Mechanisms linking cytoplasmic decay of translation-defective mRNA to transcriptional adaptation [RNA-seq]

Transcriptional adaptation (TA) is a genetic robustness mechanism through which mutant mRNA decay induces sequence-dependent upregulation of so-called adapting genes. How cytoplasmically generated mRNA fragments impact nuclear transcription remains poorly understood. Using genome-wide CRISPR screens, we uncover ILF3 as an RNA-binding protein connecting cytoplasmic mRNA decay and transcription during TA, and show it is required for a range of TA substrates. ILF3 is enriched at adapting genes' RNAs, and its artificial recruitment via dCas13 promotes gene expression. Using tiling oligonucleotide screens, we identify trigger RNA fragments that activate adapting genes when introduced into cells. Further functional dissection reveals critical role for homology between trigger and target sequences. These findings enhance our molecular understanding of TA and inform design of programmable oligonucleotides for gene expression augmentation. Overall design: MEFs trasnduced with either Actg1-NMD or ctrl(GFP-2A-RFP)-NMD lentivectors were treated with doxycyline for three days then total RNA was isolated