The research explores the synthesis of a series of novel hybrid quinazolin-2,4-dione analogs bearing acetyl/amide bridged-nitrogen heterocyclic moieties such as azetidinone, pyrrole, oxazole, oxadiazole, thiazole, pyrazole, and thiazolidine scaffolds 2-16. The newly synthesized compounds were structurally confirmed by means of IR, 1 H-NMR, 13 C-NMR, MS and elemental analysis. In addition, an in silico molecular docking analysis of new compounds and standard drug (Chloroquine) has been performed to analyze the binding modes of interaction to the putative active site of Plasmodium falciparum Dihydroorotate dehydrogenase (pfDHODH). Aiming to search for potentially better antimalarials, a modern approach has been undertaken to identify new quinazolin-2,4-dione derivatives targeting pfDHODH. The identification of antimalarial activity of the newly synthesized compounds by using experimental techniques is expensive and requires extensive pains and labor. The compound 11 showed the highest binding affinity against pfDHODH. Moreover, the electrostatic potential (ESP) of the docked molecules was also calculated. Further, the pharmacokinetic properties (ADMET) of the prepared compounds were predicted through in silico technique.
Today, cancer is considered as one of the major reasons of death in human beings worldwide. We reported herein the synthesis, anticancer activity, and in silico docking studies of a series of nine quinazolindione‐based scaffolds bearing pyrimidine, pyridine, pyran, and pyrazole moieties (1‐9) through Michael addition, Vilsmeier‐Haack, Claisen‐Schmidt, and nucleophilic addition reactions. The chemical structures of the newly prepared compounds were ascertained by means of their spectral analysis techniques like IR, 1H‐nuclear magnetic resonance (NMR), 13C‐NMR, mass spectroscopy, and elemental analysis. This work was conducted to investigate the implication of Rho7 protein in breast and hepatocellular cancer cells aggressively. MCF‐7 and HepG2 cells have been selected as models for the effect of protein expression on breast and hepatocellular cancers cell growth. All prepared compounds were biologically evaluated for their antiproliferative efficacy on hepatic cancer cell lines (HepG2) and breast cancer cell lines (MCF‐7); also, their effects on normal cell lines (BALB/3T3) were studied. Moreover, in silico molecular docking studies were studied for the compounds against the binding site of Homo sapiens Rho7 protein. The pharmacokinetic properties of the newer compounds were also evaluated using various computational tools. The compounds showed interesting interactions with satisfactory docking scores to the target Rho7; thus, they may act as promising potent drug candidates against cancer.
Cholera is a bacterial disease featured by dehydration and severe diarrhea. It is mainly caused by alimentary infection with Vibrio cholerae. Due to the wide applicability of quinazolin-2,4-dione compounds in medicinal and pharmaceutical chemistry, a new series of N-containing heterocyclic compounds was synthesized. We used the in silico docking method to test the efficacy of quinazolin-2,4-dione compounds in the prevention of cholera in humans. The newly synthesized compounds showed strong interactions and good binding affinity to outer membrane protein OmpU. Moreover, the pharmacokinetic properties of the newly synthesized compounds, such as absorption, distribution, metabolic, excretion, and toxicity (ADMET), were predicted through in silico methods. Compounds with acceptable pharmacokinetic properties were tested as novel ligand molecules. The synthesized compounds were evaluated in vitro for their antibacterial activity properties against Gram-negative Escherichia coli O78 strain using the minimum inhibition concentration (MIC) method. Compounds 2 and 6 showed reproducible, effective antibacterial activity. Hence, our study concludes that the quinazolin-2,4-dione derivatives 1 to 8 may be used as promising drug candidates with potential value for the treatment of cholera disease.
Inflammation is the response of the body's immune system to harmful stimuli. The expression of phosphodiesterase 4 enzyme (PDE4) was demonstrated in many inflammatory cells. Thus, it was considered an attractive therapeutic target for combating inflammatory disorders. In the present study, a novel class of quinazolin‐2,4‐dione analogues 1‐17a,b was synthesized. Structures of the newly synthesized compounds were characterized by means of spectral and elemental analysis. Additionally, molecular docking studies for the new synthetic compounds were performed using PyRx—virtual screening tool to demonstrate the possible binding pattern mode of interactions within the active site region of the PDE4 enzyme. The antiinflammatory activity of the synthesized compounds was also in vitro examined using inhibition of protein denaturation, anti‐proteinase effect, and membrane stabilization assay. The in silico docking studies revealed that the newly synthesized compounds were well accommodated by the active site region of the target protein through a network of noncovalent interactions such as hydrogen bonds and pi‐stacking, which contributed to the enhancement of affinity and stability between the compounds and the target protein. They exhibited better docking scores when compared with reference drugs diclofenac and coumarin. In addition, in vitro testing revealed that the compounds had moderate to good antiinflammatory effects. The biological study agreed with in silico approach, which revealed that the compounds had promising antiinflammatory activity. Hence, our detailed results can facilitate the rational drug design targeting PDE4 enzyme.
The dual c-Met/vascular endothelial growth factor receptor 2 (VEGFR-2) TK inhibition is a good strategy to overcome therapeutic resistance to small molecules VEGFR-2 inhibitors. In this study, we designed 3-substituted quinazoline-2,4(1 H ,3 H )-dione derivatives as dual c-Met/VEGFR-2 TK inhibitors. We introduced new synthetic methods for reported derivatives of 3-substituted quinazoline-2,4(1 H ,3 H )-dione 2a – g , in addition to the preparation of some new derivatives namely, 3 and 4a – j . Three compounds namely, 2c , 4b , and 4e showed substantial amount of inhibition for both c-Met and VEGFR-2 TK (IC 50 range 0.052–0.084 µM). Both compounds 4b , 4e showed HB with highly conserved residue Asp1222 in the HB region of c-Met TK. For VEGFR-2 TK, compound 4b showed HB with a highly conserved residue Asp1046 in the HB region. Compound 4e showed HB with Glu885 and Asp1046. Moreover, in silico prediction of pharmacokinetic and physicochemical parameters of target compounds was carried out using SwissADME website. The quinazoline-2,4(1 H ,3 H )-dione derivatives are promising antiproliferative candidates that require further optimisation. Highlights New 3-substituted quinazoline-2,4(1 H ,3 H )-dione derivatives were synthesised and characterised. Compounds 4b and 4e showed higher cytotoxic activity than cabozantinib against HCT-116 colorectal cell lines. Both compounds 4b and 4e showed less toxicity to WI38 normal cell line compared to HCT 116 colon cancer cell line. Compound 4b was superior to cabozantinib in VEGFR-2 inhibition while compound 2c was equipotent to cabozantinib. Compounds 4b and 4e showed remarkable c-Met inhibitory activity. Compounds 4b and 4e arrested cell cycle and induced significant levels of apoptosis. In silico ADME prediction revealed high oral bioavailability and enhanced water solubility of target compounds as compared to cabozantinib. Target compounds interacted with both c-Met and VEGFR-2 active site in similar way to ca...
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