SCREENING OF Α-Glucosidase INHIBITORS FROM TERMINALIA CATAPPA L. FRUITS USING MOLECULAR DOCKING METHOD AND IN VITRO TEST

Sari, Bina Lohita; Mun’im, Abdul; Yanuar, Arry; Riadhi, Rezi

doi:10.22159/ijpps.2016v8i12.14800

Cited by 8 publications

(7 citation statements)

References 16 publications

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“…Hal ini diperkuat dengan penelitian yang dilakukan oleh Shivanagoudra terhadap ekstrak etil asetat buah melon cina dimana senyawa 25-isopropenylchole-5,(6)-ene-3-O-β-Dglucopyranoside (IDG) yang terkandung didalam ekstrak etil aseat buah melon cina terikat pada residu Leu313, Asp242, Pro312, Val308, Val319 dan His280 di katalitik situs glukosidase. 25 IDG menghasilkan pose docking terbaik dibandingkan senyawa lain, yaitu 25-trihydroxycucurbita-5, 23(E)-dien-19-al (TCD) and charantaB yang diisolasi dari ekstrak etil asetat daun M. Charantina dengan energi ikat minimum -10,58 kkal / mol. Ligan dikelilingi oleh residu katalitik Asp 242 dan interaksi itu mungkin penting untuk penghambatan glukosidase.…”

Section: Interaksiunclassified

“…Akarbose dikelilingi oleh 18 residu asam amino sebagai situs aktifnya: Asp69, Tyr72, Tyr158, Phe159, Phe178, Asp215, Val216, Glu277, Glu279, Phe303, Asp307, Thr310, Ser311, Arg315, Asp352, Glu411 dan Arg442. 25 Interaksi yang mengikat dapat mengakibatkan penghambatan enzim. Peningkatan energi ikat meningkatkan simultan dalam energi ikat sehingga menyebabkan akarbose menghambat enzim α-Glukosidase secara kompetiti.…”

Section: Interaksiunclassified

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Molecular Docking of Active Compounds Piper crocatum on the A-Glucosidase Enzyme as Antidiabetic

Weni¹,

Safithri²,

Seno³

2020

IJPST

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Ethanol extract of Piper crocatum leaves has inhibitory activity of α-glucosidase enzyme. Ethyl acetate fraction from Piper crocatum leaves has the highest antioxidant activity. Previous research has provided information that the ethyl acetate fraction of Piper crocatum leaves has an inhibition of α-glucosidase containing 6XO32ZSP1D, Ethyl L-serinate hydrochloride compound, Schisandrin B compound, Columbin compound, 4- (4-methoxy-phenylamino) -2 compound, 3-dihydro-1H-4a, 9-diazacyclopenta (b) fluorine-10-carbonitrile, compound 6-Amino-4- [3- (benzyloxy) phenyl] -3-tert-butyl-2,4-dihydropyrano [2, 3-c] pyrazole-5-carbonitrile, compound 4 - {{4.6-Bis [(3R, 5S) -3,5-diamino-1-piperydinyl] -1,3,5-triazine-2-yl} amino) benzenesulfonamide and compound 1.1 '- (1,4-butanediyl) bis {2,6-dimethyl-4 - [(3-methyl-1,3-benzothiazol-2 (3H) ylidene) methyl] pyridinium. This study aims to study the interaction between bioactive compounds contained in ethyl acetate fraction of Piper crocatum leaves with α-glucosidase enzyme in In Silico using AutoDock Vina, Columbin shows the lowest binding energy with binding sites with amino acids Ser240, Asp242, His280, Arg315, Glu411, Phe159, Arg442, Tyr158 and Phe303. Columbin has the stability and inhibits the α-glucosidase enzyme from S. cerevisiae better than the seven other compounds, because it has OH and CH3 groups which play a role in the interaction with around the active side of the α-glucosidase enzyme.Keywords: Columbin, In Silico, α-Glucosidase

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Section: Interaksiunclassified

Molecular Docking of Active Compounds Piper crocatum on the A-Glucosidase Enzyme as Antidiabetic

Weni¹,

Safithri²,

Seno³

2020

IJPST

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“…The 3D structures of all the 10 selected ACE inhibitors were virtually screened to reveal their binding efficiencies through docking in the predicted binding site of ACE using FlexX module of LeadIT. The docking was performed with the default parameters [10][11][12].…”

Section: Virtual Screeningmentioning

confidence: 99%

Virtual Screening of Heterocyclic Compounds Against Angiotensin-Converting Enzyme for Potential Antihypertensive Inhibitors

A²,

Shanmugam³

2019

Asian J Pharm Clin Res

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Objective: The objective of this study was to investigate the antihypertensive activity of heterocyclic compounds against angiotensin-converting enzyme (ACE) through molecular docking studies. Methods: The X-ray crystal three-dimensional (3D) structure of human ACE complexed with lisinopril (PDB ID: 1O86) was retrieved from protein databank. The two-dimensional structures of 10 selected heterocyclic compounds were drawn in ACD-Chemsketch and converted into 3D structures. The 3D structures of compounds were virtually screened in the binding pockets of ACE using FlexX docking program. Further, the chemical entities revealing the molecular electronic structures of the best docked compound (Compound-4) were explored through density functional theory studies. Results: The Compound-4 showed the highest docking score of −26.6290 kJ/mol with ACE. The Hbond and non-bonded interactions are favored by phenylalanine, leucine, and arginine. The energy gap of 1.60 eV between highest occupied molecular orbital and lowest unoccupied molecular orbitals explained the presence of strong electron-acceptor group. Furthermore, the molecular electrostatic potential studies clearly envisaged the requirement of electropositive and electronegative groups are crucial for the ACE inhibitor activities. Conclusion: The identification of good ACE inhibitors requires the understanding of the current ACE inhibitors. Thus, the docking interactions of Compound-4 and its molecular electronic structure significantly imply its potential as antihypertensive agent. However, further clinical studies are required to ascertain its potential toxic effects.

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“…Homology modelling quality verified by PROCHECK (Sari et al, 2016). Using MAL32 target sequence and structure with PDB ID 3AJ7 as template, homology modelling of αglucosidase created by SWISS MODEL based on harmony of template of target using ProMod3.…”

Section: Homology Modellingmentioning

confidence: 99%

α-Glucosidase Inhibition Activity of Stem Bark Ceiba pentandra Linn. In Vitro and In Silico

Syihabudin

2018

Indonesian J. Pharm.

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Bark of Kapok (Ceiba pentandra (L.)) contains tannin, flavonoid, alkaloid, terpenoid, and saponin compounds. Flavonoid known to have inhibitory activity of α-glucosidase. The purpose of this study was to observe the n-hexane, ethyl acetate and water extract of bark of Ceiba pentandra (L.) to inhibitory activity of αglucosidase. The method used for the activity measurement of the fractions was spectrophotometry UV-Vis. Water fraction analyzed by LCMS/MS to identify the chemical compounds. The pure compound suspected analyzed using molecular docking to predict the complementarity related to the model of isomaltase αglucosidase using Autodock Vina, therefore the bond of the antidiabetic active compounds can be predicted. The results show the α-glucosidase inhibitory activity of the bark in n-hexane fraction is 4.60μg/mL, ethyl acetate fraction is 8.55μg/mL and water fraction is 5.61μg/mL. Water fraction analyzed by LCMS/MS eludated at retention time of 3.61min be fathomed as (+) catechin derivate and at retention time of 8.70min be fathomed as vavain derivate. The vavain derived compound, (+) catechin derived compound, acarbose and quercetin each shows docking score of -8.1; -8.8; -6.2 and -7.6 kkal/mol and have similarity to amino acid Glu276 bond which is a catalytic residue that plays role in hydrolysis process. The similarity of chemical bond of the active site be expected to have the same activity as α-glucosidase inhibitory agent.

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SCREENING OF Α-Glucosidase INHIBITORS FROM TERMINALIA CATAPPA L. FRUITS USING MOLECULAR DOCKING METHOD AND IN VITRO TEST

Cited by 8 publications

References 16 publications

Molecular Docking of Active Compounds Piper crocatum on the A-Glucosidase Enzyme as Antidiabetic

Molecular Docking of Active Compounds Piper crocatum on the A-Glucosidase Enzyme as Antidiabetic

Virtual Screening of Heterocyclic Compounds Against Angiotensin-Converting Enzyme for Potential Antihypertensive Inhibitors

α-Glucosidase Inhibition Activity of Stem Bark Ceiba pentandra Linn. In Vitro and In Silico

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