Project description:The subcellular localization of mRNAs plays a pivotal role in biological processes, including cell migration1-6. For instance, β-actin mRNA and its associated RNA binding protein (RBP), ZBP1/IGF2BP1, are recruited to focal adhesions (FAs), to support localized β-actin synthesis, crucial for cell migration7-9. However, whether other mRNAs and RBPs also localize at FAs remains unclear. Here, we identify hundreds of mRNAs that are enriched at FAs (FA-mRNAs). FA-mRNAs share characteristics with stress granule (SG) mRNAs and are found in ribonucleoprotein (RNP) complexes with the SG RBP. Mechanistically, G3BP1 binds to FA proteins in an RNA-dependent manner, and its RNA-binding and dimerization domains, essential for G3BP1 to form RNPs in SG10, are required for FA localization and cell migration. We find that G3BP1 RNPs promote cell speed by enhancing FA protein mobility and FA size. These findings suggest a previously unappreciated role for G3BP1 RNPs in regulating FA function under non-stress conditions.

Project description:Cells limit energy-consuming mRNA translation during stress to maintain metabolic homeostasis. Sequestration of mRNAs by RNA binding proteins (RBPs) into stress granules (SGs) reduces translation, but it remains unclear whether SGs also function in partitioning of specific transcripts to polysomes (PSs) to guide selective translation and stress-adaptation in cancer. Transcripts enriched in PSs, defined by polysome fractionation and RNAseq, were compared with mRNAs complexed with the SG-nucleator protein, G3BP1, defined by spatially-restricted enzymatic tagging. Short-term oxidative stress profoundly altered mRNA translation by promoting selective enrichment of transcripts within SGs or PSs. G3BP1 participates in this compartmentalisation by sequestering transcripts in SGs. Under stress, G3BP1-bound transcripts are PS-depleted and encode proteins involved in mRNA translation, pro-apoptosis, and mitochondrial function. In contrast, specific PS-enriched transcripts disassociate from G3BP1 under stress to encode proteins involved in diverse cellular cytoprotective pathways. Therefore, G3BP1 partitioning guides selective translation to support stress adaptation and cell survival.

Project description:Proteomic analysis of murine stress granule and G3BP1 granulome in infected cells. BV2 GFP-G3BP1 cells were either treated with 0.1 mM arsenite for 1h to induce SG assembly or infected with MNV for 9h. G3BP1 granules were enriched by sequential centrifugation and purified by immunoprecipitation using antibodies to GFP (to trap GFP-G3BP1) or IgG (as a control) followed by pull down with Protein A-conjugated epoxy Dynabeads as previously described. To characterize the identity of G3BP1 partners within these, Mass Spectrometric analysis was performed.

Project description:Stress Granules (SG) formation is a cellular protection mechanism, constituting a storage for untranslated mRNAs and RNA-binding proteins (RBPs); however, these condensates can turn into pathological aggregates, related to the onset of neurodegenerative diseases like Amyotrophic Lateral Sclerosis (ALS). This transition towards cytotoxic inclusions is triggered by ALS-causative mutations in the RBP FUS, which lead to its cytoplasmic mis-localization and accumulation in SG. Here, we describe the SG transcriptome in a neural context and describe several features for RNA recruitment in SG. We demonstrate that SG dynamics and RNA content are strongly modified by the incorporation of mutant FUS, switching to a more unstructured, AU-rich SG transcriptome. Moreover, we show that mutant FUS, together with its protein interactors and their target RNAs, are responsible for the reshaping of the mutant SG transcriptome with alterations that can be linked to neurodegeneration. Therefore, our data give a comprehensive view of the molecular differences between physiological and pathological SG in ALS conditions, showing how FUS mutations impact the RNA and protein population of these condensates.

Project description:In order to identify sites of the SEC16A specifically phosphorylated by the Dual Specificity Kinase DYRK3, mCherry-SEC16A was transiently over expressed in HeLa cells together with GFP-DYRK3 or EGFP-C1 only

Project description:Mitochondrial calcium signaling plays a critical role in mitochondrial homeostasis during non-alcoholic steatohepatitis (NASH) progression. Here, we report Ras‐GTPase activating protein SH3 domain‐binding protein 1 (G3BP1), a core protein of stress granule (SG), significantly upregulated in NAFLD/NASH patients, mouse models and palmitic acid-stimulated hepatocytes. Hepatocyte-specific G3BP1 deficiency attenuates NASH in two dietary mouse models. SG and the mitochondrial import protein TOM70 collaboratively mediate the translocation of G3BP1 to the mitochondria. G3BP1 interacts and stabilizes mitochondrial calcium uptake 1 (MICU1) via inhibiting YME1L1-mediated degradation of MICU1, and also impedes MCU complex activity and assembly, leading to mitochondrial calcium overload. Moreover, metabolic stress suppresses TRIM25-mediated K63-ubiquitination of G3BP1 and subsequent SG disassembly. Pharmacological inhibition of G3BP1 impairs the G3BP1-MICU1 interaction and prevents mitochondrial homeostasis imbalance and NASH progression. Collectively, we uncover the significant role of mitochondrial G3BP1 in mitochondrial homeostasis and NASH progression, which provides a potential target for therapeutic interventions.

Project description:Mitochondrial calcium signaling plays a critical role in mitochondrial homeostasis during non-alcoholic steatohepatitis (NASH) progression. Here, we report Ras‐GTPase activating protein SH3 domain‐binding protein 1 (G3BP1), a core protein of stress granule (SG), significantly upregulated in NAFLD/NASH patients, mouse models and palmitic acid-stimulated hepatocytes. Hepatocyte-specific G3BP1 deficiency attenuates NASH in two dietary mouse models. SG and the mitochondrial import protein TOM70 collaboratively mediate the translocation of G3BP1 to the mitochondria. G3BP1 interacts and stabilizes mitochondrial calcium uptake 1 (MICU1) via inhibiting YME1L1-mediated degradation of MICU1, and also impedes MCU complex activity and assembly, leading to mitochondrial calcium overload. Moreover, metabolic stress suppresses TRIM25-mediated K63-ubiquitination of G3BP1 and subsequent SG disassembly. Pharmacological inhibition of G3BP1 impairs the G3BP1-MICU1 interaction and prevents mitochondrial homeostasis imbalance and NASH progression. Collectively, we uncover the significant role of mitochondrial G3BP1 in mitochondrial homeostasis and NASH progression, which provides a potential target for therapeutic interventions.

Project description:The SRC inhibitor PP2 can block CASK nucleus translocation in macrophage under H5N1 infection. Since PP2 is a general inhibitor for Src family kinases (SFKs), which includes nine members (Csk, Yes, Fyn, Fgr, Lck, Hck, Blk, Lyn, and Frk), we aimed to identify the specific member responsible for the nuclear translocation of CASK. First, we examined the expression of SFKs in macrophages (Csk, Fyn, Fgr, and Hck) following H5N1-IAV infection (Fig. 4A). This observation suggests that Hck is the most abundant SFK and may contribute to virus-induced nuclear translocation of CASK. To test this, we generated constitutively active forms of HCK: HCK△513-524 (deletion mutant) and HCK Y499F mutant (YF mutation) [24], then co-transfected them with an EGFP-CASK construct into 293T cells. Immunoprecipitation with anti-GFP mAb, followed by trypsin digestion and LC-MS/MS analysis, revealed that compared to the control group, the phospho/nonphospho ratio at residue Serine 395 (S395) of CASK increased approximately 10-fold (0.008 to 0.072 by HCK△513-524, 0.008 to 0.108 by HCK Y499F), while the other 8 potential phosphorylation sites did not show significant alterations (Table 1). To confirm the phosphorylation of S395 of CASK is required for nuclear translocation, we generated an EGFP-CASK S395A mutant (SA mutation) to prevent CASK phosphorylation. In the absence of HCK Y499F, both the wild type (CASK S395) and mutant (CASK S395A) remained in the cytosol (left two columns, Fig. 4B). In contrast, transfection of HCK Y499F (red color) induced the translocation of wild type CASK (green color) into the nucleus (3rd column from left, Fig. 4B), an effect not observed with the CASK S395A mutant (4th column from left, Fig. 4B). The percentage of nuclear GFP-CASK (60% and 90% in WT and 35% in S395A) resulting from the overexpression of wild type HCK and HCK Y499F is shown in Figure 4C. Thus, we concluded that activated HCK induces the phosphorylation of CASK at Ser395, facilitating its nuclear translocation.

Project description:We investigated design principles of DARPin-based bioPROTACs targeting the model substrate GS-eGFP (eGFP with an n-terminal tag, necessary for proteasomal unfolding). Using a highly active E3 ligase domain from CHIP and nine well-characterized DARPins, we evaluated their ability to induce proteasomal degradation. Seven of nine DARPin bioPROTACs successfully mediated catalytic degradation of GS-eGFP, with the binding epitope emerging as a key determinant of efficiency. LC-MS/MS analysis revealed that efficient degradation required ubiquitination at four specific lysine residues on eGFP. Notably, DP6-bioPROTAC promoted polyubiquitination, whereas DP9-bioPROTAC did not, likely due to differences in binding geometry. DP7-bioPROTAC appeared to hinder E2 enzyme access, further confirming the importance of structural orientation. Additionally, we observed that DARPins lacking an E3 domain can trigger non-catalytic degradation, potentially via recruitment of endogenous E3 ligases. Ubiquitination patterns of selected GS-eGFP complexes (DP1, DP9, and a lysine-free DP6 mutant) were also characterized by LC-MS/MS.

Project description:We previously identified the stimuli-responsive lncRNA CALA to impact endothelial cell function and identified G3BP1 as a main interaction partner of CALA in the cytoplasm of human umblical vein endothelial cells (HUVECs). To uncover the role of the lncRNA CALA in G3BP1-RNPs in the cytoplasm, we purified the G3BP1 interactome in control and CALA-silenced HUVECs via anti-G3BP1 immunoprecipitation followed by mass spectrometry. We thereby uncover the basal G3BP1 protein interactome in HUVECs and additionally identify lncRNA-dependent protein interactions of G3BP1 in the cytoplasm of HUVEC.