Xenobiotics and loss of cell adhesion drive distinct transcriptional outcomes by aryl hydrocarbon receptor signaling

Xenobiotics and loss of cell adhesion drive distinct transcriptional outcomes by aryl hydrocarbon receptor signaling

The aryl hydrocarbon receptor (AhR) is a signal-regulated transcription factor, which is canonically activated by the direct binding of xenobiotics. In addition, switching cells from adherent to suspension culture also activates the AhR, representing a nonxenobiotic, physiological activation of AhR...

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Bibliographic Details
Published in:Molecular pharmacology Vol. 82; no. 6; p. 1082
Main Authors: Hao, Nan, Lee, Kian Leong, Furness, Sebastian G B, Bosdotter, Cecilia, Poellinger, Lorenz, Whitelaw, Murray L
Format: Journal Article
Language:English
Published: United States 01-12-2012
Subjects:
Animals
Cell Adhesion - drug effects
Cell Adhesion - genetics
Cell Line
Chromatin Immunoprecipitation
DNA-Binding Proteins - genetics
DNA-Binding Proteins - metabolism
Gene Expression - drug effects
HEK293 Cells
Hepatocytes - drug effects
Hepatocytes - metabolism
Humans
LDL-Receptor Related Proteins - genetics
LDL-Receptor Related Proteins - metabolism
Ligands
Mice
Receptors, Aryl Hydrocarbon - genetics
Receptors, Aryl Hydrocarbon - metabolism
Signal Transduction - drug effects
Transcription, Genetic - drug effects
Transcriptional Activation - drug effects
Transcriptional Activation - genetics
Transcriptome - drug effects
Xenobiotics - pharmacology
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Summary:The aryl hydrocarbon receptor (AhR) is a signal-regulated transcription factor, which is canonically activated by the direct binding of xenobiotics. In addition, switching cells from adherent to suspension culture also activates the AhR, representing a nonxenobiotic, physiological activation of AhR signaling. Here, we show that the AhR is recruited to target gene enhancers in both ligand [isopropyl-2-(1,3-dithietane-2-ylidene)-2-[N-(4-methylthiazol-2-yl)carbamoyl]acetate (YH439)]-treated and suspension cells, suggesting a common mechanism of target gene induction between these two routes of AhR activation. However, gene expression profiles critically differ between xenobiotic- and suspension-activated AhR signaling. Por and Cldnd1 were regulated predominantly by ligand treatments, whereas, in contrast, ApoER2 and Ganc were regulated predominantly by the suspension condition. Classic xenobiotic-metabolizing AhR targets such as Cyp1a1, Cyp1b1, and Nqo1 were regulated by both ligand and suspension conditions. Temporal expression patterns of AhR target genes were also found to vary, with examples of transient activation, transient repression, or sustained alterations in expression. Furthermore, sequence analysis coupled with chromatin immunoprecipitation assays and reporter gene analysis identified a functional xenobiotic response element (XRE) in the intron 1 of the mouse Tiparp gene, which was also bound by hypoxia-inducible factor-1α during hypoxia and features a concatemer of four XRE cores (GCGTG). Our data suggest that this XRE concatemer site concurrently regulates the expression of both the Tiparp gene and its cis antisense noncoding RNA after ligand- or suspension-induced AhR activation. This work provides novel insights into how AhR signaling drives different transcriptional programs via the ligand versus suspension modes of activation.
ISSN:1521-0111
DOI:10.1124/mol.112.078873