Poly lactide-co-glycolide encapsulated nano-curcumin promoting antagonistic interactions between HSP 90 and XRCC1 proteins to prevent cypermethrin-induced toxicity: An in silico predicted in vitro and in vivo approach.

The present study describes the preparation and characterization of poly-lactide-co-glycolide encapsulated nano-curcumin (NCUR) drug, and its potential efficacy against the pesticide, such as cypermethrin-induced DNA damage and genotoxicity. Cypermethrin, the chosen pesticide, contaminates the aquatic environment after being washed off from the agricultural field to nearby water bodies leading to biomagnification-related perturbation of the ecological balance and overall environmental health by elevating adverse effects on non-target organisms producing toxic metabolites through biotransformation. The physico-chemical properties of NCUR were evaluated by employing the AFM, DLS and UV-Vis techniques. Sustainable release of NCUR, their bio-availability and ability to cross the blood-brain-barrier was assessed in the fish model. The in silico molecular docking study to identify the signalling proteins that interact with phyto-core-compound curcumin (CUR) was undertaken to predict the effectiveness of NCUR to combat pesticide-induced toxicity by modulating p53, PARP, HSP 90 and XRCC1 stress proteins, and other associated parameters in in vivo model using tilapia fish and in vitro model using L6 (mammalian skeletal muscle) cell line. Overall results revealed that negatively charged poly-lactide-co-glycolide (PLGA)-encapsulated NCUR (∼46 nm) showed hyperchromic binding with DNA and modulated the signalling cascades involved in stress and DNA repair mechanisms, corroborating well with the in silico prediction that would pave a new pathway in the arena of chemical and biological sciences to serve mankind.