Project description:Cytokine release syndrome (CRS) is a potentially life-threatening inflammatory condition. However, the defining features that distinguish it from self-resolving inflammation remain poorly understood. In this study, we identified monocyte/macrophage hyper-translation as a hallmark of CRS pathogenesis in patient samples. To uncover the molecular drivers of this phenomenon, a CRISPR screen followed by genetic validation pinpointed BCAP as a critical regulator of hyper-translation. Mechanistically, BCAP activated the RSK-EIF4B axis, fueling hyperactive translation in macrophages. Genetic ablation of RSK attenuated CRS-associated inflammation, and pharmacological inhibition of RSK alleviated CRS symptoms in a humanized mouse model. These findings establish hyper-translation as a key pathogenic feature of CRS and highlight protein translation as a druggable pathway, opening venues for therapeutic interventions of CRS and other inflammatory diseases.

Project description:Cytokine release syndrome (CRS) is a potentially life-threatening inflammatory condition. However, the defining features that distinguish it from self-resolving inflammation remain poorly understood. In this study, we identified monocyte/macrophage hyper-translation as a hallmark of CRS pathogenesis in patient samples. To uncover the molecular drivers of this phenomenon, a CRISPR screen followed by genetic validation pinpointed BCAP as a critical regulator of hyper-translation. Mechanistically, BCAP activated the RSK-EIF4B axis, fueling hyperactive translation in macrophages. Genetic ablation of RSK attenuated CRS-associated inflammation, and pharmacological inhibition of RSK alleviated CRS symptoms in a humanized mouse model. These findings establish hyper-translation as a key pathogenic feature of CRS and highlight protein translation as a druggable pathway, opening venues for therapeutic interventions of CRS and other inflammatory diseases.

Project description:Cytokine release syndrome (CRS) is a potentially life-threatening inflammatory condition. However, the defining features that distinguish it from self-resolving inflammation remain poorly understood. In this study, we identified monocyte/macrophage hyper-translation as a hallmark of CRS pathogenesis in patient samples. To uncover the molecular drivers of this phenomenon, a CRISPR screen followed by genetic validation pinpointed BCAP as a critical regulator of hyper-translation. Mechanistically, BCAP activated the RSK-EIF4B axis, fueling hyperactive translation in macrophages. Genetic ablation of RSK attenuated CRS-associated inflammation, and pharmacological inhibition of RSK alleviated CRS symptoms in a humanized mouse model. These findings establish hyper-translation as a key pathogenic feature of CRS and highlight protein translation as a druggable pathway, opening venues for therapeutic interventions of CRS and other inflammatory diseases.

Project description:Cytokine release syndrome (CRS) is a potentially life-threatening inflammatory condition. However, the defining features that distinguish it from self-resolving inflammation remain poorly understood. In this study, we identified monocyte/macrophage hyper-translation as a hallmark of CRS pathogenesis in patient samples. To uncover the molecular drivers of this phenomenon, a CRISPR screen followed by genetic validation pinpointed BCAP as a critical regulator of hyper-translation. Mechanistically, BCAP activated the RSK-EIF4B axis, fueling hyperactive translation in macrophages. Genetic ablation of RSK attenuated CRS-associated inflammation, and pharmacological inhibition of RSK alleviated CRS symptoms in a humanized mouse model. These findings establish hyper-translation as a key pathogenic feature of CRS and highlight protein translation as a druggable pathway, opening venues for therapeutic interventions of CRS and other inflammatory diseases.

Project description:Cytokine release syndrome (CRS) is a potentially life-threatening inflammatory condition. However, the defining features that distinguish it from self-resolving inflammation remain poorly understood. In this study, we identified monocyte/macrophage hyper-translation as a hallmark of CRS pathogenesis in patient samples. To uncover the molecular drivers of this phenomenon, a CRISPR screen followed by genetic validation pinpointed BCAP as a critical regulator of hyper-translation. Mechanistically, BCAP activated the RSK-EIF4B axis, fueling hyperactive translation in macrophages. Genetic ablation of RSK attenuated CRS-associated inflammation, and pharmacological inhibition of RSK alleviated CRS symptoms in a humanized mouse model. These findings establish hyper-translation as a key pathogenic feature of CRS and highlight protein translation as a druggable pathway, opening venues for therapeutic interventions of CRS and other inflammatory diseases.

Project description:The p90 ribosomal S6 kinase (RSK) family, downstream targets of Ras/ERK signaling, encompass four human isoforms (RSK1-4). Glioblastoma (GBM) predominantly expresses RSK1 and RSK2. Notably, RSK1 is markedly upregulated in a subset of GBMs associated with dismal prognosis and immune infiltration, whereas RSK2 expression remains consistent across cases. We verified that GBM-derived cell lines recapitulate RSK isoform expression profiles and estimated their stoichiometry. Through the generation of RSK1 and RSK2 knockout (RSK1KO and RSK2KO) as well as double knockout (DKO) GBM cells, we investigated isoform-specific functions of RSK. Surprisingly, contrary to conventional belief, we found that mTORC1 is not activated by RSK isoforms. Instead, eIF4B phosphorylation at S422 was RSK-dependent rather than mTORC1/S6K-dependent, with RSK1 exerting a more pronounced effect. Intriguingly, RSK1 and RSK2 displayed differential effects on translation, with RSK1 maintaining translation of specific mRNAs under conditions of reduced overall translation due to mTORC1 inhibition, unlike RSK2. Finally, we verified that while the translatome of RSK1KO cells show a downregulation of mRNAs affecting cell cycle, DNA replication and repair, RSK2 depletion impacted mitochondrial and respiratory genes. Notably, DKO cells exhibited compounded phenotypes, underscoring the existence of isoform-specific gene regulation programs orchestrated by RSK. Collectively, our findings offer mechanistic insights crucial for unraveling the role of RSK1 in GBMs.

Project description:Inflammatory responses rapidly detect pathogen invasion and mount a regulated reaction. However, dysregulated anti-pathogen immune responses can provoke life-threatening inflammatory pathologies collectively known as cytokine release syndrome (CRS), exemplified by key clinical phenotypes unearthed during the SARS-Cov-2 pandemic. The underlying pathophysiology of CRS remains elusive. We found that FLIP, a protein that controls caspase-8 death pathways, was highly expressed in myeloid cells of COVID-19 lungs. FLIP controlled CRS by fueling a STAT3-dependent inflammatory program. Indeed, constitutive expression of a viral FLIP homologue in myeloid cells triggered a STAT3-linked, progressive and fatal inflammatory syndrome in mice, characterized by elevated cytokine output, lymphopenia, lung injury and multiple organ dysfunctions that mimicked human CRS. As STAT3-targeting approaches relieved inflammation, immune disorders, and organ failures in these mice, targeted intervention towards this pathway could suppress the lethal CRS inflammatory state.

Project description:DEAD-box RNA helicases eIF4A and Ded1 promote translation by resolving mRNA secondary structures that impede preinitiation complex (PIC) attachment to mRNA or scanning. eIF4B is a cofactor for eIF4A but might also function independently of eIF4A. Ribosome profiling of mutants lacking eIF4B or with impaired eIF4A or Ded1 activity revealed that eliminating eIF4B reduces the relative translational efficiencies of many more genes than does inactivation of eIF4A, despite comparable reductions in bulk translation, and few genes display unusually strong requirements for both factors. However, either eliminating eIF4B or inactivating eIF4A preferentially impacts mRNAs with longer, more structured 5’UTRs. These findings reveal an eIF4A-independent role for eIF4B in addition to its function as eIF4A cofactor in promoting PIC attachment or scanning on structured mRNAs. eIF4B, eIF4A, and Ded1 mutations also preferentially impair translation of longer mRNAs in a fashion mitigated by the ability to form closed-loop mRNPs via eIF4F-Pab1 association, suggesting cooperation between closed-loop assembly and eIF4B/helicase functions. Remarkably, depleting eIF4G, the scaffold subunit of eIF4F, preferentially impacts short mRNAs with strong closed-loop potential and unstructured 5’UTRs, exactly the opposite features associated with hyperdependence on the eIF4B/helicases. We propose that short, highly efficient mRNAs preferentially depend on the stimulatory effects of eIF4G-dependent closed-loop assembly.

Project description:Chronic rhinosinusitis (CRS) is a heterogeneous disease characterized by local inflammation of the upper airways which persists for at least 12 weeks. CRS is one of the most common chronic diseases in adults in the United States, affecting over 30 million Americans. CRS is frequently divided into 2 types: CRS with nasal polyps (CRSwNP) and CRS without nasal polyps (CRSsNP). Histologic studies have demonstrated significant tissue eosinophilia in CRSwNP. T cells in the mucosa are elevated in both forms of CRS and are skewed towards Th2 cytokine expression in CRSwNP. However pathogenic role of CRS has not been fully explored. To screen for pathogenic factors in CRS, we performed a microarray study. We collected uncinate tissues (UT) from 6 subjects with CRSsNP, 6 subjects with CRSwNP and 6 control subjects and nasal polyp (NP) tissues from 6 subjects with CRSwNP and then evaluated gene expression profiles using Affymetrix Human Genome U133 plus 2.0 array. We collected UT from control subjects and pathients with CRSsNP and CRSwNP, and nasal polyp tissues from patients with CRSwNP. Gene expression profiles were evaluated using Human Genome U133 plus 2.0 array (Affymetrix).

Project description:The yeast eukaryotic initiation factor 4B binds the 40S subunit in translation preinitiation complexes (PICs) and promotes mRNA binding. Here we have compared the effects of disrupting eIF4B RNA- and ribosome-binding domains under ~1400 growth conditions. The RNA-binding RRM was dispensable for stress responses, but ribosome binding stimulated by the NTD promoted growth in response to a number of stressors through changes in translation. In particular, the NTD confers a strong growth advantage in the presence of the denaturing reagent, urea, and a number of osmolytes that require robust cellular integrity for survival. Ribosome profiling of cells with and without the NTD of eIF4B reveals changes in translation of mRNAs containing longer than average and highly structured 5-prime untranslated regions both normally, and in response to urea exposure. Because these changes require 40S binding, our results suggest eIF4B regulates mRNA recruitment as a part of the scanning PIC, rather than by activating isolated mRNPs prior to ribosome binding. This analysis indicates the cellular response to urea in yeast includes a translational component, driven by increased translation of mRNAs encoding proteins associated with the cellular periphery, and highlights the importance of the general translation factor eIF4B in adapting to external conditions.