Project description:Stress granules (SGs) are highly dynamic cytoplasmic membrane-less organelles that assemble when cells are challenged by stress. At different stages of assembly, various RNA molecules are sorted into SGs where they play important roles in maintaining the structural stability of SGs and regulating gene expression. Despite recent efforts of fluorescence microscopy and biochemical fractionation analysis, there still lacks a complete description of the dynamic changes in the molecular inventory of SG components during different stages of assembly and disassembly. In this study, we applied a proximity-dependent RNA labeling method, CAP-seq, to comprehensively investigate the content of local transcriptome in SGs, in the context of live mammalian cells. CAP-seq captures 457 and 822 RNAs in arsenite- and sorbitol-induced SGs in HEK293T cells, respectively, revealing that SG enrichment is positively correlated with RNA length and AU content, but negatively correlated with translation efficiency. The high spatial specificity of CAP-seq dataset is validated by single-molecule FISH imaging. We further applied CAP-seq profile RNA components in microscopically invisible SG cores, both before stress and after recovery from stress, thus mapping the dynamic changes in SG-proximal transcriptome along the time course of granule assembly/disassembly processes. Our data portray a model of AU-rich and translationally repressed SG nanostructure that are memorized long after the removal of stress.

Project description:Non-membrane-bound compartments such as mRNA processing bodies (PBs) and stress granules (SGs) play important roles in the regulation of gene expression following environmental stresses. Here we perform RIP-seq to determine the RNA interactors of Dcp1 (PB marker) and Pbp1 (SG marker) before and after an appropriate glucose stress.

Project description:Stress granules (SGs) are stress induced RNA-protein assemblies formed from untranslating mRNPs. Mammalian SGs are non-uniform and contain “cores”, which are stable in lysates and heterogenous in protein composition. The interactions defining RNA recruitment into SGs, and whether the RNA composition varies between different cores remains unclear. Herein, we determine the SG transcriptome through purification of both PABPC1 and G3BP SG cores during both arsenite and sorbitol stress. We observe that similar RNAs are recruited to SGs independent of the protein used for core purification, suggesting individual RNA-binding proteins (RBPs) may play a limited role in defining the SG transcriptome. Analysis of the sorbitol-induced SG transcriptome reveals G3BP1/2 has little effect on RNAs recruited to SGs suggesting RNAs localize to SGs independent of individual RBPs. Taken together, we suggest that partitioning of RNAs to SGs is independent of at least some proteins, consistent with SGs forming through intermolecular RNA-RNA interactions.

Project description:Stress granules (SGs) are conserved reversible cytoplasmic condensates enriched with aggregation-prone proteins assembled in response to various stresses. Defects in disassembly have been associated with various neuro- and muscular degenerative diseases in humans. Plants appear to have efficient approaches to avoid the pathological conversion of SGs. However, how plants regulate SG dynamics is unclear. Here we show increase in either temperature or duration of heat stress reduces the molecular mobility of SG marker protein and suppresses SG clearance. Proteomics analysis and FRAP assays demonstrated 20S and 26S proteasomes as stable “core” components of SGs recruited early during the heat stress. Strikingly, while heat stress inhibits the activity of the overall proteasomes, it induces dramatic ubiquitylation of SG components and enhances the activities of SG-resident proteasomes, which degrade SG components even during the assembly phase. Their proteolytic activities enable the timely disassembly of SGs and secure the survival of plant cells during the recovery from heat stress.

Project description:• Stress granules (SGs) are evolutionary conserved aggregates of proteins and untranslated mRNAs formed in response to stress. Despite their importance for stress adaptation, no complete proteome composition has been reported for plant SGs. Herein, we addressed the existing gap. Importantly, we also provide evidence for metabolite sequestration within the SGs. • To isolate SGs we used Arabidopsis seedlings expressing GFP fusion of the SGs marker protein, Rbp47b, and an experimental protocol combining differential centrifugation with affinity purification. SGs isolates were analyzed using mass spectrometry-based proteomics and metabolomics. • A quarter of the identified proteins constituted known or predicted SG components. Intriguingly, the remaining proteins were enriched in key enzymes and regulators, such as cyclin dependent kinase A (CDKA), that mediate plant responses to stress. In addition to proteins, also nucleotides, amino acids and phospholipids accumulated in SGs. • Taken together, our results indicate (i) the presence of a pre-existing SG protein interaction network, (ii) an evolutionary conservation of the proteins involved in SG assembly and dynamics, (iii) an important role for SGs in moderation of stress responses by selective storage of proteins and metabolites.

Project description:N7-methylguanosine (m7G) modification, routinely occurring at the 5’ cap of mRNA or within tRNA and rRNA, also exists internally in mRNA. Although essential for mRNA translation as well as stress response, the “reader” protein for mRNA internal m7G modification is still unrevealed. Here, we reported that Quaking protein (QKI), especially QKI7, can selectively recognize the internal mRNA m7G decoration in the cytosol of various cell types. We identified over 1000 confident m7G-modified and QKI binding RNA targets with a conserved motif, “GANGAN (N=A/U/G)”. More strikingly, internal m7G reader QKI7 directly interacts with the SG core protein G3BP1 and can shuttle a subset of m7G-modified transcripts into SG mRNA pool under oxidative stress condition. Additionally, by sequestering mRNA within SGs, QKI7 modulates the translation efficiency of selected transcripts. Moreover, in line with the observation that doxorubicin triggers the assembly of SGs, QKI7 mediates the sensitivity of cancer cells to chemotherapy drug treatment.

Project description:N7-methylguanosine (m7G) modification, routinely occurring at the 5’ cap of mRNA or within tRNA and rRNA, also exists internally in mRNA. Although essential for mRNA translation as well as stress response, the “reader” protein for mRNA internal m7G modification is still unrevealed. Here, we reported that Quaking protein (QKI), especially QKI7, can selectively recognize the internal mRNA m7G decoration in the cytosol of various cell types. We identified over 1000 confident m7G-modified and QKI binding RNA targets with a conserved motif, “GANGAN (N=A/U/G)”. More strikingly, internal m7G reader QKI7 directly interacts with the SG core protein G3BP1 and can shuttle a subset of m7G-modified transcripts into SG mRNA pool under oxidative stress condition. Additionally, by sequestering mRNA within SGs, QKI7 modulates the translation efficiency of selected transcripts. Moreover, in line with the observation that doxorubicin triggers the assembly of SGs, QKI7 mediates the sensitivity of cancer cells to chemotherapy drug treatment.

Project description:N7-methylguanosine (m7G) modification, routinely occurring at the 5’ cap of mRNA or within tRNA and rRNA, also exists internally in mRNA. Although essential for mRNA translation as well as stress response, the “reader” protein for mRNA internal m7G modification is still unrevealed. Here, we reported that Quaking protein (QKI), especially QKI7, can selectively recognize the internal mRNA m7G decoration in the cytosol of various cell types. We identified over 1000 confident m7G-modified and QKI binding RNA targets with a conserved motif, “GANGAN (N=A/U/G)”. More strikingly, internal m7G reader QKI7 directly interacts with the SG core protein G3BP1 and can shuttle a subset of m7G-modified transcripts into SG mRNA pool under oxidative stress condition. Additionally, by sequestering mRNA within SGs, QKI7 modulates the translation efficiency of selected transcripts. Moreover, in line with the observation that doxorubicin triggers the assembly of SGs, QKI7 mediates the sensitivity of cancer cells to chemotherapy drug treatment.

Project description:N7-methylguanosine (m7G) modification, routinely occurring at the 5’ cap of mRNA or within tRNA and rRNA, also exists internally in mRNA. Although essential for mRNA translation as well as stress response, the “reader” protein for mRNA internal m7G modification is still unrevealed. Here, we reported that Quaking protein (QKI), especially QKI7, can selectively recognize the internal mRNA m7G decoration in the cytosol of various cell types. We identified over 1000 confident m7G-modified and QKI binding RNA targets with a conserved motif, “GANGAN (N=A/U/G)”. More strikingly, internal m7G reader QKI7 directly interacts with the SG core protein G3BP1 and can shuttle a subset of m7G-modified transcripts into SG mRNA pool under oxidative stress condition. Additionally, by sequestering mRNA within SGs, QKI7 modulates the translation efficiency of selected transcripts. Moreover, in line with the observation that doxorubicin triggers the assembly of SGs, QKI7 mediates the sensitivity of cancer cells to chemotherapy drug treatment.

Project description:N7-methylguanosine (m7G) modification, routinely occurring at the 5’ cap of mRNA or within tRNA and rRNA, also exists internally in mRNA. Although essential for mRNA translation as well as stress response, the “reader” protein for mRNA internal m7G modification is still unrevealed. Here, we reported that Quaking protein (QKI), especially QKI7, can selectively recognize the internal mRNA m7G decoration in the cytosol of various cell types. We identified over 1000 confident m7G-modified and QKI binding RNA targets with a conserved motif, “GANGAN (N=A/U/G)”. More strikingly, internal m7G reader QKI7 directly interacts with the SG core protein G3BP1 and can shuttle a subset of m7G-modified transcripts into SG mRNA pool under oxidative stress condition. Additionally, by sequestering mRNA within SGs, QKI7 modulates the translation efficiency of selected transcripts. Moreover, in line with the observation that doxorubicin triggers the assembly of SGs, QKI7 mediates the sensitivity of cancer cells to chemotherapy drug treatment.