Cell cycle arrest mediated by WEE1 is involved in the unfolded protein response in plants

Activation of the unfolded protein response (UPR) in mammalian cells leads to cell cycle arrest at the G1 phase (Thomas et al., J Biol Chem 288:7606–7617, 2013). However, how UPR signaling affects cell cycle arrest remains largely unknown in plants. Here, we examined UPR and endoreduplication in Col-0, wee1, and ER stress sensing-deficient ire1a&b plants during DNA replication and ER stress conditions. We found that WEE1, an essential negative regulator of the cell cycle, is involved in the maintenance of ER homeostasis during genotoxic stress and the ER stress hypersensitivity of ire1a&b is alleviated by loss-of-function mutation in WEE1. WEE1-mediated cell cycle arrest was required for IRE1–bZIP60 pathway activation during ER stress. In contrast, loss-of-function mutation in WEE1 caused increased expression of UPR-related genes during DNA replication stress. WEE1 and IRE1 were required for endoreduplication during DNA replication stress and ER stress, respectively. Taken together, these findings suggest that cell cycle regulation is associated with UPR activation in different manners during ER stress and DNA replication stress in Arabidopsis.     

Inter‐regulation of the unfolded protein response and auxin signaling

The unfolded protein response (UPR) is a signaling network triggered by overload of protein‐folding demand in the endoplasmic reticulum (ER), a condition termed ER stress. The UPR is critical for growth and development; nonetheless, connections between the UPR and other cellular regulatory processes remain largely unknown. Here, we identify a link between the UPR and the phytohormone auxin, a master regulator of plant physiology. We show that ER stress triggers down‐regulation of auxin receptors and transporters in Arabidopsis thaliana. We also demonstrate that an Arabidopsis mutant of a conserved ER stress sensor IRE1 exhibits defects in the auxin response and levels. These data not only support that the plant IRE1 is required for auxin homeostasis, they also reveal a species‐specific feature of IRE1 in multicellular eukaryotes. Furthermore, by establishing that UPR activation is reduced in mutants of ER‐localized auxin transporters, including PIN5, we define a long‐neglected biological significance of ER‐based auxin regulation. We further examine the functional relationship of IRE1 and PIN5 by showing that an ire1 pin5 triple mutant enhances defects of UPR activation and auxin homeostasis in ire1 or pin5. Our results imply that the plant UPR has evolved a hormone‐dependent strategy for coordinating ER function with physiological processes.     

Unfolded protein response-induced BiP/Kar2p production protects cell growth against accumulation of misfolded protein aggregates in the yeast endoplasmic reticulum

Overproduction of delta(pro), a mutated secretory proteinase derived from a filamentous fungus Rhizopus niveus, results in formation of gross aggregates (delta(pro) aggregates) in the yeast endoplasmic reticulum (ER) lumen, activation of the unfolded protein response (UPR) and ER membrane proliferation. To investigate the roles of the UPR against the delta(pro) aggregates, we constructed an IRE1-deleted ((delta)ire1) strain. In contrast to wild-type cells, (delta)ire1 cells ceased to grow several hours after the overproduction of (delta)pro. Two lines of evidence argued against the possibility that the growth defect was due to the inability to make extra ER membrane which accommodates the (delta)pro aggregates. First, by electron microscopy, ER membrane proliferation was observed in (delta)ire1 cells overproducing (delta)pro. Second, disruption of the OPI1 gene in the (delta)ire1 mutant, which is considered to derepress the activities of phospholipid-synthesizing enzymes, did not restore the growth upon the overproduction of (delta)pro. Instead, the growth was restored when an extra copy of the KAR2 gene, which encodes yeast BiP, was introduced, indicating that an increase in the amount of BiP is essential for cell growth when the (delta)pro aggregates accumulate in the ER. Since BiP is included in the insoluble (delta)pro aggregates, it is likely that the amount of free BiP in the ER lumen is insufficient without the UPR to fully exert its functions. Consistently, overproduction of (delta)pro impaired protein translocation and folding in (delta)ire1 cells but not in wild-type cells. The tunicamycin sensitivity of (delta)ire1 cells was also suppressed by extra expression of KAR2, suggesting that BiP plays a principal role in protecting cell growth against misfolded proteins accumulated in the ER.     

Endoplasmic reticulum‐mediated unfolded protein response is an integral part of singlet oxygen signalling in plants

Singlet oxygen (¹O₂) is a by‐product of photosynthesis that triggers a signalling pathway leading to stress acclimation or to cell death. By analyzing gene expressions in a ¹O₂‐overproducing Arabidopsis mutant (ch1) under different light regimes, we show here that the ¹O₂ signalling pathway involves the endoplasmic reticulum (ER)‐mediated unfolded protein response (UPR). ch1 plants in low light exhibited a moderate activation of UPR genes, in particular bZIP60, and low concentrations of the UPR‐inducer tunicamycin enhanced tolerance to photooxidative stress, together suggesting a role for UPR in plant acclimation to low ¹O₂ levels. Exposure of ch1 to high light stress ultimately leading to cell death resulted in a marked upregulation of the two UPR branches (bZIP60/IRE1 and bZIP28/bZIP17). Accordingly, mutational suppression of bZIP60 and bZIP28 increased plant phototolerance, and a strong UPR activation by high tunicamycin concentrations promoted high light‐induced cell death. Conversely, light acclimation of ch1 to ¹O₂ stress put a limitation in the high light‐induced expression of UPR genes, except for the gene encoding the BIP3 chaperone, which was selectively upregulated. BIP3 deletion enhanced Arabidopsis photosensitivity while plants treated with a chemical chaperone exhibited enhanced phototolerance. In conclusion, ¹O₂ induces the ER‐mediated UPR response that fulfils a dual role in high light stress: a moderate UPR, with selective induction of BIP3, is part of the acclimatory response to ¹O₂, and a strong activation of the whole UPR is associated with cell death.     

Characterization of two homologs of Ire1p,a kinase/endoribonuclease in yeast,in Arabidopsis thaliana

The accumulation of unfolded proteins in the endoplasmic reticulum (ER) elicits an ER-to-nucleus signaling pathway known as the unfolded protein response (UPR) in eukaryotes. In yeast, Ire1p, a kinase/endoribonuclease in the ER membrane, plays a key role in the UPR signaling. We isolated two cDNA homologs of IRE1 gene from Arabidopsis (AtIre1a, AtIre1b). The two IRE1 homologs were predicted to form a type I transmembrane protein structure and contain kinase/endoribonuclease domains at their C-terminal halves. The expressions of the two genes were detected in various organ tissues of the Arabidopsis plant. The C-terminal half of the AtIre1a protein showed in vitro autophosphorylation activity. However, we could not detect endoribonuclease activity of the AtIre1a protein when we used yeast HAC1 RNA as the substrate in vivo.     

Direct Association of Unfolded Proteins with Mammalian ER Stress Sensor,IRE1β

IRE1, an ER-localized transmembrane protein, plays a central role in the unfolded protein response (UPR). IRE1 senses the accumulation of unfolded proteins in its luminal domain and transmits a signal to the cytosolic side through its kinase and RNase domains. Although the downstream pathways mediated by two mammalian IRE1s, IRE1α and IRE1β, are well documented, their luminal events have not been fully elucidated. In particular, there have been no reports on how IRE1β senses the unfolded proteins. In this study, we performed a comparative analysis to clarify the luminal event mediated by the mammalian IRE1s. Confocal fluorescent microscopy using GFP-fused IRE1s revealed that IRE1β clustered into discrete foci upon ER stress. Also, fluorescence correlation spectroscopy (FCS) analysis in living cells indicated that the size of the IRE1β complex is robustly increased upon ER stress. Moreover, unlike IRE1α, the luminal domain of IRE1β showed anti-aggregation activity in vitro, and IRE1β was coprecipitated with the model unfolded proteins in cells. Strikingly, association with BiP was drastically reduced in IRE1β, while IRE1α was associated with BiP and dissociated upon ER stress. This is the first report indicating that, differently from IRE1α, the luminal event mediated by IRE1β involves direct interaction with unfolded proteins rather than association/dissociation with BiP, implying an intrinsic diversity in the sensing mechanism of mammalian sensors.     

The unknown face of IRE1α – Beyond ER stress

IRE1α (Inositol Requiring kinase Enzyme 1 alpha), a transmembrane protein localized to the endoplasmic reticulum (ER) is a master regulator of the unfolded protein response (UPR) pathway. The fate determining steps during ER stress-induced apoptosis are greatly attributed to IRE1α’s endoribonuclease and kinase activities. Apart from its role as a chief executioner in ER stress, recent studies have shown that upon activation in the presence or absence of ER stress, IRE1α executes multiple cellular processes such as differentiation, immune response, progression and repression of the cell cycle. Besides its crucial role in protein misfolding, the versatile contributions of IRE1α in other cellular functions are greatly unknown. In this review, we have discussed the structural conservation of IRE1 among eukaryotes, the mechanisms underlying its activation and the recent understandings of the non-apoptotic functions of IRE1 other than ER stress-induced cell death.