Project description:Membrane integrity at the endoplasmic reticulum (ER) is tightly regulated and its disturbance is implicated in metabolic diseases. Using an engineered sensor that activates the unfolded protein response (UPR) exclusively when normal ER membrane lipid composition is compromised, we identified pathways beyond lipid metabolism that are necessary to maintain ER integrity in yeast and in C. elegans. To systematically validate yeast mutants that disrupt ER membrane homeostasis, we identified a lipid bilayer stress (LBS) sensor in the UPR transducer protein Ire1, located at the interface of the amphipathic and transmembrane helices. Furthermore, transcriptome and chromatin immunoprecipitation (ChIP) analyses pinpoint the UPR as a broad-spectrum compensatory response wherein LBS and proteotoxic stress deploy divergent transcriptional UPR programs. Together, these findings reveal the UPR program as the sum of two independent stress responses, an insight that could be exploited for future therapeutic intervention.

Project description:The unfolded protein response (UPR) continually monitors the protein folding capacity of the endoplasmic reticulum (ER). In S. pombe, Ire1, an ER membrane-resident kinase/endoribonuclease, utilizes a mechanism of selective degradation of ER-targeted mRNAs (RIDD) to maintain ER homeostasis. Here, we used a genetic screen to identify factors critical to the Ire1-mediated UPR response in S. pombe and found several proteins, Dom34, Hbs1 and SkiX, previously implicated in ribosome rescue and the no-go-decay (NGD) pathway. Ribosome profiling in ER-stressed cells lacking these factors revealed that Ire1-mediated cleavage on ER-associated mRNAs results in ribosome stalling on the cleaved transcript and, ultimately in full mRNA degradation. The process engages mechanisms of precise, iterated cleavage of the mRNAs and ribosome rescue. This clear signature allowed us to discover hundreds of novel mRNA targets of Ire1. Our results reveal that the UPR in S. pombe executes RIDD in an intricate interplay between Ire1, translation, and the NGD surveillance pathway, and establish a critical role for NGD in maintaining ER homeostasis.

Project description:Stress pathways monitor intracellular systems and deploy a range of regulatory mechanisms in response to stress. One of the best-characterized pathways, the unfolded protein response (UPR), is responsible for maintaining endoplasmic reticulum (ER) homeostasis. The highly conserved Ire1 branch regulates hundreds of gene targets by activating a UPR specific transcription factor. To understand how the UPR manages ER stress, a novel genetic approach was applied to reveal how the system corrects disequilibria. The data show that UPR can address a wide range of dysfunctions that is otherwise lethal if not for its intervention. Transcriptional profiling of stress alleviated cells shows that the program can be modulated, not just in signal amplitude, but also through differential target gene expression depending on the stress. The breadth of the functions mitigated by the UPR further supports its role as a major mechanism maintaining systems robustness. Genes expression from early log phase of ALG5, LHS1, and SCJ1 knockout cell and untreated and DTT-treated WT cells. RNA was prepared from independent triplicate samples.

Project description:The ARV1-encoded protein mediates sterol transport from the endoplasmic reticulum (ER) to the plasma membrane. Yeast ARV1 mutants accumulate multiple lipids in the ER and are sensitive to pharmacological modulators of both sterol and sphingolipid metabolism. Using fluorescent and electron microscopy, we demonstrate sterol accumulation, subcellular membrane expansion, elevated lipid droplet formation and vacuolar fragmentation in ARV1 mutants. Motif-based regression analysis of ARV1 deletion transcription profiles indicates activation of Hac1p, an integral component of the UPR. Accordingly, we show constitutive splicing of HAC1 transcripts, induction of a UPR reporter and elevated expression of UPR targets in ARV1 mutants. IRE1, encoding the unfolded protein sensor in the ER lumen, exhibits a lethal genetic interaction with ARV1, indicating a viability requirement for the UPR in cells lacking ARV1. Surprisingly, ARV1 mutants expressing a variant of Ire1p defective in sensing unfolded proteins are viable. Moreover these strains also exhibit constitutive HAC1 splicing that interacts with DTT-mediated perturbation of protein folding. These data suggest a component of UPR induction in arv1? strains is distinct from protein misfolding. Decreased ARV1 expression in murine macrophages also results in UPR induction, particularly up-regulation of activating transcription factor-4, C/EBP homologous protein (CHOP) and apoptosis. Cholesterol loading or inhibition of cholesterol esterification further elevated CHOP expression in ARV1 knockdown cells. Thus, loss or down-regulation of ARV1 disturbs membrane and lipid homeostasis resulting in a disruption of ER integrity, one consequence of which is induction of the UPR. Yeast strains were grown to mid-logarithmic stage (A600=0.5-0.6) for RNA extraction and hybridization on Ye6100 or S98 Affymetrix gene chips. The control array (sample name C) was carried out in duplicate. The ARV1 mutant array (sample name A) was carried out in triplicate. Both ARV1 mutants Ye6100 arrays were compared to the same control Ye6100 array. Strains represent different isolates of the same genotype, mating type and genetic background (w303). Sturley lab collection (SCY) strains include SCY328 and SCY2004 for controls and SCY820 and SCY840 for ARV1 mutants.

Project description:The Unfolded Protein Response (UPR) is an adaptive pathway that restores cellular homeostasis after endoplasmic reticulum (ER) stress caused by an impairment of its protein folding capacity. The ER-resident kinase/ribonuclease Ire1 is the only UPR sensor that has been conserved during evolution from yeast to mammals; in these organisms, Ire1 transmits information from the ER to the nucleus trough the non-conventional splicing of Hac1 (yeast)/Xbp1 (metazoans) mRNA. We described the Dictyostelium discoideum ER-stress response and characterized its single bonafide Ire1 orthologue, IreA. We found that tunicamycin (TN) triggers a gene-expression program that increases the protein folding capacity of the ER and that alleviates ER protein load. Further, IreA resulted essential not only for cell-survival after TN-induced ER-stress, but also to accomplish about nearly 40% of the transcriptional changes induced upon a TN treatment. In addition, we described that autophagy is activated in Dictyostelium cells after a TN treatment and that autophagy-defective mutants exhibited increased sensitivity to this drug. The response of Dictyostelium cells to ER-stress involves the combined activation of an IreA-dependent gene expression program and the autophagy pathway.

Project description:Perturbation of tissue homeostasis accompanies a diversity of inflammatory pathologies and imposes metabolic constraints at the cellular level that elicit ER stress, protein misfolding, and cell death. In response to ER stress, cells initiate the unfolded protein response (UPR), which determines divergent cell fate decisions, either promoting recovery of ER proteostasis and cell survival or triggering programmed cell death. However, the mechanisms by which the UPR transitions from the adaptive to terminal state are not fully understood. To discover novel UPR pathway regulators that influence the outcome of cellular ER stress responses, we performed genome-scale genetic perturbations. Our genome-wide screens revealed that distinct sets of genes regulate UPR activity and maintenance of ER homeostasis. This expansive dataset provides a rich resource that can be leveraged to elucidate signaling crosstalk during ER stress and discover novel UPR regulators.

Project description:The unfolded protein response (UPR) aims to restore ER homeostasis under conditions of high protein folding load, a function primarily serving secretory cells. Additional, non-canonical UPR functions have recently been unraveled in immune cells. We addressed the function of the inositol-requiring-enzyme 1 (IRE1) signaling branch of the UPR in NK cells in homeostasis and microbial challenge. Cell-intrinsic compound deficiency (DKO) of IRE1 and its downstream transcription factor XBP1 in NKp46 + NK cells, did not affect basal NK cell homeostasis, or overall outcome of viral MCMV infection. However, mixed bone marrow chimeras revealed a competitive advantage in the proliferation of IRE1 sufficient Ly49H + NK cells after viral infection. CITE-Seq analysis confirmed strong induction of IRE1 early upon infection, concomitant with the activation of a canonical UPR signature. Therefore, we conclude that cell-intrinsic IRE1/XBP1 activation is required for NK cell proliferation early upon viral infection, as part of a canonical UPR response.

Project description:The unfolded protein response (UPR) aims to restore ER homeostasis under conditions of high protein folding load, a function primarily serving secretory cells. Additional, non-canonical UPR functions have recently been unraveled in immune cells. We addressed the function of the inositol-requiring-enzyme 1 (IRE1) signaling branch of the UPR in NK cells in homeostasis and microbial challenge. Cell-intrinsic compound deficiency (DKO) of IRE1 and its downstream transcription factor XBP1 in NKp46 + NK cells, did not affect basal NK cell homeostasis, or overall outcome of viral MCMV infection. However, mixed bone marrow chimeras revealed a competitive advantage in the proliferation of IRE1 sufficient Ly49H + NK cells after viral infection. CITE-Seq analysis confirmed strong induction of IRE1 early upon infection, concomitant with the activation of a canonical UPR signature. Therefore, we conclude that cell-intrinsic IRE1/XBP1 activation is required for NK cell proliferation early upon viral infection, as part of a canonical UPR response.

Project description:Disruptions of the endoplasmic reticulum (ER) that perturb protein folding cause ER stress and elicit an unfolded protein response (UPR) that involves translational and transcriptional changes in gene expression aimed at expanding the ER processing capacity and alleviating cellular injury. Three ER stress sensors PERK, ATF6, and IRE1 implement the UPR. PERK phosphorylation of eIF2 during ER stress represses protein synthesis, which prevents further influx of ER client proteins, along with preferential translation of ATF4, a transcription activator of the integrated stress response. In this study we show that the PERK/eIF2α~P/ATF4 pathway is required not only for translational control, but also activation of ATF6 and its target genes. The PERK pathway facilitates both the synthesis of ATF6 and trafficking of ATF6 from the ER to the Golgi for intramembrane proteolysis and activation of ATF6. As a consequence, liver-specific depletion of PERK significantly reduces both the translational and transcriptional phases of the UPR, leading to reduced protein chaperone expression, disruptions of lipid metabolism, and enhanced apoptosis. These findings show that the regulatory networks of the UPR are fully integrated, and helps explain the diverse pathologies associated with loss of PERK. 14 gene expression arrays, 3 WT control arrays; 3 lsPERK control arrays; 4 WT Treated arrays; 4 lsPERK treated arrays. Comparison of gene expression profiles for treated vs control in wildtype and knock-out.

Project description:ER stress and the unfolded protein response (UPR) involve extensive proteome remodeling in many cell compartments. However, a comprehensive analysis has been lagging due to technological limitations. Here we employ SILAC-based proteomics to quantify over 6,200 proteins at increasing concentrations of tunicamycin in HeLa cells. We further compare the effects of tunicamycin to those of thapsigargin and DTT, both activating the UPR through different mechanisms. The systematic description of the proteome-wide expression changes following proteostatic stress is a resource for the scientific community, which enables to discover novel players involved the pathophysiology of disorders linked to proteostasis. Here, we identified 38 proteins, not previously linked to the UPR, whose expression increases, of which 15 would likely remediate ER stress, and the remainder may contribute to pathological outcomes. Unexpectedly, we see few strongly downregulated proteins, despite expression of the pro-apoptotic transcription factor CHOP, suggesting that IRE1-dependent mRNA decay (RIDD) has a limited contribution to ER-stress mediated cell death in our system.