, absorption, distribution, excretion, metabolism, toxicity, and drug-drug interaction profiles is important to provide effective and cure therapy. In these objectives and goals, twenty aromatic nitrogen heterocycle compounds were chosen for in silico, docking and AMET studies against SARS-CoV-2. In this paper with respect to the protein S of SARS-CoV-2 properties, the GAUSSIAN 09w program used in the semi-empirical method at the AM1 level with the optimization of the geometry of the structures. Then Toxicity and physicochemical properties were evaluated by AMET. Molecular docking investigations conducted; the binding affinities as well as interactions of the sieve compounds with the SRAS-CoV-2 protein Spike using PyRx software. In general, the preliminary results are fructuous and needs further in vitro testes.

New azole antifungal agents with novel modes of action: synthesis and biological studies of new tridentate ligands based on pyrazole and triazole.

The synthesis and extensive biological study of two new tridentates ligands based on pyrazole and triazole are described. The antifungal activity against the budding yeast cells of the newly synthesized compounds was determined. These compounds were toxic to yeast cells. Cell cycle analysis suggested that treatment with these compounds impairs cell division in G1 of the cell cycle. Using yeast-based functional genomics technologies, we found that these compounds tolerance requires DNA repair pathway and SKI complex function. We have also found that the PKC1 heterozygous deletion strain was the most sensitive to these compounds using HaploInsufficiency Profiling, suggesting that the Pkc1 protein may be the target for these compounds. These results strongly suggest that these compounds induce DNA damage and thus exert a different mechanism of action compared to other azole derivatives. These two compounds might therefore represent promising lead compounds for further development of antifungal drugs for human therapy.