Cross-species transcriptomic analysis elucidates constitutive aryl hydrocarbon receptor activity

6533b823fe1ef96bd127ecaa

RESEARCH PRODUCT

Cross-species transcriptomic analysis elucidates constitutive aryl hydrocarbon receptor activity

Kathleen E. Houlahan Allan B. Okey Ivy D. Moffat Paul C. Boutros Christine P'ng Sanna Lensu Sanna Lensu Jere Lindén Stephenie D. Prokopec John D. Watson Trent T. Simmons Ren X. Sun Lauren C. Chong Raimo Pohjanvirta

subject

Male HEPATIC GENE-EXPRESSION 413 Veterinary science Medical and Health Sciences Transcriptome DIOXIN RECEPTOR Mice 0302 clinical medicine TCDD-induced toxicity Receptors Transcriptional regulation ABNORMAL LIVER DEVELOPMENT 2.1 Biological and endogenous factors Cluster Analysis Aetiology Receptor AH RECEPTOR IN-VIVO Aryl hydrocarbon receptor Genetics Regulation of gene expression 0303 health sciences Biological Sciences respiratory system Core-gene battery Aryl Hydrocarbon Organ Specificity 030220 oncology & carcinogenesis AHR endogenous ligands 2 3 7 8-TETRACHLORODIBENZO-P-DIOXIN TCDD Signal transduction Research Article Biotechnology Signal Transduction Protein Binding Bioinformatics 1.1 Normal biological development and functioning education RAT-LIVER Constitutive gene expression Biology MICE LACKING 03 medical and health sciences Species Specificity Underpinning research Information and Computing Sciences Genetics Animals 030304 developmental biology Aryl hydrocarbon receptor activity Gene Expression Profiling Computational Biology Aryl hydrocarbon receptor CELL-CYCLE CONTROL Rats respiratory tract diseases Gene expression profiling Receptors Aryl Hydrocarbon Gene Expression Regulation SUBCHRONIC EXPOSURE biology.protein Digestive Diseases Transcriptome

description

Background Research on the aryl hydrocarbon receptor (AHR) has largely focused on variations in toxic outcomes resulting from its activation by halogenated aromatic hydrocarbons. But the AHR also plays key roles in regulating pathways critical for development, and after decades of research the mechanisms underlying physiological regulation by the AHR remain poorly characterized. Previous studies identified several core genes that respond to xenobiotic AHR ligands across a broad range of species and tissues. However, only limited inferences have been made regarding its role in regulating constitutive gene activity, i.e. in the absence of exogenous ligands. To address this, we profiled transcriptomic variations between AHR-active and AHR-less-active animals in the absence of an exogenous agonist across five tissues, three of which came from rats (hypothalamus, white adipose and liver) and two of which came from mice (kidney and liver). Because AHR status alone has been shown sufficient to alter transcriptomic responses, we reason that by contrasting profiles amongst AHR-variant animals, we may elucidate effects of the AHR on constitutive mRNA abundances. Results We found significantly more overlap in constitutive mRNA abundances amongst tissues within the same species than from tissues between species and identified 13 genes (Agt, Car3, Creg1, Ctsc, E2f6, Enpp1, Gatm, Gstm4, Kcnj8, Me1, Pdk1, Slc35a3, and Sqrdl) that are affected by AHR-status in four of five tissues. One gene, Creg1, was significantly up-regulated in all AHR-less-active animals. We also find greater overlap between tissues at the pathway level than at the gene level, suggesting coherency to the AHR signalling response within these processes. Analysis of regulatory motifs suggests that the AHR mostly mediates transcriptional regulation via direct binding to response elements. Conclusions These findings, though preliminary, present a platform for further evaluating the role of the AHR in regulation of constitutive mRNA levels and physiologic function. Electronic supplementary material The online version of this article (doi:10.1186/1471-2164-15-1053) contains supplementary material, which is available to authorized users.

year	journal	country	edition	language
2014-12-01

http://urn.fi/URN:NBN:fi:jyu-201804202307