Publication:
Apoptosis induction associated with the ER stress response through up-regulation of JNK in HeLa cells by gambogic acid

dc.contributor.authorKrajarng A.
dc.contributor.authorImoto M.
dc.contributor.authorTashiro E.
dc.contributor.authorFujimaki T.
dc.contributor.authorShinjo S.
dc.contributor.authorWatanapokasin R.
dc.date.accessioned2021-04-05T03:25:57Z
dc.date.available2021-04-05T03:25:57Z
dc.date.issued2015
dc.date.issuedBE2558
dc.description.abstractBackground: Gambogic acid (GA) was extracted from the dried yellow resin of gamboge (Garcinia hanburyi) which is traditionally used as a coloring material for painting and cloth dying. Gamboge has been also used as a folk medicine for an internal purgative and externally infected wound. We focused on the mechanisms of apoptosis induction by GA through the unfold protein response (ER stress) in HeLa cells. Methods: The cytotoxic effect of GA against HeLa cells was determined by trypan blue exclusion assay. Markers of ER stress such as XBP-1, GRP78, CHOP, GADD34 and ERdj4 were analyzed by RT-PCR and Real-time RT-PCR. Cell morphological changes and apoptotic proteins were performed by Hoechst33342 staining and Western blotting technique. Results: Our results indicated a time- and dose-dependent decrease of cell viability by GA. The ER stress induction is determined by the up-regulation of spliced XBP1 mRNA and activated GRP78, CHOP, GADD34 and ERdj4 expression. GA also induced cell morphological changes such as nuclear condensation, membrane blebbing and apoptotic body in Hela cells. Apoptosis cell death detected by increased DR5, caspase-8, -9, and -3 expression as well as increased cleaved-PARP, while decreased Bcl-2 upon GA treatment. In addition, phosphorylated JNK was up-regulated but phosphorylated ERK was down-regulated after exposure to GA. Conclusions: These results suggest that GA induce apoptosis associated with the ER stress response through up-regulation of p-JNK and down-regulation of p-ERK in HeLa cells. © 2015 Krajarng et al.
dc.format.mimetypeapplication/pdf
dc.identifier.citationBMC Complementary and Alternative Medicine. Vol 15, No.1 (2015)
dc.identifier.doi10.1186/s12906-015-0544-4
dc.identifier.issn14726882
dc.identifier.other2-s2.0-84924338427
dc.identifier.urihttps://hdl.handle.net/20.500.14740/6171
dc.rights.holderScopus
dc.subject.otherBIM protein
dc.subject.otherCaspase 3
dc.subject.otherCaspase 8
dc.subject.otherCaspase 9
dc.subject.otherDeath receptor 5
dc.subject.otherEndoplasmic reticulum localized DnaJ homologue protein
dc.subject.otherGambogic acid
dc.subject.otherGlucose regulated protein 78
dc.subject.otherGrowth arrest and DNA damage inducible protein 153
dc.subject.otherGrowth arrest and DNA damage inducible protein 34
dc.subject.otherHoe 33342
dc.subject.otherNicotinamide adenine dinucleotide adenosine diphosphate ribosyltransferase
dc.subject.otherNucleic acid binding protein
dc.subject.otherProcaspase 3
dc.subject.otherProcaspase 8
dc.subject.otherProcaspase 9
dc.subject.otherProtein bcl 2
dc.subject.otherProtein DnaJ
dc.subject.otherStress activated protein kinase
dc.subject.otherTunicamycin
dc.subject.otherUnclassified drug
dc.subject.otherX box binding protein 1
dc.subject.otherAntineoplastic agent
dc.subject.otherGambogic acid
dc.subject.otherHeat shock protein
dc.subject.otherMitogen activated protein kinase
dc.subject.otherMolecular chaperone GRP78
dc.subject.otherPlant extract
dc.subject.otherStress activated protein kinase
dc.subject.otherXanthone derivative
dc.subject.otherAntineoplastic activity
dc.subject.otherApoptosis
dc.subject.otherArticle
dc.subject.otherBinding site
dc.subject.otherBright field microscopy
dc.subject.otherCancer cell culture
dc.subject.otherCancer inhibition
dc.subject.otherCell proliferation
dc.subject.otherCell structure
dc.subject.otherCell survival
dc.subject.otherCell viability
dc.subject.otherConcentration response
dc.subject.otherControlled study
dc.subject.otherDNA flanking region
dc.subject.otherDown regulation
dc.subject.otherEndoplasmic reticulum stress
dc.subject.otherEnzyme phosphorylation
dc.subject.otherFemale
dc.subject.otherFluorescence microscopy
dc.subject.otherGarcinia
dc.subject.otherGarcinia hanburyi
dc.subject.otherHeLa cell line
dc.subject.otherHuman
dc.subject.otherHuman cell
dc.subject.otherProtein cleavage
dc.subject.otherProtein expression
dc.subject.otherProtein localization
dc.subject.otherReal time polymerase chain reaction
dc.subject.otherReverse transcription polymerase chain reaction
dc.subject.otherUpregulation
dc.subject.otherUterine cervix cancer
dc.subject.otherWestern blotting
dc.subject.otherApoptosis
dc.subject.otherChemistry
dc.subject.otherDrug effects
dc.subject.otherMetabolism
dc.subject.otherPhytotherapy
dc.subject.otherTranscription initiation
dc.subject.otherUpregulation
dc.subject.otherUterine Cervical Neoplasms
dc.subject.otherAntineoplastic Agents, Phytogenic
dc.subject.otherApoptosis
dc.subject.otherCell Survival
dc.subject.otherDown-Regulation
dc.subject.otherEndoplasmic Reticulum Stress
dc.subject.otherExtracellular Signal-Regulated MAP Kinases
dc.subject.otherFemale
dc.subject.otherGarcinia
dc.subject.otherHeat-Shock Proteins
dc.subject.otherHeLa Cells
dc.subject.otherHumans
dc.subject.otherJNK Mitogen-Activated Protein Kinases
dc.subject.otherPhytotherapy
dc.subject.otherPlant Extracts
dc.subject.otherTranscriptional Activation
dc.subject.otherUp-Regulation
dc.subject.otherUterine Cervical Neoplasms
dc.subject.otherXanthones
dc.titleApoptosis induction associated with the ER stress response through up-regulation of JNK in HeLa cells by gambogic acid
dc.typeArticle
dspace.entity.typePublication
swu.datasource.scopushttps://www.scopus.com/inward/record.uri?eid=2-s2.0-84924338427&doi=10.1186%2fs12906-015-0544-4&partnerID=40&md5=5fb3af74c3fff642f92643a31834f11b

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