Project description:Eukaryotic IRE1 mitigates endoplasmic-reticulum (ER) stress by orchestrating the unfolded-protein response (UPR). IRE1 spans the ER membrane, and signals through a cytosolic kinase-endoribonuclease module. The endoribonuclease generates the transcription factor XBP1s by intron excision between similar RNA stem-loop endomotifs, and depletes select cellular mRNAs through regulated IRE1-dependent decay (RIDD). Paradoxically, mammalian RIDD seemingly targets only mRNAs with XBP1-like endomotifs, while in flies RIDD exhibits little sequence restriction. By comparing nascent and total IRE1α-controlled mRNAs in human breast cancer cells, we discovered not only canonical endomotif-containing RIDD substrates, but also many targets lacking recognizable motifs—degraded by a process we coin RIDDLE, for RIDD lacking endomotif. IRE1α displayed two basic endoribonuclease modalities: endomotif-specific cleavage, minimally requiring dimers; and endomotif-independent promiscuous processing, requiring phospho-oligomers. An oligomer-deficient mutant that did not support RIDDLE failed to rescue cancer-cell viability. These results link IRE1α oligomers, RIDDLE, and cell survival, advancing mechanistic understanding of the UPR.

Project description:Eukaryotic IRE1 mitigates endoplasmic-reticulum (ER) stress by orchestrating the unfolded-protein response (UPR). IRE1 spans the ER membrane, and signals through a cytosolic kinase-endoribonuclease module. The endoribonuclease generates the transcription factor XBP1s by intron excision between similar RNA stem-loop endomotifs, and depletes select cellular mRNAs through regulated IRE1-dependent decay (RIDD). Paradoxically, mammalian RIDD seemingly targets only mRNAs with XBP1-like endomotifs, while in flies RIDD exhibits little sequence restriction. By comparing nascent and total IRE1α-controlled mRNAs in human breast cancer cells, we discovered not only canonical endomotif-containing RIDD substrates, but also many targets lacking recognizable motifs—degraded by a process we coin RIDDLE, for RIDD lacking endomotif. IRE1α displayed two basic endoribonuclease modalities: endomotif-specific cleavage, minimally requiring dimers; and endomotif-independent promiscuous processing, requiring phospho-oligomers. An oligomer-deficient mutant that did not support RIDDLE failed to rescue cancer-cell viability. These results link IRE1α oligomers, RIDDLE, and cell survival, advancing mechanistic understanding of the UPR.

Project description:IRE1a and XBP1 are key regulators of the unfolded protein response (UPR). XBP1 ablation causes profound hypolipidemia in mice, and triggers feedback activation of its upstream enzyme IRE1a, instigating regulated IRE1-dependent decay (RIDD), an mRNA degradation mechanism dependent on IRE1a's endoribonuclease activity. Comprehensive microarray analysis of XBP1 and/or IRE1a deficient liver identified genes involved in lipogenesis and lipoprotein metabolism as RIDD substrates, which might contribute to the suppression of plasma lipid levels by activated IRE1a. To identify RIDD substrate mRNAs and direct XBP1 targets in the liver, we performed a comprehensive comparative microarray analysis of three groups of RNA samples: WT and XBP1 deficient mice, WT and IRE1a deficient mice untreated or injected with tunicamycin, and XBP1 deficient mice injected with luciferase or IRE1a siRNA.

Project description:IRE1a and XBP1 are key regulators of the unfolded protein response (UPR). XBP1 ablation causes profound hypolipidemia in mice, and triggers feedback activation of its upstream enzyme IRE1a, instigating regulated IRE1-dependent decay (RIDD), an mRNA degradation mechanism dependent on IRE1a's endoribonuclease activity. Comprehensive microarray analysis of XBP1 and/or IRE1a deficient liver identified genes involved in lipogenesis and lipoprotein metabolism as RIDD substrates, which might contribute to the suppression of plasma lipid levels by activated IRE1a.

Project description:Endoplasmic Reticulum (ER) stress is a hallmark of various diseases, which is dealt with through the activation of an adaptive signaling pathway named the Unfolded Protein Response (UPR). This response is mediated by three ER-resident sensors and the most evolutionary conserved, IRE1α signals through its cytosolic kinase and endoribonuclease (RNase) activities. IRE1α RNase activity can either catalyze the initial step of XBP1 mRNA unconventional splicing or degrade a number of RNAs through Regulated IRE1-Dependent Decay (RIDD). The balance between these two activities plays an instrumental role in cells’ life and death decisions upon ER stress. Until now, the biochemical and biological outputs of IRE1α RNase activity have been well documented, however, the precise mechanisms controlling whether IRE1 signaling is adaptive or pro-death (terminal) remain unclear. This prompted us to further investigate those mechanisms and we hypothesized that XBP1 mRNA splicing and RIDD activity could be co-regulated by the IRE1α RNase regulatory network. We showed that a key nexus in this pathway is the tRNA ligase RtcB which, together with IRE1α, is responsible for XBP1 mRNA splicing. We demonstrated that RtcB is tyrosine phosphorylated by c-Abl and dephosphorylated by PTP1B. Moreover, we identified RtcB Y306 as a key residue which, when phosphorylated, perturbs RtcB interaction with IRE1α, thereby attenuating XBP1 mRNA splicing and favoring RIDD. Our results demonstrate that the IRE1α RNase regulatory network is dynamically fine-tuned by tyrosine kinases and phosphatases upon various stresses and that the nature of the stress determines cell adaptive or death outputs.

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:Mutations in myelin protein zero (MPZ) are generally associated with Charcot-Marie-Tooth type 1B (CMT1B) disease, one of the most common forms of demyelinating neuropathy. Pathogenesis of some MPZ mutants, such as S63del and R98C, involves protein misfolding and retention in the endoplasmic reticulum (ER) of myelinating Schwann cells. To cope with proteotoxic ER-stress, Schwann cells mount an unfolded protein response (UPR) characterized by activation of the PERK, ATF6 and IRE1/XBP1 pathways. Previous studies have reported that targeting PERK pathway can mitigate the neuropathy in CMT1B mice. To unravel the role of the XBP1 pathway in normal myelination and in CMT1B, we generated mouse models of in which XBP1 is deleted specifically in Schwann cells. We observed that whereas XBP1 is dispensable for normal developmental myelination, myelin maintenance and remyelination after injury, the absence of XBP1 dramatically worsens the hypomyelination and the electrophysiological and locomotor parameters in young and adult CMT1B neuropathic animals. RNAseq analysis suggested that XBP1 exerts its adaptive function in large part via the induction of genes involved in misfolded protein degradation. Accordingly, the exacerbation of the neuropathy was accompanied by upregulation of ER-stress pathways and of IRE1-mediated RIDD signaling, suggesting that the activation of XBP1 plays a critical role in limiting mutant proteins toxicity, which cannot be compensated by other stress responses. Schwann cell specific overexpression of spliced XBP1 partially re-established Schwann cell proteostasis and attenuated CMT1B severity in vivo in both the S63del and R98C mouse models. In addition, the pharmacologic selective activation of XBP1 signaling ameliorated myelination in S63del dorsal root ganglia explants.

Project description:xenograft, patientderived xenograft and the genetic Arid1aflox/flox/Pik3caH1047R mouse models. Finally, B-I09 synergizes with inhibition of HDAC6, a known regulator of the ER stress response, in suppressing the growth of ARID1A-inactivated OCCCs. These studies reveal a promising therapeutic strategy for ARID1A-mutant OCCCs and define the IRE1?-XBP1 axis of the ER stress response as a targetable vulnerability for ARID1A-mutant OCCCs. Our findings indicate that pharmacological inhibition of the IRE1?-XBP1 pathway alone or in combination with HDAC6 inhibition represents an urgently needed therapeutic strategy for ARID1A-mutant ovarian cancers.

Project description:Autophagy is a conserved process in eukaryotes that contributes to cell survival in response to stress. Previously, we found that ER stress induces autophagy in a manner dependent upon IRE1b, an ER membrane-associated factor involved in the splicing of bZIP60 mRNA. IRE1 is a dual protein kinase and ribonuclease, and here we studied the involvement of the protein kinase catalytic domain, nucleotide binding and RNase domains of IRE1b in activating autophagy. Autophagy was assessed by quantifying the numbers of autophagosomes in transgenic Arabidopsis seedlings bearing mutations in the various IRE1b domains. The results showed that nucleotide binding and RNase activity of IRE1b are required for ER stress-mediated autophagy. The RNase activity is involved in IRE1b’s mRNA splicing function, but its principal splicing target, bZIP60, is not involved in IRE1b’s activation of autophagy. We therefore considered other roles for IRE1b in the activation of autophagy. Clustering of ER localized IRE1b-YFP was observed when seedlings were subjected to ER stress, and so we investigated whether IRE1b clustering induced autophagy. However, the RNase knockout mutation in IRE1b still undergoes clustering, suggesting that IRE1b clustering does not induce autophagy. In response to ER stress, the RNase of IRE1 has been found to engage in another activity called Regulated Ire1-Dependent Decay of Messenger RNA (RIDD), which is the promiscuous degradation of other mRNA in response to ER stress. By analyzing the RNA-seq data, 12 RIDD target genes were picked up for testing their role in inhibiting autophagy, and glucosidase 21 and peroxidase 14 are proved to be degraded to support the induction of autophagy by ER stress.

Project description:Epithelial mesenchymal plasticity (EMP) is a complex cellular reprogramming event that plays a major role in tissue homeostasis to infections and injury. Recently we elucidated a mechanism wherein the unfolded protein response (UPR) triggers EMP through the inositol-requiring protein 1 (IRE1α)–X-box-binding protein 1 (XBP1) axis, enhancing glucose shunting to protein N glycosylation producing ER stress. To better the genomic targets for the IRE1-XBP1 pathway that activate compensatory metabolic changes in EMP, we systematically identified the genomic XBP1 targets using Cleavage Under Targets and Release Using Nuclease (CUT&RUN) of a FLAG-epitope tagged XBP1 in RSV infection. CUT&RUN identified 7,086 enriched binding sites mapped to 4,827 genes; of these XBP1 binds to 2,119 sites within 1 kb of the transcription start sites. Interestingly, XBP1 binds to 322 superenhancers associated with RHO GTPase signaling that were associated with largely inert gene expression. By contrast, XBP1 binds to proximal promoters inducing coordinate mRNA expression of hexosamine biosynthetic enzymes encoding sequential steps in UDP-GlcNAc biosynthesis through AGCTCA motifs. We demonstrate that IRE1-XBP1 signaling is necessary and sufficient to activate core HBP enzymatic pathway by recruiting transcriptional elongation-competent phospho-Ser2 CTD modified RNA Pol II (pSer-PolII).