SAT-446 Transcriptome Comparison of a Natural T3 Regulated Process and a Treatment with T3

Abstract

Thyroid hormones (TH) act mainly on the expression of the genome. It is well accepted that differential gene expression following treatment with TH recapitulates the expression profiles taking place during natural processes induced by these hormones. Although both processes seem to correlate at the scale of a few target genes, this hasn’t been addressed in a systematic manner. Our objectives were first to compare transcriptome variations after TH treatment with transcriptome variations during a TH controlled natural process and second to evaluate the proportion of the direct TH-response. The measurement of gene expression at genome scale (transcriptome) is obtained by sequencing all the messenger RNAs (RNA-seq). Direct response was sorted out by linking the transcription start sites of target genes using RNA-PET analysis with TR binding sites mapping using chromatin interaction analysis by paired-end tag sequencing (ChIA-PET). Indeed, ChIA-PET not only allow to map TR binding sites but also the physical interactions between them and transcription start sites of regulated genes. Our model is one of the striking developmental processes orchestrated by TH: amphibian metamorphosis. Tadpole transformation is marked by dramatic changes including de novo morphogenesis (limb), tissue remodelling (brain, intestine...) and organ resorption through apoptosis (tail). These changes involve cascades of gene regulation initiated by TH and their receptors. Because metamorphosis has close and interesting parallels with the perinatal period in mammals (including human), metamorphosis is thus an attractive model to analyze in a physiological context, the functions and mechanisms of action of TH. Here, we have focused on one Xenopus tropicalis organs, the tail fin skin which will disappear through cell death. We have compared natural metamorphosis with 24h of 10nM triiodothyronine (T3) treatment. We were able to observe several differences between T3 treatment and natural development. First, the genes regulated by T3 only correspond to a proportion of genes differentially expressed during metamorphosis. Second, T3-response genes start to be regulated well before tail regression (several days). Finally, T3-direct target genes represent a few percent of all the genes differentially expressed during tail regression. In conclusion, the comparison of transcriptomes of natural and induced metamorphosis allow us to reach a more precise understanding of TH action