Project description:One major component of cellular proteome resides in the endoplasmic reticulum (ER), the key organelle for protein biogenesis in the secretory pathway. Disruption of ER proteostasis leads to ER stress, which subsequently activates multiple adaptive stress response pathways, collectedly termed as the unfolded protein response (UPR). One UPR branch is mediated by IRE1(inositol-requiring enzyme 1). Activation of the IRE1 UPR branch generates a potent transcriptional factor: spliced X-box–binding protein-1 (XBP1s). Since activation of this UPR branch has been shown to be neuroprotective in brain ischemia/stroke, it is critical to identify the XBP1s-regulated genes in neurons in vivo and thus help determine the molecular mechanisms underlying the beneficial effects exerted by this UPR branch. In this study, we performed RNA-Seq analysis on the hippocampus from XBP1s conditional transgenic mice.

Project description:One major component of cellular proteome resides in the endoplasmic reticulum (ER), the key organelle for protein biogenesis in the secretory pathway. Disruption of ER proteostasis leads to ER stress, which subsequently activates multiple adaptive stress response pathways, collectedly termed as the unfolded protein response (UPR). One UPR branch is mediated by ATF6 (activating transcription factor 6). Activation of the ATF6 branch generates a transcriptional factor: short form ATF6 (sATF6). Since activation of this UPR branch has been shown to be neuroprotective in brain ischemia/stroke, it is critical to identify what genes are regulated by the sATF6 in neurons in vivo and determine the molecular mechanisms underlying the beneficial effects exerted by this UPR branch. In this study, we performed RNA-Seq analysis on the hippocampus from sATF6 conditional transgenic mice.

Project description:All animals must maintain genome and proteome integrity, especially when experiencing endogenous or exogenous stress. To cope, organisms have evolved sophisticated and conserved response systems: unfolded protein responses (UPRs) ensure proteostasis while the DNA damage response (DDR) maintains genome integrity. Emerging evidence suggests that UPRs and DDRs crosstalk, but the extent of crosstalk remains poorly understood. Here, we demonstrate that inactivation of the DNA primases pri-1 and pri-2, which synthesize RNA primers at replication forks and whose inactivation causes DNA damage, activates the UPR of the endoplasmic reticulum (UPR-ER) in Caenorhabditis elegans, with especially strong activation in the germline. We observed activation of both the inositol-requiring-enzyme 1 (ire-1) and the protein kinase RNA-like ER kinase (PEK-1) branches of the UPR-ER. Interestingly, activation of the UPR-ER output gene hsp-4/BiP was partially independent of its canonical activators, ire-1 and xbp-1, and instead required the third branch of the UPR-ER, atf-6, suggesting functional redundancy. We further found that primase depletion specifically induces the UPR-ER, but not the mechanistically distinct cytosolic or mitochondrial UPRs, suggesting that primase inactivation causes compartment-specific rather than global stress. Functionally, loss of ire-1 or pek-1 sensitized animals to replication stress caused by hydroxyurea. Finally, transcriptome analysis of pri-1 embryos revealed several deregulated processes that could cause UPR-ER activation, including protein glycosylation, calcium signaling, and fatty acid desaturation. Together, our data show that the UPR-ER, but not other UPRs, responds to replication fork stress and that the UPR-ER is required to alleviate this stress.

Project description:The major heat shock protein Hsp70 has been shown to form a complex with a scaffold protein Bag3, linking it to multiple signaling pathways. Via these interactions, the Hsp70-Bag3 module functions as a proteotoxicity sensor that controls cell signaling. Here, as a tool to identify signaling pathways regulated by this complex, we utilized JG-98, an allosteric inhibitor of Hsp70 that blocks its interaction with Bag3. Gene expression profiling followed by the pathway analysis indicated that a set of signaling pathways including the unfolded protein response (UPR) was activated by JG-98. Surprisingly, only the translation initiation factor eIF2a-associated branch of the UPR was activated under these conditions, while other UPR branches mediating induction of ER chaperones were not induced, suggesting that the response was not related to ER proteotoxicity and thus to ER-associated kinase PERK1. Indeed, induction of the UPR genes under these conditions was dependent on activation of a distinct cytoplasmic eIF2a kinase, HRI. We demonstrated that the Hsp70-Bag3 complex directly interacted with HRI and regulated phosphorylation of eIF2a upon induction of cytoplasmic proteotoxicity. Therefore, we uncovered a novel signaling response, which regulates cell death upon the buildup of abnormal protein species in cytoplasm via an Hsp70-Bag3-HRI-eIF2a axis.

Project description:Despite the potential of the endoplasmic reticulum (ER) stress response to accommodate adaptive pathways, its integration with other environmental-induced responses is poorly understood in plants. Here, we performed global expression profiling on soybean leaves exposed to polyethylene glycol treatment or to unfolded protein response (UPR) inducers to identify integrated networks between osmotic and ER stress-induced adaptive responses. The results unmasked the major branches of the ER-stress response, which includes enhancing protein folding and degradation in the ER, as well as specific osmotically regulated changes linked to cellular responses induced by dehydration. However, a small proportion (5.5%) of total up-regulated genes represented a shared response that seemed to integrate the two signaling pathways. These co-regulated genes were considered downstream targets based on similar induction kinetics and a synergistic response to the combination of osmotic- and ER-stress-inducing treatments. Genes in this integrated pathway with the strongest synergistic induction encoded proteins with diverse roles. Two of them contained a plant-specific development and cell death (DCD) domain while another had homology to proteins with an ubiquitin-associated (UBA) domain. A NAC domain-containing protein exhibited robust early kinetics of induction consistent with a role as a transfactor. This integrated pathway diverged further from characterized ER-specific branches of UPR as downstream targets were inversely regulated by osmotic stress. Collectively, our results describe a novel branch of the ER stress response that integrates the osmotic signal to potentiate transcription of shared target genes. Keywords: stress response

Project description:To dissect the requirements of membrane protein degradation from the ER, we expressed the mouse major histocompatibility complex class I heavy chain H-2K(b) in yeast. Like other proteins degraded from the ER, unassembled H-2K(b) heavy chains are not transported to the Golgi but are degraded in a proteasome-dependent manner. The overexpression of H-2K(b) heavy chains induces the unfolded protein response (UPR). In yeast mutants unable to mount the UPR, H-2K(b) heavy chains are greatly stabilized. This defect in degradation is suppressed by the expression of the active form of Hac1p, the transcription factor that upregulates UPR-induced genes. These results indicate that induction of the UPR is required for the degradation of protein substrates from the ER.

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:To dissect the requirements of membrane protein degradation from the ER, we expressed the mouse major histocompatibility complex class I heavy chain H-2K(b) in yeast. Like other proteins degraded from the ER, unassembled H-2K(b) heavy chains are not transported to the Golgi but are degraded in a proteasome-dependent manner. The overexpression of H-2K(b) heavy chains induces the unfolded protein response (UPR). In yeast mutants unable to mount the UPR, H-2K(b) heavy chains are greatly stabilized. This defect in degradation is suppressed by the expression of the active form of Hac1p, the transcription factor that upregulates UPR-induced genes. These results indicate that induction of the UPR is required for the degradation of protein substrates from the ER. Set of arrays organized by shared biological context, such as organism, tumors types, processes, etc. Computed

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: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.