Pulsatillic acid as a potential inhibitor of protein kinase C-alpha in non-small cell lung cancer.

Non-small cell lung cancer (NSCLC) is a global health concern with a significant impact on morbidity and mortality. Small molecule inhibitors targeting genetic mutations like EGFR and ALK have shown promise in NSCLC treatment. This study focuses on Protein Kinase C-alpha (PKCα), implicated in NSCLC pathogenesis. Overexpression of PKCα correlates with advanced disease stages. Preclinical studies suggest its inhibition can suppress NSCLC cell growth. The research employs molecular docking to identify Pulsatillic acid (PA) as a potential PKCα inhibitor. ADMET predictions support PA's candidacy and PASS analysis and Swiss Target Prediction reveal its biological properties. Fluorescence-based binding assays demonstrate PA's inhibitory potency on PKCα, aligning with molecular docking findings. Cytotoxicity assays show PA's minimal impact on HEK-293 cell viability, with an IC50 of 21.03 µM in A549 cells. mRNA expression analysis in A549 cells indicates PA's potential inhibitory effect on PKCα. In conclusion, this study highlights that PA may emerge as a promising therapeutic candidate for NSCLC, emphasizing the need for further research, validation, and exploration of its translational potential. The study contributes valuable insights into NSCLC treatment strategies, emphasizing the significance of targeting PKCα.

In-silico and in-vitro studies revealed alpha-amyrin as a potent pnhibitor of TLR2 for the therapeutics of bacterial infection and sepsis.

This study employed a multifaceted approach to investigate the inhibitory potential of alpha-amyrin against TLR2, a key player in bacterial infection and sepsis. A high-resolution TLR2 model was constructed using Swiss-MODEL, exhibiting excellent quality with 100% sequence identity and coverage. Cavity detection revealed five significant cavities on TLR2. Molecular docking identifies alpha-amyrin as a potent inhibitor, displaying a strong binding affinity of -8.6 kcal/mol. Comprehensive analyses, including ADMET predictions, PASS analysis, and SwissTargetPrediction, affirm alpha-amyrin's drug-like properties and diverse biological activities. Cytotoxicity assays on HEK-293 cells confirm its safety, and fluorescence-based inhibition assays provide empirical evidence of its inhibitory potency on TLR2 enzymatic activity. Further validations in HUVECs show a significant decrease in TLR2 mRNA expression (p<0.01) and activity (p<0.05) upon alpha-amyrin treatment. In conclusion, this integrative study positions alpha-amyrin as a promising therapeutic candidate for TLR2 inhibition, emphasizing its potential in combating bacterial infections with safety and efficacy.

Thymoquinone Nanoparticles (TQ-NPs) in Kidney Toxicity Induced by Ehrlich Ascites Carcinoma (EAC): An In Vivo Study.

Background: Cisplatin (Cis) is potent chemotherapy used to treating already many different types of cancer; however, it is found to correlate with nephrotoxicity and other adverse health consequences. Thymoquinone (TQ) is an antioxidant and anti-inflammatory molecule that may defend against the consequences of different chemotherapies. Thymoquinone uses, although, are negatively impacted by its weak solubility and inadequate biological availability. Objectives: This investigation examined the efficacy of a new nanoparticle (NP) absorbing TQ in an Ehrlich Ascites Carcinoma (EAC) mice model to address its low solubility, enhance its bioavailability, and protect against Cis-induced nephrotoxicity. Methods: Following 4 treatment groups were included in this research: (1) control, (2) EAC, (3) EAC + Cis + Thymoquinone nanoparticle (TQ-NP) treated, and (4) EAC + Cis-treated. Results: The study revealed that TQ-NP was efficacious in avoiding Cis-induced kidney problems in EAC mice, as well as restoring kidney function and pathology. Thymoquinone nanoparticle considerably reduced Cis-induced oxidative damage in renal tissue by augmenting antioxidant levels. According to tumor weight and histological investigation results, TQ-NP did not impair Cis's anticancer efficacy. Conclusion: Thymoquinone nanoparticle might be used as a potential drug along with Cis anticancer therapy to reduce nephrotoxicity and other side effects while maintaining Cis anticancer properties.

Contexte: Le cisplatine (CIS) est un puissant agent chimiothérapeutique utilisé pour le traitement de nombreux types de cancers. Le cisplatine est cependant corrélé à de la néphrotoxicité et à d'autres conséquences néfastes pour la santé. La thymoquinone (TQ) est une molécule antioxydante et anti-inflammatoire qui peut protéger contre les effets néfastes de différents agents chimiothérapeutiques. Les faibles solubilité et biodisponibilité de la TQ limitent toutefois son utilisation. Objectifs: Un modèle de souris atteintes d'un carcinome ascitique d'Ehrlich (souris EAC) a servi à vérifier l'efficacité d'une nouvelle nanoparticule (NP) absorbant la TQ pour remédier aux faibles solubilité et biodisponibilité de la TQ et protéger contre la néphrotoxicité induite par le CIS. Méthodologie: Les quatre groupes suivants ont été examinés: i) témoin; ii) souris EAC; iii) souris EAC traitées par CIS + TQ-NP (thymoquinone-nanoparticule); iv) souris EAC traitées par CIS. Résultats: L'étude a révélé que la TQ-NP était efficace pour éviter les problèmes rénaux induits par le CIS chez les souris EAC, de même que pour restaurer la fonction rénale et soigner la pathologie. En augmentant les niveaux d'antioxydants, la TQ-NP a considérablement réduit les dommages oxydatifs induits par le CIS dans le tissu rénal. Selon le poids des tumeurs et les résultats de l'étude histologique, la TQ-NP n'a pas altéré l'efficacité anticancéreuse du CIS. Conclusion: La TQ-NP pourrait potentiellement être utilisée avec le traitement anticancéreux par CIS afin de réduire la néphrotoxicité et les autres effets secondaires, sans altérer les propriétés anticancer du CIS.