Diabetes, a chronic metabolic disease, has become a severe health problem worldwide. According to the latest data from the International Diabetes Federation (IDF), there were 537 million diabetic mellitus (DM) patients worldwide in 2021, expected to increase to 783 million by 2045. Over 90% of people with diabetes have type 2 diabetes, which is driven by socio-economic, demographic, environmental, and genetic factors. Diabetes is still a major global health issue, with prevalence rates rising all across the world. This not only imposes a significant burden on healthcare systems but also impacts the quality of life of affected individuals and their families. Therefore, there is a continuous high demand worldwide to develop novel, more effective, and easily affordable medications against diabetes. This paper illustrates the in-vitro antidiabetic activity and probable binding mechanism prediction of phytoconstituents of Allamanda cathartica against type 2 diabetes molecular targets. Through the application of bioactivity score prediction, molecular docking, and ADMET prediction approach, the potential and selective phytoconstituents with the highest binding affinity and lower toxicity were gained from the curated datasets. Further molecular dynamics simulations and DFT calculations were carried out to identify the favorable binding conformations when the top-scored phytoconstituents bind with the PPAR[Formula: see text] receptors compared to the rosiglitazone. Compound AC2 interacts with the PPAR[Formula: see text] proteins by forming seven hydrogen bonds with the amino acid residues Phe282, His449, Tyr327, His323, and Ser289. The ligand was bound to the protein during the simulation since none of the complex conformations was unstable, and no unfolding or folding occurred. Our results provided an approach to further design and optimize the natural product-inspired small druglike molecules as potential antidiabetic agents. This study highlighted that the phytoconstituents of Allamanda cathartica have antidiabetic potential through the binding of PPAR[Formula: see text], [Formula: see text]-amylase and [Formula: see text]-glucosidase proteins that can be further explored for novel antidiabetic drug development.