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Please use this identifier to cite or link to this item: https://doi.org/10.1371/journal.pone.0006958
DC FieldValue
dc.titleIntestinal microbiota regulate xenobiotic metabolism in the liver
dc.contributor.authorBjörkholm B.
dc.contributor.authorBok C.M.
dc.contributor.authorLundin A.
dc.contributor.authorRafter J.
dc.contributor.authorHibberd M.L.
dc.contributor.authorPettersson S.
dc.date.accessioned2019-11-07T08:16:31Z
dc.date.available2019-11-07T08:16:31Z
dc.date.issued2009
dc.identifier.citationBjörkholm B., Bok C.M., Lundin A., Rafter J., Hibberd M.L., Pettersson S. (2009). Intestinal microbiota regulate xenobiotic metabolism in the liver. PLoS ONE 4 (9) : e6958. ScholarBank@NUS Repository. https://doi.org/10.1371/journal.pone.0006958
dc.identifier.issn19326203
dc.identifier.urihttps://scholarbank.nus.edu.sg/handle/10635/161828
dc.description.abstractBackground: The liver is the central organ for xenobiotic metabolism (XM) and is regulated by nuclear receptors such as CAR and PXR, which control the metabolism of drugs. Here we report that gut microbiota influences liver gene expression and alters xenobiotic metabolism in animals exposed to barbiturates. Principal findings: By comparing hepatic gene expression on microarrays from germfree (GF) and conventionally-raised mice (SPF), we identified a cluster of 112 differentially expressed target genes predominantly connected to xenobiotic metabolism and pathways inhibiting RXR function. These findings were functionally validated by exposing GF and SPF mice to pentobarbital which confirmed that xenobiotic metabolism in GF mice is significantly more efficient (shorter time of anesthesia) when compared to the SPF group. Conclusion: Our data demonstrate that gut microbiota modulates hepatic gene expression and function by altering its xenobiotic response to drugs without direct contact with the liver. © 2009 Björkholm et al.
dc.rightsAttribution 4.0 International
dc.rights.urihttp://creativecommons.org/licenses/by/4.0/
dc.sourceUnpaywall 20191101
dc.subjectconstitutive androstane receptor
dc.subjectcytochrome P450
dc.subjectfarnesoid X receptor
dc.subjectpentobarbital
dc.subjectretinoid X receptor
dc.subjectbarbituric acid derivative
dc.subjectpentobarbital
dc.subjectxenobiotic agent
dc.subjectarticle
dc.subjectcircadian rhythm
dc.subjectcontrolled study
dc.subjectgene expression
dc.subjectgenetic regulation
dc.subjectintestine flora
dc.subjectliver
dc.subjectliver function
dc.subjectliver size
dc.subjectliver weight
dc.subjectmale
dc.subjectmicroarray analysis
dc.subjectmouse
dc.subjectnonhuman
dc.subjectxenobiotic metabolism
dc.subjectanimal
dc.subjectbiological model
dc.subjectcell nucleus
dc.subjectDNA microarray
dc.subjectgene expression profiling
dc.subjectgene expression regulation
dc.subjectintestine
dc.subjectmetabolism
dc.subjectmicrobiology
dc.subjectmultigene family
dc.subjecttime
dc.subjectAnimalia
dc.subjectMus
dc.subjectAnimals
dc.subjectBarbiturates
dc.subjectCell Nucleus
dc.subjectGene Expression Profiling
dc.subjectGene Expression Regulation
dc.subjectIntestines
dc.subjectLiver
dc.subjectMale
dc.subjectMice
dc.subjectModels, Biological
dc.subjectMultigene Family
dc.subjectOligonucleotide Array Sequence Analysis
dc.subjectPentobarbital
dc.subjectTime Factors
dc.subjectXenobiotics
dc.typeArticle
dc.contributor.departmentSAW SWEE HOCK SCHOOL OF PUBLIC HEALTH
dc.description.doi10.1371/journal.pone.0006958
dc.description.sourcetitlePLoS ONE
dc.description.volume4
dc.description.issue9
dc.description.pagee6958
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