In silico and in vitro studies on antidiabetic potential of Niacin ester derivative of Oleanolic acid Antidiabetic study

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Victor Anah
Samuel James Offor Offor
Aniekan Stephen Ebong Ebong
Olorunfemi A. Eseyin

Résumé

Background: Oleanolic acid (OA) has been found to exert bene?cial effects against Type 2 Diabetes mellitus and metabolic syndrome. This study aims at designing derivatives of OA and evaluating their binding affinities to protein targets implicated in diabetes. Synthesis, physicochemical and in vitro studies were carried out on one of the promising ligand – niacin derivative (ND). Method: Thirty derivatives of OA were designed with ChemDraw ultra. The eight targets implicated in diabetes include; ?-amylase (AAM); Protein Tyrosine Phosphatase 1B (PTP1B); Dipeptidyl peptidase (DPP4); ?-glucosidase (AGCS); Glycogen synthase kinases 3? (GSK3); Fructose-1,6-diphosphatase (F1,6DP); Peroxisome proliferator-activated receptor gamma (PPARG) and Glucokinase (GLK). These were downloaded from the Protein data bank. Ligands and targets were converted to pdbqt format using PyRx. Molecular docking was done using Autodock Vina. Discovery Studio was used to analyze ligand-protein binding interactions. Pharmacokinetic properties were calculated from pKCM website and molecular properties from molinspiration websites. Synthesis of ND was done base on acyl chloride nucleophilic substitution method. In vitro study was done using ?-amylase inhibition and glucose uptake by yeast cells methods. Results: In silico, Ligand 16 (ND) showed better binding activity on more than one target over OA. (AAM, DPP4, PPARG, PTB1B and GLK).  In vitro, the ?-amylase inhibition values for IC50; (Acarbose:48.21±0.56 ?g/mL, OA:26.40±0.32 ?g/mL; ND = 24.25±0.52). For % glucose uptake by yeast cells (OA=80.2; ND=88.5; Glibenclamide=72.6) Conclusion: Higher binding affinities, low IC50 and higher glucose uptake by yeast cells observed in niacin derivative ND show that it is a potential antidiabetic compound.

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Anah, V., Offor, S. J. O., Ebong, A. S. E., & Eseyin, O. A. (2024). In silico and in vitro studies on antidiabetic potential of Niacin ester derivative of Oleanolic acid: Antidiabetic study. Nigerian Journal of Pharmaceutical and Applied Science Research, 13(1), 65–75. https://doi.org/10.60787/nijophasr-v13-i1-535
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Bibliographies de l'auteur-e

Samuel James Offor Offor, University of Uyo

Associate Professor, Department of Pharmacology and Toxicology, University of Uyo

Aniekan Stephen Ebong Ebong, University of Uyo, Nigeria

Senior lecturer, Department of Pharmaceutical and Medicinal Chemistry, University of Uyo

Références

WHO (2019). Classification of Diabetes mellitus, 2019. https://www.who.int/health-topics/diabetes. Retrieved 19-06-2023.

Lankatillake, C, Huynh, T. and Dias, D, A. (2019). Understanding Glycaemic Control and Current Approaches for Screening Antidiabetic Natural Products from Evidence-based Medicinal Plants, Plant Methods. 15:105-140.

Liu, J. (1995). Pharmacology of oleanolic acid and ursolic acid. Journal of Ethnopharmacology, 49(2):57–68.

Pollier, J. and Goossens, A. (2012). Oleanolic Acid. Phytochemistry, 77:10-

Castelano J. M., Guinda, A., Delgado, T., Rada, M. and Cayuela, J. A. (2013). Biochemical Basis of the anti-diabetic activity of Oleanolic acid and Related Pentacyclic Triterpenes. Diabetes. 62(6):1791-1799.

Ashburn, T. T. (2004). Drug repurpositioning, identifying and developing new uses for existing drugs. Nat Rev Drug Discovery, 3(8): 673-83.

Guedes, I. A.,Costa, L. S. C., Dardenne, L. E. (2021). Drug Design and repurposing with Dockthor-Vs web Server focusing on SAR-Cov-2 therapeutic targets and their non-synonym variants. Scientific Report, 11:5543-51.

Olorunfemi A. Eseyin, Ekarika C. Johnson, Emmanuel I. Etim, Arnold C. Igboasoiyi, Emmanuel Attih, Sunday S. Udobre, Aniekan S. Ebong, Paschal C. Anthony, Edet E. Asanga, Goodnews E. Charles and Akaninyene O. Daniel (2022). In silico evaluation of the antidiabetic potentials of some quercetin derivatives. Journal of Drug Discovery and Research 1(1): 1-15.

Morrison, R. T. and Boyd, R. N. (2007). Organic Chemistry. 6th Ed, Pearson Education Ltd., London, pp798.

Harbone, J. B. (1984). The Terpenoids, Phytochemical Methods. 1:100-141.

Hansawasdi, C., Kawabata, J. and Takanori, K. (2000). Alpha-Amylase Inhibitors from Roselle (Hibiscus sabdariffa Linn.) Tea. Bioscience, Biotechnology and Biochemistry, 64:1041-1043.

Cirillo, V. (2008). Sugar Transport in Psychrophilic Yeast. Journal of Bacteriology, 106:247-252.

Trott, O. and Olson, A. J. (2010). AutoDock Vina: Improving the speed and accuracy of docking with a new scoring function, efficient optimization and multithreading, Journal of Computational Chemistry, 31: 455-461.

Johnson, E. C., Etim, E. I. and Archibong, E. O. (2017). Isolation, Characterization and Antidiabetic Potentials of Oleanolic acid from the leaves of Aspilia africana (Pers) CD Adams (Asteraceae), Journal of Pharmaceutical and Applied Sciences Research. 6(1): 26-32.