iTAG-RNA Isolates Cell-Specific Transcriptional Responses to Environmental Stimuli and Identifies an RNA-Based Endocrine Axis

Biofluids contain various circulating cell-free RNAs (ccfRNAs). The composition of these ccfRNAs varies among biofluids. They constitute tantalizing biomarker candidates for several pathologies and have been demonstrated to be mediators of cellular communication. Little is known about their function...

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Published in:Cell reports (Cambridge) 2020-03, Vol.30 (9), p.3183-3194.e4
Main Authors: Darr, Jonatan, Tomar, Archana, Lassi, Maximilian, Gerlini, Raffaele, Berti, Lucia, Hering, Annette, Scheid, Fabienne, Hrabě de Angelis, Martin, Witting, Michael, Teperino, Raffaele
Format: Article
Language:English
Subjects:
Adipose Tissue - metabolism
Animals
Cell-Free Nucleic Acids - blood
Cellular Reprogramming - genetics
Chemical Precipitation
Cytochrome P-450 CYP3A - metabolism
Deoxyuridine - analogs & derivatives
Deoxyuridine - chemistry
Deoxyuridine - metabolism
Diet, High-Fat
Endocrine System - metabolism
Environment
Hepatocytes - metabolism
Homeostasis
Lipid Metabolism - genetics
Liver - metabolism
Mass Spectrometry
Mice
Muscle, Skeletal - metabolism
Organ Specificity
Prodrugs - chemistry
Prodrugs - metabolism
Reproducibility of Results
RNA - blood
RNA - metabolism
RNA tagging, mouse genetics, circulating RNA, 5EU prodrug, epigenetics, RNA biomarker
Small Molecule Libraries - chemistry
Small Molecule Libraries - pharmacology
Staining and Labeling
Transcription, Genetic
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Summary:Biofluids contain various circulating cell-free RNAs (ccfRNAs). The composition of these ccfRNAs varies among biofluids. They constitute tantalizing biomarker candidates for several pathologies and have been demonstrated to be mediators of cellular communication. Little is known about their function in physiological and developmental settings, and most works are limited to in vitro studies. Here, we develop iTAG-RNA, a method for the unbiased tagging of RNA transcripts in mice in vivo. We use iTAG-RNA to isolate hepatocytes and kidney proximal epithelial cell-specific transcriptional responses to a dietary challenge without interfering with the tissue architecture and to identify multiple hepatocyte-secreted ccfRNAs in plasma. We also identify specific transfer of liver-derived ccfRNAs to adipose tissue and skeletal muscle, where they likely constitute a buffering system to maintain lipid homeostasis under acute high-fat-diet feeding. Our findings directly demonstrate in vivo transfer of RNAs between tissues and highlight its implications for endocrine signaling and homeostasis. [Display omitted] •iTAG-RNA allows unbiased in vivo targeted tagging of RNA•iTAG-RNA isolates cell-type-specific responses to diet from an intact tissue in vivo•iTAG-RNA identifies hepatocyte-secreted circulating cell-free RNAs•iTAG-RNA identifies RNA transfer from liver to adipose tissue and skeletal muscle RNAs populate biofluids and are potential biomarkers. Their physiological function is not completely understood due to a lack of technologies allowing unbiased transcriptional labeling and source-to-sink RNA tracking. Darr et al. develop iTAG-RNA for unbiased tagging of RNA in vivo and identify a diet-sensitive liver-to-adipose and muscle endocrine axis.
ISSN:2211-1247
2211-1247
DOI:10.1016/j.celrep.2020.02.020