Publication:
Effects of propolis, caffeic acid phenethyl ester, and pollen on renal injury in hypertensive rat: An experimental and theoretical approach

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dc.contributor.authorSalmas, Ramin Ekhteiari
dc.contributor.authorGülhan, Mehmet Fuat
dc.contributor.authorDurdagi, Serdar
dc.contributor.authorŞahna, Engin
dc.contributor.authorAbdullah, Huda Ismail
dc.contributor.authorSelamoglu, Zeliha S.
dc.contributor.institutionSalmas, Ramin Ekhteiari, Department of Biophysics, Bahçeşehir Üniversitesi, Istanbul, Turkey
dc.contributor.institutionGülhan, Mehmet Fuat, Department of Medicinal and Aromatic Plants, Vocational School of Technical Sciences, Aksaray, Turkey
dc.contributor.institutionDurdagi, Serdar, Department of Biophysics, Bahçeşehir Üniversitesi, Istanbul, Turkey
dc.contributor.institutionŞahna, Engin, Department of Pharmacology, Firat Üniversitesi, Elazig, Turkey
dc.contributor.institutionAbdullah, Huda Ismail, Department of Medical Biology, Niğde Ömer Halisdemir University, Nigde, Turkey
dc.contributor.institutionSelamoglu, Zeliha S., Department of Medical Biology, Niğde Ömer Halisdemir University, Nigde, Turkey
dc.date.accessioned2025-10-05T16:15:43Z
dc.date.issued2017
dc.description.abstractThe objective of this study was to evaluate the antioxidant effects of propolis, caffeic acid phenethyl ester (CAPE, active compound in propolis), and pollen on biochemical oxidative stress biomarkers in rat kidney tissue inhibited by Nω-nitro-L-arginine methyl ester (L-NAME). The biomarkers evaluated were paraoxonase (PON1), oxidative stress index (OSI), total antioxidant status (TAS), total oxidant status (TOS), asymmetric dimethylarginine (ADMA), and nuclear factor kappa B (NF-κB). TAS levels and PON1 activity were significantly decreased in kidney tissue samples in the L-NAME-treated group (P < 0.05). The levels of TAS and PONI were higher in the L-NAME plus propolis, CAPE, and pollen groups compared with the L-NAME-treated group. TOS, ADMA, and NF-κB levels were significantly increased in the kidney tissue samples of the L-NAME-treated group (P < 0.05). However, these parameters were significantly lower in the L-NAME plus propolis, CAPE, and pollen groups (P < 0.05) compared with rats administered L-NAME alone (P < 0.05). Furthermore, the binding energy of CAPE within catalytic domain of glutathione reductase (GR) enzyme as well as its inhibitory mechanism was determined using molecular modeling approaches. In conclusion, experimental and theoretical data suggested that oxidative alterations occurring in the kidney tissue of chronic hypertensive rats may be prevented via active compound of propolis, CAPE administration. © 2017 Elsevier B.V., All rights reserved.
dc.identifier.doi10.1002/cbf.3277
dc.identifier.endpage314
dc.identifier.issn10990844
dc.identifier.issn02636484
dc.identifier.issue6
dc.identifier.pubmed28833317
dc.identifier.scopus2-s2.0-85028434459
dc.identifier.startpage304
dc.identifier.urihttps://doi.org/10.1002/cbf.3277
dc.identifier.urihttps://hdl.handle.net/20.500.14719/12003
dc.identifier.volume35
dc.language.isoen
dc.publisherJohn Wiley and Sons Ltd vgorayska@wiley.com Southern Gate Chichester, West Sussex PO19 8SQ
dc.relation.sourceCell Biochemistry and Function
dc.subject.authorkeywordsCape
dc.subject.authorkeywordsHypertension
dc.subject.authorkeywordsMm-pbsa
dc.subject.authorkeywordsMolecular Dynamics Simulations
dc.subject.authorkeywordsMolecular Modeling
dc.subject.authorkeywordsPollen
dc.subject.authorkeywordsPropolis
dc.subject.authorkeywordsCaffeic Acid Phenethyl Ester
dc.subject.authorkeywordsHydrogen
dc.subject.authorkeywordsN(g) Nitroarginine Methyl Ester
dc.subject.authorkeywordsN(g),n(g) Dimethylarginine
dc.subject.authorkeywordsPropolis
dc.subject.authorkeywordsArginine
dc.subject.authorkeywordsArginine Methyl Ester
dc.subject.authorkeywordsAryldialkylphosphatase
dc.subject.authorkeywordsGlutathione Reductase
dc.subject.authorkeywordsPhenethyl Alcohol
dc.subject.authorkeywordsAntioxidants
dc.subject.authorkeywordsArginine
dc.subject.authorkeywordsArginine Methyl Ester
dc.subject.authorkeywordsAryldialkylphosphatase
dc.subject.authorkeywordsCaffeic Acid Phenethyl Ester
dc.subject.authorkeywordsCaffeic Acids
dc.subject.authorkeywordsGlutathione Reductase
dc.subject.authorkeywordsN,n-dimethylarginine
dc.subject.authorkeywordsNf-kappa B
dc.subject.authorkeywordsPhenylethyl Alcohol
dc.subject.authorkeywordsPropolis
dc.subject.authorkeywordsAntioxidant
dc.subject.authorkeywordsAryldialkylphosphatase 1
dc.subject.authorkeywordsBiological Marker
dc.subject.authorkeywordsCaffeic Acid Phenethyl Ester
dc.subject.authorkeywordsHydrogen
dc.subject.authorkeywordsImmunoglobulin Enhancer Binding Protein
dc.subject.authorkeywordsN(g) Nitroarginine Methyl Ester
dc.subject.authorkeywordsN(g),n(g) Dimethylarginine
dc.subject.authorkeywordsOxidizing Agent
dc.subject.authorkeywordsPropolis
dc.subject.authorkeywordsArginine
dc.subject.authorkeywordsArginine Methyl Ester
dc.subject.authorkeywordsAryldialkylphosphatase
dc.subject.authorkeywordsCaffeic Acid Derivative
dc.subject.authorkeywordsGlutathione Reductase
dc.subject.authorkeywordsN,n-dimethylarginine
dc.subject.authorkeywordsPhenethyl Alcohol
dc.subject.authorkeywordsAnimal Experiment
dc.subject.authorkeywordsAnimal Model
dc.subject.authorkeywordsAnimal Tissue
dc.subject.authorkeywordsAntihypertensive Activity
dc.subject.authorkeywordsAntioxidant Activity
dc.subject.authorkeywordsArticle
dc.subject.authorkeywordsBiochemical Analysis
dc.subject.authorkeywordsChemical Parameters
dc.subject.authorkeywordsComputer Model
dc.subject.authorkeywordsConformational Transition
dc.subject.authorkeywordsControlled Study
dc.subject.authorkeywordsCrystal Structure
dc.subject.authorkeywordsDrug Mechanism
dc.subject.authorkeywordsEntropy
dc.subject.authorkeywordsEnzyme Active Site
dc.subject.authorkeywordsEvaluation Study
dc.subject.authorkeywordsExperimental Study
dc.subject.authorkeywordsHydrogen Bond
dc.subject.authorkeywordsHypertension
dc.subject.authorkeywordsKidney Injury
dc.subject.authorkeywordsKidney Tissue
dc.subject.authorkeywordsKidney Tubule Absorption
dc.subject.authorkeywordsMale
dc.subject.authorkeywordsMolecular Docking
dc.subject.authorkeywordsMolecular Dynamics
dc.subject.authorkeywordsMolecular Model
dc.subject.authorkeywordsNonhuman
dc.subject.authorkeywordsOxidative Stress
dc.subject.authorkeywordsOxidative Stress Index
dc.subject.authorkeywordsPollen
dc.subject.authorkeywordsPriority Journal
dc.subject.authorkeywordsProtein Interaction
dc.subject.authorkeywordsRat
dc.subject.authorkeywordsTheoretical Study
dc.subject.authorkeywordsTotal Antioxidant Status
dc.subject.authorkeywordsTotal Oxidant Status
dc.subject.authorkeywordsAnalogs And Derivatives
dc.subject.authorkeywordsAnimal
dc.subject.authorkeywordsBinding Site
dc.subject.authorkeywordsChemistry
dc.subject.authorkeywordsDrug Effects
dc.subject.authorkeywordsHalf Life Time
dc.subject.authorkeywordsKidney Diseases
dc.subject.authorkeywordsMetabolism
dc.subject.authorkeywordsPathology
dc.subject.authorkeywordsProtein Tertiary Structure
dc.subject.authorkeywordsSprague Dawley Rat
dc.subject.authorkeywordsAnimals
dc.subject.authorkeywordsAntioxidants
dc.subject.authorkeywordsArginine
dc.subject.authorkeywordsAryldialkylphosphatase
dc.subject.authorkeywordsBinding Sites
dc.subject.authorkeywordsCaffeic Acids
dc.subject.authorkeywordsGlutathione Reductase
dc.subject.authorkeywordsHalf-life
dc.subject.authorkeywordsHypertension
dc.subject.authorkeywordsMale
dc.subject.authorkeywordsMolecular Docking Simulation
dc.subject.authorkeywordsMolecular Dynamics Simulation
dc.subject.authorkeywordsNf-kappa B
dc.subject.authorkeywordsOxidative Stress
dc.subject.authorkeywordsPhenylethyl Alcohol
dc.subject.authorkeywordsPollen
dc.subject.authorkeywordsPropolis
dc.subject.authorkeywordsProtein Structure, Tertiary
dc.subject.authorkeywordsRats
dc.subject.authorkeywordsRats, Sprague-dawley
dc.subject.indexkeywordsantioxidant
dc.subject.indexkeywordsaryldialkylphosphatase 1
dc.subject.indexkeywordsbiological marker
dc.subject.indexkeywordscaffeic acid phenethyl ester
dc.subject.indexkeywordshydrogen
dc.subject.indexkeywordsimmunoglobulin enhancer binding protein
dc.subject.indexkeywordsn(g) nitroarginine methyl ester
dc.subject.indexkeywordsn(g),n(g) dimethylarginine
dc.subject.indexkeywordsoxidizing agent
dc.subject.indexkeywordspropolis
dc.subject.indexkeywordsarginine
dc.subject.indexkeywordsarginine methyl ester
dc.subject.indexkeywordsaryldialkylphosphatase
dc.subject.indexkeywordscaffeic acid derivative
dc.subject.indexkeywordsglutathione reductase
dc.subject.indexkeywordsN,N-dimethylarginine
dc.subject.indexkeywordsphenethyl alcohol
dc.subject.indexkeywordsanimal experiment
dc.subject.indexkeywordsanimal model
dc.subject.indexkeywordsanimal tissue
dc.subject.indexkeywordsantihypertensive activity
dc.subject.indexkeywordsantioxidant activity
dc.subject.indexkeywordsArticle
dc.subject.indexkeywordsbiochemical analysis
dc.subject.indexkeywordschemical parameters
dc.subject.indexkeywordscomputer model
dc.subject.indexkeywordsconformational transition
dc.subject.indexkeywordscontrolled study
dc.subject.indexkeywordscrystal structure
dc.subject.indexkeywordsdrug mechanism
dc.subject.indexkeywordsentropy
dc.subject.indexkeywordsenzyme active site
dc.subject.indexkeywordsevaluation study
dc.subject.indexkeywordsexperimental study
dc.subject.indexkeywordshydrogen bond
dc.subject.indexkeywordshypertension
dc.subject.indexkeywordskidney injury
dc.subject.indexkeywordskidney tissue
dc.subject.indexkeywordskidney tubule absorption
dc.subject.indexkeywordsmale
dc.subject.indexkeywordsmolecular docking
dc.subject.indexkeywordsmolecular dynamics
dc.subject.indexkeywordsmolecular model
dc.subject.indexkeywordsnonhuman
dc.subject.indexkeywordsoxidative stress
dc.subject.indexkeywordsoxidative stress index
dc.subject.indexkeywordspollen
dc.subject.indexkeywordspriority journal
dc.subject.indexkeywordsprotein interaction
dc.subject.indexkeywordsrat
dc.subject.indexkeywordstheoretical study
dc.subject.indexkeywordstotal antioxidant status
dc.subject.indexkeywordstotal oxidant status
dc.subject.indexkeywordsanalogs and derivatives
dc.subject.indexkeywordsanimal
dc.subject.indexkeywordsbinding site
dc.subject.indexkeywordschemistry
dc.subject.indexkeywordsdrug effects
dc.subject.indexkeywordshalf life time
dc.subject.indexkeywordsKidney Diseases
dc.subject.indexkeywordsmetabolism
dc.subject.indexkeywordspathology
dc.subject.indexkeywordsprotein tertiary structure
dc.subject.indexkeywordsSprague Dawley rat
dc.subject.indexkeywordsAnimals
dc.subject.indexkeywordsAntioxidants
dc.subject.indexkeywordsArginine
dc.subject.indexkeywordsAryldialkylphosphatase
dc.subject.indexkeywordsBinding Sites
dc.subject.indexkeywordsCaffeic Acids
dc.subject.indexkeywordsGlutathione Reductase
dc.subject.indexkeywordsHalf-Life
dc.subject.indexkeywordsHypertension
dc.subject.indexkeywordsMale
dc.subject.indexkeywordsMolecular Docking Simulation
dc.subject.indexkeywordsMolecular Dynamics Simulation
dc.subject.indexkeywordsNF-kappa B
dc.subject.indexkeywordsOxidative Stress
dc.subject.indexkeywordsPhenylethyl Alcohol
dc.subject.indexkeywordsPollen
dc.subject.indexkeywordsPropolis
dc.subject.indexkeywordsProtein Structure, Tertiary
dc.subject.indexkeywordsRats
dc.subject.indexkeywordsRats, Sprague-Dawley
dc.titleEffects of propolis, caffeic acid phenethyl ester, and pollen on renal injury in hypertensive rat: An experimental and theoretical approach
dc.typeArticle
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dspace.entity.typePublication
local.indexed.atScopus
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person.identifier.scopus-author-id56412874000
person.identifier.scopus-author-id7004172389
person.identifier.scopus-author-id23471088100

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