In-Silico Analysis and Antidiabetic Effect of α-Amylase and α-Glucosidase Inhibitory Peptides from Lupin Protein Hydrolysate: Enzyme-Peptide Interaction Study Using Molecular Docking Approach.
Gbemisola J FadimuAsgar FarahnakyHarsharn GillOlusegun Abayomi OlalereChee Yuen GanTuyen TruongPublished in: Foods (Basel, Switzerland) (2022)
The use of natural ingredients for managing diabetes is becoming more popular in recent times due to the several adverse effects associated with synthetic antidiabetic medications. In this study, we investigated the in vitro antidiabetic potential (through inhibition of α-glucosidase (AG) and α-amylase (AA)) of hydrolysates from lupin proteins pretreated with ultrasound and hydrolyzed using alcalase (ACT) and flavourzyme (FCT). We further fractionated ACT and FCT into three molecular weight fractions. Unfractionated ACT and FCT showed significantly ( p < 0.05) higher AG (IC 50 value = 1.65 mg/mL and 1.91 mg/mL) and AA (IC 50 value = 1.66 mg/mL and 1.98 mg/mL) inhibitory activities than their ultrafiltrated fractions, where lower IC 50 values indicate higher inhibitory activities. Then, ACT and FCT were subjected to peptide sequencing using LC-MS-QTOF to identify the potential AG and AA inhibitors. Molecular docking was performed on peptides with the highest number of hotspots and PeptideRanker score to study their interactions with AG and AA enzymes. Among the peptides identified, SPRRF, FE, and RR were predicted to be the most active peptides against AG, while AA inhibitors were predicted to be RPR, PPGIP, and LRP. Overall, hydrolysates prepared from lupin proteins using alcalase and flavourzyme may be useful in formulating functional food for managing diabetics.
Keyphrases
- molecular docking
- molecular dynamics simulations
- quantum dots
- amino acid
- highly efficient
- visible light
- type diabetes
- magnetic resonance imaging
- cardiovascular disease
- human health
- small cell lung cancer
- metabolic syndrome
- risk assessment
- glycemic control
- skeletal muscle
- ultrasound guided
- insulin resistance
- atomic force microscopy
- weight loss
- single molecule
- brain metastases
- high speed