Project description: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.

Project description: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.

Project description: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.

Project description: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.

Project description: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.

Project description:Transcriptional adaptation (TA) is a cellular process whereby mRNA-destabilizing mutations lead to the transcriptional upregulation of so-called adapting genes. The nature of the TA-triggering factor(s) remains unclear. Here, we first generated Cas9-induced mutations in mouse Actg1, including an mRNA-destabilizing allele and an RNA-less allele. We find in the Actg1 mRNA-destabilizing allele, higher levels of Actg2 mRNA as well as increased chromatin accessibility at the Actg2 locus compared with wild-type and the RNA-less allele. Notably, Cas13d experiments show that Actg1 mRNA cleavage, but not Actg1 pre-mRNA cleavage, also triggers Actg2 upregulation; however, this upregulation is not associated with increased chromatin accessibility at the Actg2 locus. Furthermore, time course experiments show that increased Actg2 expression persists even after Actg1 mRNA degradation by Cas13d ceases. Together, our data highlight the importance of cytoplasmic mRNA degradation as a trigger for the TA response and suggest that chromatin remodeling is not necessary for TA.

Project description:Transcriptional adaptation (TA) is a cellular process whereby mRNA-destabilizing mutations lead to the transcriptional upregulation of so-called adapting genes. The nature of the TA-triggering factor(s) remains unclear. Here, we first generated Cas9-induced mutations in mouse Actg1, including an mRNA-destabilizing allele and an RNA-less allele. We find in the Actg1 mRNA-destabilizing allele, higher levels of Actg2 mRNA as well as increased chromatin accessibility at the Actg2 locus compared with wild-type and the RNA-less allele. Notably, Cas13d experiments show that Actg1 mRNA cleavage, but not Actg1 pre-mRNA cleavage, also triggers Actg2 upregulation; however, this upregulation is not associated with increased chromatin accessibility at the Actg2 locus. Furthermore, time course experiments show that increased Actg2 expression persists even after Actg1 mRNA degradation by Cas13d ceases. Together, our data highlight the importance of cytoplasmic mRNA degradation as a trigger for the TA response and suggest that chromatin remodeling is not necessary for TA.

Project description:Transcriptional adaptation (TA) is a cellular process whereby mRNA-destabilizing mutations lead to the transcriptional upregulation of so-called adapting genes. The nature of the TA-triggering factor(s) remains unclear, namely whether an mRNA-borne premature termination codon (PTC) or the subsequent mRNA degradation process, and/or its products, elicits TA. Here, we first established two perturbations leading to mRNA destabilization for mouse Actg1: a Cas9-induced mutation that leads to a PTC, and Cas13d-mediated mRNA cleavage. We find that both perturbations are effective in degrading Actg1 mRNA and upregulating Actg2. Notably, increased chromatin accessibility at the Actg2 locus was observed only in the Cas9-induced mutant allele but not in the Cas13d-targeted cells, suggesting that chromatin remodeling is not required for Actg2 upregulation. We further show that ribozyme-mediated Actg1 pre-mRNA cleavage also leads to a robust upregulation of Actg2. Together, these data highlight the critical role of RNA destabilization events as a trigger for TA.

Project description:mRNA decay machineries play important roles in various biological events. Among them, Cnot deadenylase complex has a critical function to trigger mRNA decay. To understand roles of the complex in liver development, we compare RNA expression between control and Cnot complex-deficient liver.

Project description:XRN 5′-3′ exoribonucleases play crucial roles in the control of RNA processing, quality, and quantity in eukaryotes. Although genome-wide profiling of RNA decay fragments is now feasible, how XRNs shape the plant mRNA degradome remains elusive. Here, we profiled and analyzed the RNA degradomes of the Arabidopsis wild type and mutants with defects in XRN activity. Deficiency of nuclear XRN3 or cytoplasmic XRN4 but not nuclear XRN2 activity largely altered Arabidopsis mRNA decay profiles. In addition to the primary XRN4 substrates derived from decapping and microRNA-directed slicing, terminating ribosome- and exon junction complex-protected fragments produced from XRN4-mediated cytoplasmic decay also represent the most abundant decay intermediates of Arabidopsis mRNAs. Short excised linear introns and cleaved pre-mRNA fragments downstream of polyadenylation sites were polyadenylated and stabilized in the xrn3 mutant, demonstrating the function of XRN3 in the removal of cleavage remnants from pre-mRNA processing. Further analysis of stabilized XRN3 substrates confirmed that polyadenylation cleavage frequently occurs after an adenosine. An increase in decay intermediates with 5′ ends upstream of a consensus motif in the xrn4 mutant suggests an endonucleolytic cleavage mechanism targeting the 3′ untranslated region of many Arabidopsis mRNAs. However, analysis of decay fragments stabilized in the xrn4 mutant indicated that, except for microRNA-directed slicing, endonucleolytic cleavage events in the coding sequence might rarely result in major decay intermediates. Together, the results of this study reveal major substrates and products of nuclear and cytoplasmic XRNs along Arabidopsis transcripts and provide a basis for precise interpretation of RNA degradome data.