Impact of polar (DMSO, ethanol, water) solvation on geometry, spectroscopy (FT-IR, UV, NMR), quantum chemical parameters, and the antifungal activities of benzothiazole derivative by molecular docking approach

Due to their ubiquity and the rise of drug-resistant forms, Candida albicans infections pose a serious threat to world health. Exploring new molecular possibilities is essential in order to create newer antifungal medicines to address this challenge. Herein, the use of density functional theory at the B3LYP-D3BJ/aug-cc-pVDZ method along with the in silico molecular docking was utilized to examine the effects of polar (DMSO, ethanol, water) solvation on the reactivity, spectral (NMR, UV, FT-IR) investigation, and the antifungal potential of a bis[ethyl2-(4-hydroxy-3-{(E)-[(1,3-benzothiazol-2-yl)inimo]methyl} phenyl)-4-methyl-1,3-thiazole-5-carbo -xylate (BTZ). The study finds that polar solvents exert a notable influence on BTZ's reactivity, with the highest energy gap observed in the gas phase with a value of 3.4939 eV while in the solvents; the values are 3.4477, 3.4477, and 3.4422 eV for DMSO, ethanol, and water, respectively. This observation implies that BTZ may exhibit varying degrees of reactivity under different solvents. To evaluate BTZ's suitability as a potential antifungal agent, absorption, distribution, metabolism, excretion, and toxicity (ADMET) studies were conducted which reveals that BTZ adheres to Lipinski's rule of five, demonstrating its drug-like potential. Molecular docking simulations against Candida albicans proteins (1ZAP and 6ZDU) show promising binding affinities, with BTZ exhibiting a strong interaction with 1ZAP (-5.4 kcal/mol). The findings of this research contribute valuable insights into the reactivity and potential antifungal activity of BTZ, providing a promising candidate for further exploration in the quest for effective treatments against Candida infections

Exploration of semi-carbazone derivatives as promising agents against cholera: Insights from spectroscopic analysis, reactivity studies (ELF, HOMO-LUMO, NBO), solvation effects, and molecular docking investigations

This study is aimed at evaluating the impact of solvation on the structural, spectroscopy (UV, NMR, FT-IR), reactivity, bonding interactions, and the drug potential of Pyridine 4-Carbaldehyde Semi-carbazone (PCS) against the disease (cholera) causing protein in the Gram-negative bacterium; Vibrio cholerae. Notably, the study was carried out using both experimental and theoretical calculations based on density functional theory (DFT) at the GD3B/B3LYP/6–311G++(2D,2P) level of theory along with molecular docking. Results from the UV- spectrum showed very fair absorption levels across the different solvents used, with theoretical peaks at 463 nm, 467 nm, 470 nm and 468 nm for PCS_DMSO, PCS_ETOH, PCS_H2O and PCS_MEOH, respectively. The study reveals discrepancies between experimental and theoretical 1H NMR shifts. However, theoretical 13C NMR shifts show minute differences. RDG analysis reveals steric repulsions in the pyridine ring. Whereas, the investigation of electronic properties reveal that the decreasing order of PCS_DMSO (3.668 eV) > PCS_H2O (3.206 eV) > PCS_MEOH (3.202 eV) > PCS_ETOH (0.312 eV). The results of docking showed that PCS had binding affinities of -5.0 Kcal/mol with protein 7P3R and -5.4 Kcal/mol with protein 1XTC which happen to be much lesser than -10.2 Kcal/mol formed between erythromycin and 7P3R. However, erythromycin formed a non-feasible bonding interactions with 1XTC with biding affinity of 18.0 Kcal/mol. Results of the MD simulation showed that PCS-MEOH had a higher energy value than PCS-DMSO, PCS-ETOH, and PCS-H2, indicating that it can interact with other substances more effectively, disperse more quickly. These results from the various studied objectives, however, suggest Pyridine 4-Carbaldehyde Semi-carbazone to be a lead compound for tackling the incidence, distribution and prevalence of cholera