Project description:We determined the enrichment of mRNA in stress granules in WT and NAT10 KO cells to assess the impact of RNA acetylation on stress granule mRNA localization.

Project description:Stress granules are mRNA-protein assemblies formed on nontranslating mRNAs. Stress granules are important in the stress response, related to neuronal mRNP granules, and aberrant stress granules contribute to some degenerative diseases. By RNA-Seq and single molecule FISH, we describe the stress granule transcriptome in both yeast and mammalian cells. This reveals that while essentially every mRNA, and some ncRNAs, can be targeted to stress granules, the efficiency of targeting can vary from <1% to 73%. mRNA accumulation in stress granules is increased by longer coding regions, poor translatability, and correlates with some RNA binding proteins. Standardizing the RNA-Seq analysis by single molecule FISH allows a quantitative description of the general and stress gra­nule transcriptome. Approximately 15% of the bulk mRNA molecules accumulate in stress granules suggesting their effect will be limited primarily to subsets of mRNAs highly accumulating in stress granules

Project description:Cell division ensures that both genetic information and non-genetic contents are inherited by daughter cells. Whereas considerable detail has been learned about the processing of intact or damaged DNA during the cell cycle (Branzei & Foiani, 2008; Klaasen et al., 2022),(Bakhoum & Cantley, 2018),(Hustedt & Durocher, 2016), how daughter cells deal with other forms of inherited damage is unknown. Here we identified a special kind of cytoplasmic granules responsible for the compartmentalisation of parental RNA damage. We found that ultraviolet (UV)-induced RNA, but not DNA, damage triggered assembly of this unique type of granules characterized by the presence of RNA helicase DHX9. By developing a novel methodology, FANCI, we discovered that DHX9 granules are enriched in damaged intron RNA and pre-mRNA-binding proteins, which is in contrast to other classical stress granules (SGs) that are composed of mature mRNA. Intron damage impeded proper splicing and intron decay, and induced generation of circRNA and dsRNA in the granules. Moreover, we showed that intron damage induced DHX9 granules assembled specifically in postmitotic daughter cells and triggered a cellular dsRNA immune response. Condensation with dsRNA is crucial for DHX9 localization to the granules and the modulation of dsRNA in these granules by DHX9 was crucial for daughter cell survival. Our observations revealed that DHX9 granules constitute a dedicated non-membrane-bound cytoplasmic compartment that protects daughter cells from parental damaged RNA.

Project description:Stress granules are small RNA-protein granules that modify the translational landscape during cellular stress to promote survival. The RhoGTPase RhoA is implicated in the formation of RNA stress granules. Our data demonstrate that the cytokinetic proteins ECT2 and AurkB are localized to stress granules in human astrocytoma cells. AurkB and its downstream target histone-3 are phosphorylated during arsenite-induced stress. Chemical (AZD1152-HQPA) and siRNA inhibition of AurkB results in fewer and smaller stress granules when analyzed utilizing high throughput fluorescent based cellomics assays. RNA immunoprecipitation with the known stress granule aggregates TIAR and G3BP1 was performed on astrocytoma cells and subsequent analysis revealed that astrocytoma stress granules harbour unique mRNAs for various cellular pathways including cellular migration, metabolism, translation and transcriptional regulation. Human astrocytoma cell stress granules contain mRNA that are known to be involved in glioma signaling and the mTOR pathway. These data provide evidence that RNA stress granules are a novel form of epigenetic regulation in astrocytoma cells, which may be targetable by chemical inhibitors and enhance astrocytoma susceptiblity to conventional therapy such as radiation and chemotherapy. Astrocytoma cells were either untreated or treated with arsenite to induce stress granule formation and RNA immunoprecipitates were analyzed by exon array analysis. RNA species that were enriched in TIAR RIPs and G3BP1 RIPS, respectively were compared to compared to TIAR and G3BP1 RIPs from untreated cells and input controls. Ingenuity pathway analysis was performed on the stress granule enriched mRNAs from the TIAR and G3BP1 RIPs to identify significant functional biology networks.

Project description:RNA partitioning into stress granules is independent of G3BP

Project description:Stress granules are small RNA-protein granules that modify the translational landscape during cellular stress to promote survival. The RhoGTPase RhoA is implicated in the formation of RNA stress granules. Our data demonstrate that the cytokinetic proteins ECT2 and AurkB are localized to stress granules in human astrocytoma cells. AurkB and its downstream target histone-3 are phosphorylated during arsenite-induced stress. Chemical (AZD1152-HQPA) and siRNA inhibition of AurkB results in fewer and smaller stress granules when analyzed utilizing high throughput fluorescent based cellomics assays. RNA immunoprecipitation with the known stress granule aggregates TIAR and G3BP1 was performed on astrocytoma cells and subsequent analysis revealed that astrocytoma stress granules harbour unique mRNAs for various cellular pathways including cellular migration, metabolism, translation and transcriptional regulation. Human astrocytoma cell stress granules contain mRNA that are known to be involved in glioma signaling and the mTOR pathway. These data provide evidence that RNA stress granules are a novel form of epigenetic regulation in astrocytoma cells, which may be targetable by chemical inhibitors and enhance astrocytoma susceptiblity to conventional therapy such as radiation and chemotherapy.

Project description:Stress granules are dynamic non-membrane bound organelles made up of untranslating messenger ribonucleoproteins (mRNPs) that form when cells integrate stressful environmental cues resulting in stalled translation initiation complexes. Although stress granules dramatically alter mRNA and protein localization, understanding these complexes has proven to be challenging through conventional imaging, purification, and crosslinking approaches. We therefore developed an RNA proximity labeling technique, APEX-Seq, which uses the ascorbate peroxidase APEX2 to probe the spatial organization of the transcriptome. We show that APEX-Seq can resolve the localization of RNAs within the cell and determine their enrichment or depletion near key RNA-binding proteins. Matching both the spatial transcriptome using APEX-seq, and the spatial proteome using APEX-mass spectrometry (APEX-MS) provide new insights into the organization of translation initiation complexes on active mRNAs, as well as revealing unanticipated complexity in stress granule contents, and provides a powerful approach to explore the spatial environment of macromolecules.

Project description:The eukaryotic cytosol contains multiple RNP granules including P-bodies and stress granules. Three different methods have been used to describe the transcriptome of stress granules or P-bodies, but how these methods compare, and how RNA partitioning occurs between P-bodies and stress granules has not been addressed. Herein, we compare the analysis of the stress granule transcriptome based on differential centrifugation, with and without subsequent stress granule immunopurification. We find that while differential centrifugation alone gives a first approximation of the stress granule transcriptome, this methodology contains non-specific transcripts that play a confounding role in the interpretation of results. We also immunopurify and compare the RNAs in stress granules and P-bodies under arsenite stress and compare those results to the P-body transcriptome described under non-stress conditions. We find that the P-body transcriptome is dominated by poorly translated mRNAs under non-stress conditions, but during arsenite stress, when translation is globally repressed, the P-body transcriptome is very similar to the stress granule transcriptome. This suggests that translation is a dominant factor in targeting mRNAs into both P-bodies and stress granules, and during stress, when most mRNAs are untranslated, the composition of P- bodies reflects this broader translation repression.

Project description:In Arabidopsis thaliana, ARGONAUTE1 (AGO1) plays a central role in microRNA (miRNA) and small interfering RNA (siRNA)-mediated silencing. Nuclear AGO1 is loaded with miRNAs and exported to the cytosol where it associates to the rough ER to conduct miRNA-mediated translational repression, mRNA cleavage and biogenesis of phased siRNAs. These latter, as well as other cytosolic siRNAs, are loaded into cytosolic AGO1, but in which compartment this happens is not known. Moreover, the effect of stress on AGO1 localization is still unclear. Here, we show that heat stress (HS) promotes AGO1 protein accumulation, which co-localizes with components of the siRNA bodies and of stress granules (SGs). AGO1 does not need SGS3, a key component of siRNA bodies, to efficiently form condensates during HS. Instead, we found that the still poorly characterized N-terminal Poly-Q domain of AGO1, which contains a prion-like domain, is sufficient to undergo phase separation. Moreover, an exposure of 1 hour to HS only moderately affected AGO1 loading by miRNAs and target cleavage, suggesting that its localization in condensates protects AGO1 rather than promoting its activity in reprograming gene expression during stress. Collectively, our work shed new light on the impact of high temperatures on the main effector of RNA silencing in plants.

Project description:In Arabidopsis thaliana, ARGONAUTE1 (AGO1) plays a central role in microRNA (miRNA) and small interfering RNA (siRNA)-mediated silencing. Nuclear AGO1 is loaded with miRNAs and exported to the cytosol where it associates to the rough ER to conduct miRNA-mediated translational repression, mRNA cleavage and biogenesis of phased siRNAs. These latter, as well as other cytosolic siRNAs, are loaded into cytosolic AGO1, but in which compartment this happens is not known. Moreover, the effect of stress on AGO1 localization is still unclear. Here, we show that heat stress (HS) promotes AGO1 protein accumulation, which co-localizes with components of the siRNA bodies and of stress granules (SGs). AGO1 does not need SGS3, a key component of siRNA bodies, to efficiently form condensates during HS. Instead, we found that the still poorly characterized N-terminal Poly-Q domain of AGO1, which contains a prion-like domain, is sufficient to undergo phase separation. Moreover, an exposure of 1 hour to HS only moderately affected AGO1 loading by miRNAs and target cleavage, suggesting that its localization in condensates protects AGO1 rather than promoting its activity in reprograming gene expression during stress. Collectively, our work shed new light on the impact of high temperatures on the main effector of RNA silencing in plants.