Akira Hosoda

Translational control by the ER transmembrane kinase/ribonuclease IRE1 under ER stress

Under conditions of endoplasmic reticulum (ER) stress, mammalian cells induce both translational repression and the unfolded protein response that transcriptionally activates genes encoding ER-resident molecular chaperones. To date, the only known pathway for translational repression in response to ER stress has been the phosphorylation of eIF-2α by the double-stranded RNA-activated protein kinase (PKR) or the transmembrane PKR-like ER kinase (PERK). Here we report another pathway in which the ER transmembrane kinase/ribonuclease IRE1β induces translational repression through 28S ribosomal RNA cleavage in response to ER stress. The evidence suggests that both pathways are important for efficient translational repression during the ER stress response.

Cotranslational Targeting of XBP1 Protein to the Membrane Promotes Cytoplasmic Splicing of Its Own mRNA

Endoplasmic reticulum (ER) stress triggers the cytoplasmic splicing of XBP1 mRNA by the transmembrane endoribonuclease IRE1alpha, resulting in activation of the unfolded protein response, which maintains ER homeostasis. We show that the unspliced XBP1 (XBP1u) mRNA is localized to the membrane, although its product is neither a secretory nor a membrane protein and is released to the cytosol after splicing. Biochemical and mutagenic analyses demonstrated that membrane localization of XBP1u mRNA required its in-frame translation. An insertional frame-shift mutation greatly diminished both membrane localization and splicing of the XBP1u mRNA. Furthermore, membrane localization was compromised by puromycin treatment and required a hydrophobic region within XBP1u. These data demonstrate that the nascent XBP1u polypeptide recruits its own mRNA to the membrane. This system serves to enhance cytoplasmic splicing and could facilitate a more rapid response to ER stress, and represents a unique way of cotranslational protein targeting coupled to mRNA maturation.

Identification of a consensus element recognized and cleaved by IRE1α

IRE1α is an endoplasmic reticulum (ER)-located transmembrane RNase that plays a central role in the ER stress response. Upon ER stress, IRE1α is activated and cleaves specific exon–intron sites in the mRNA encoding the transcription factor X-box-binding protein 1 (XBP1). In addition, previous studies allow us to predict that IRE1α targets several RNAs other than the XBP1. In fact, we have identified CD59 mRNA as a cleavage target of IRE1α. However, it is not yet clear how IRE1α recognizes and cleaves target RNAs. To address this question, we devised a unique method that combines an in vitro cleavage assay with an exon microarray analysis, and performed genome-wide screening for IRE1α cleavage targets. We identified 13 novel mRNAs as candidate IRE1α cleavage targets. Moreover, an analysis of the novel cleavage sites revealed a consensus sequence (CUGCAG) which, when accompanied by a stem-loop structure, is essential for IRE1α-mediated cleavage. The sequence and structure were also conserved in the known IRE1α cleavage targets, CD59 and XBP1. These findings provide the important clue to understanding the molecular mechanisms by which IRE1α recognizes and cleaves target RNAs.

RNase domains determine the functional difference between IRE1α and IRE1β

Endoplasmic reticulum (ER) stress is associated with the functional disorder of the ER. During conditions of ER stress, cells induce at least two responses to maintain ER function: transcriptional upregulation of ER quality control genes, and translational attenuation of protein synthesis. Induction of ER quality control proteins is mediated by IRE1α, which activates the transcription factor XBP1 via an unconventional splicing event, while a partial translational attenuation is mediated by IRE1β. Here, we show by both in vivo and in vitro analyses that the RNase domain of IRE1 determines the functional specificities of each of these isoforms.

Positive contribution of ERdj5/JPDI to endoplasmic reticulum protein quality control in the salivary gland

In eukaryotic cells, most membrane and secretory proteins are modified post-translationally in the ER (endoplasmic reticulum) for correct folding and assembly. Disulfide-bond formation is one of the important modifications affecting folding and is catalysed by the PDI (protein disulfide isomerase) family proteins. ERdj5 [also known as JPDI (J-domain-containing PDI-like protein)] is a member of the PDI family proteins and has been reported to act as a reductase in ERAD (ER-associated degradation). However, the role of ERdj5 at the whole-body level remains unclear. Therefore in the present study we generated ERdj5-knockout mice {the mouse gene of ERdj5 is known as Dnajc10 [DnaJ (Hsp40) homologue, subfamily C, member 10]} and analysed them. Although ERdj5-knockout mice were viable and healthy, the ER stress response was activated in the salivary gland of the knockout mice more than that of control mice. Furthermore, in ERdj5-knockout cells, the expression of exogenous ERdj5 mitigated the ER stress caused by overproduction of alpha-amylase, which is one of the most abundant proteins in saliva and has five intramolecular disulfide bonds. This effect was dependent on the thioredoxin-like motifs of ERdj5. Thus we suggest that ERdj5 contributes to ER protein quality control in the salivary gland.

Identification of a novel mammalian endoplasmic reticulum-resident KDEL protein using an EST database motif search.

Several endoplasmic reticulum (ER)-resident proteins contain a unique C-terminal sequence (KDEL) which is required for the retention of these proteins in the ER. By searching a mouse EST database for records containing the nucleotide sequence encoding the KDEL motif, we extracted cDNAs encoding putative novel ER-resident proteins in addition to all of the known ER proteins bearing the KDEL motif. Using the sequence information obtained by this database search, we cloned the cDNA encoding a novel KDEL motif-bearing protein, ER protein 58 (EP58), sharing no significant homology to any of the known ER-resident proteins. Subcellular localization of EP58 in the ER was confirmed by cytoimmunofluorescence studies using epitope-tagged EP58. The EP58 gene was primarily expressed in embryo, placenta, and adult heart. Neither heat shock nor ER stress as tested here was sufficient to induce expression of the EP58 gene. A putative role of the N-terminal half of EP58 in protein-protein interaction is suggested by its similarity to the filamin rod domain. Similarity of the EP58 sequence with bacterial and fungus proteins suggests a possible role for EP58 in polysaccharide biosynthesis.

Identification of the redox partners of ERdj5/JPDI, a PDI family member, from an animal tissue

ERdj5 (also known as JPDI) is a member of PDI family conserved in higher eukaryotes. This protein possesses an N-terminal J domain and C-terminal four thioredoxin domains each having a redox active site motif. Despite the insights obtained at the cellular level on ERdj5, the role of this protein in vivo is still unclear. Here, we present a simple method to purify and identify the disulfide-linked complexes of this protein efficiently from a mouse tissue. By combining acid quenching and thiol-alkylation, we identified a number of potential redox partners of ERdj5 from the mouse epididymis. Further, we show that ERdj5 indeed interacted with two of the identified proteins via formation of intermolecular disulfide bond. Thus, this approach enabled us to detect and identify redox partners of a PDI family member from an animal tissue.

Detection of ER stress in vivo by Raman spectroscopy

The endoplasmic reticulum (ER) is an organelle in which most membrane and secretory proteins are synthesized. If these proteins are not folded correctly, unfolded proteins accumulate in the ER lumen, causing a cellular situation known as ER stress. Recently, many studies on the relationship between ER stress and diseases have been reported. Thus, studies of ER stress in vivo should yield information that is useful in pathology. Model mice have been developed as a powerful tool to visualize ER stress in vivo, but this approach depends on transgenic technology. Here, we report on a method of detecting ER stress in vivo by Raman spectroscopy. Our experiments revealed that two specific Raman bands were reduced in both cultured cells and animal tissues in an ER stress dependent manner. This suggests that Raman spectroscopy could be a useful tool to detect ER stress in vivo without transgenic technology.

Constitutive role of GADD34 and CReP in cancellation of phospho‐eIF2α‐dependent translational attenuation and insulin biosynthesis in pancreatic β cells

Insulin biosynthesis has been well characterized with respect to transcriptional and post‐translational regulation. However, the relationship between translational regulation of insulin and protein quality control in the endoplasmic reticulum (ER) remains to be clarified. Here we carried out forced expression of insulin in non‐insulin‐producing cells and compared activation level of ER stress‐responsive molecules between insulin‐producing cells and non‐insulin‐producing cells under normal culture condition or ER stress condition. Forced expression of insulin in non‐insulin‐producing cells caused severe ER stress with striking translational attenuation through phosphorylation of eIF2α by activation of protein kinase RNA‐like endoplasmic reticulum kinase (PERK), resulting in inhibition of insulin production at the protein level. We also found that GADD34 and CReP are highly expressed in the cells that endogenously produce insulin and that eIF2α shows constitutively low phosphorylation level in these cells although PERK is constitutively activated under both normal culture conditions and physiological conditions in the same cells. Inhibition of eIF2α phosphatase further decreased insulin level in pancreatic β cells. These findings suggest that eIF2α phosphorylation level is kept low by GADD34‐ and/or CReP‐regulated phosphatases in pancreatic β cells and that cancellation of phospho‐eIF2α‐dependent translational inhibition by the molecular mechanism contributes to mass production of insulin in pancreatic β cells.