GRP78, also known as BiP, is a central regulator of endoplasmic reticulum (ER) homeostasis due to its multiple functional roles in protein folding, ER calcium binding, and controlling of the activation of transmembrane ER stress sensors. ER stress induction of GRP78/BiP represents a major prosurvival arm of the unfolded protein response (UPR). However, the physiological role of GRP78 in development is not known. Using a transgenic approach, we discovered that the Grp78 promoter is activated in both the trophectoderm and inner cell mass (ICM) of embryos at embryonic day 3.5 via a mechanism requiring the ER stress elements. To reveal the function of the GRP78 in vivo, we created a tri-loxP Grp78 mutant allele, which was further crossed with EIIA-cre to create a knockout allele. The Grp78 ؉/؊ mice, which express 50% of the wild-type level of the GRP78 protein, are viable. Interestingly, the heterozygous Grp78 cells up-regulate the ER proteins GRP94 and protein disulfide isomerase at both the transcript and protein levels, while other UPR targets such as CHOP and XBP-1 are not affected. Further studies revealed that mouse embryonic fibroblasts from Grp78 ؉/؊ mice are capable of responding to ER stress. However, Grp78؊/؊ embryos that are completely devoid of GRP78 lead to peri-implantation lethality. These embryos do not hatch from the zona pellucida in vitro, fail to grow in culture, and exhibit proliferation defects and a massive increase in apoptosis in the ICM, which is the precursor of embryonic stem cells. These findings provide the first evidence that GRP78 is essential for embryonic cell growth and pluripotent cell survival.The unfolded protein response (UPR), which is conserved from yeast to human, triggers multiple pathways to allow cells to respond to stress conditions that target the endoplasmic reticulum (ER) (17). The ER is the site for the synthesis of secretory and membrane proteins and lipids and is also a major intracellular calcium storage compartment. As such, ER homeostasis is critical for the survival of eukaryotic cells. The 78-kDa glucose-regulated protein GRP78, also referred to as the immunoglobulin binding protein BiP, is a stress-inducible ER chaperone that belongs to the HSP70 family (15,27). GRP78 is composed of three domains: the ATPase domain, the peptide-binding domain, and a C-terminal domain with unknown function (21). GRP78 binds to the unfolded peptides through the peptide-binding domain and uses the energy from hydrolyzing ATP to promote proper folding and to prevent aggregation (22). GRP78 also possesses the capacity to bind Ca 2ϩ , which helps to immobilize Ca 2ϩ and maintain ER calcium homeostasis (26). Furthermore, GRP78 serves as a master modulator for the UPR network by binding to the ER stress sensors PERK, Ire1p, and ATF6 and inhibiting their activation (3, 43). Furthermore, due to its antiapoptotic property, stress induction of GRP78 represents an important prosurvival arm of the UPR, with implications for cancer progression, drug resistance, neuroprotection, and diabete...
ATF6 as a Transcription Activator of the Endoplasmic Reticulum Stress Element: Thapsigargin Stress-Induced Changes and Synergistic Interactions with NF-Y and YY1
ATF6, a member of the leucine zipper protein family, can constitutively induce the promoter of glucoseregulated protein (grp) genes through activation of the endoplasmic reticulum (ER) stress element (ERSE). To understand the mechanism of grp78 induction by ATF6 in cells subjected to ER calcium depletion stress mediated by thapsigargin (Tg) treatment, we discovered that ATF6 itself undergoes Tg stress-induced changes. In nonstressed cells, ATF6, which contains a putative short transmembrane domain, is primarily associated with the perinuclear region. Upon Tg stress, the ATF6 protein level dropped initially but quickly recovered with the additional appearance of a faster-migrating form. This new form of ATF6 was recovered as soluble nuclear protein by biochemical fractionation, correlating with enhanced nuclear localization of ATF6 as revealed by immunofluorescence. Optimal ATF6 stimulation requires at least two copies of the ERSE and the integrity of the tripartite structure of the ERSE. Of primary importance is a functional NF-Y complex and a high-affinity NF-Y binding site that confers selectivity among different ERSEs for ATF6 inducibility. In addition, we showed that YY1 interacts with ATF6 and in Tg-treated cells can enhance ATF6 activity. The ERSE stimulatory activity of ATF6 exhibits properties distinct from those of human Ire1p, an upstream regulator of the mammalian unfolded protein response. The requirement for a high-affinity NF-Y site for ATF6 but not human Ire1p activity suggests that they stimulate the ERSE through diverse pathways.
Endoplasmic Reticulum Stress Induction of the Grp78/BiP Promoter: Activating Mechanisms Mediated by YY1 and Its Interactive Chromatin Modifiers
The unfolded protein response is an evolutionarily conserved mechanism whereby cells respond to stress conditions that target the endoplasmic reticulum (ER). The transcriptional activation of the promoter of GRP78/BiP, a prosurvival ER chaperone, has been used extensively as an indicator of the onset of the UPR. YY1, a constitutively expressed multifunctional transcription factor, activates the Grp78 promoter only under ER stress conditions. Previously, in vivo footprinting analysis revealed that the YY1 binding site of the ER stress response element of the Grp78 promoter exhibits ER stress-induced changes in occupancy. Toward understanding the underlying mechanisms of these unique phenomena, we performed chromatin immunoprecipitation analyses, revealing that YY1 only occupies the Grp78 promoter upon ER stress and is mediated in part by the nuclear form of ATF6. We show that YY1 is an essential coactivator of ATF6 and uncover their specific interactive domains. Using small interfering RNA against YY1 and insertional mutation of the gene encoding ATF6␣, we provide direct evidence that YY1 and ATF6 are required for optimal stress induction of Grp78. We also discovered enhancement of the ER-stressed induction of the Grp78 promoter through the interaction of YY1 with the arginine methyltransferase PRMT1 and evidence of its action through methylation of the arginine 3 residue on histone H4. Furthermore, we detected ER stress-induced binding of the histone acetyltransferase p300 to the Grp78 promoter and histone H4 acetylation. A model for the ER stress-mediated transcription factor binding and chromatin modifications at the Grp78 promoter leading to its activation is proposed.
OBJECTIVETo investigate the role of the endoplasmic reticulum (ER) chaperone glucose-regulated protein (GRP) 78/BiP in the pathogenesis of obesity, insulin resistance, and type 2 diabetes.RESEARCH DESIGN AND METHODSMale Grp78+/− mice and their wild-type littermates were subjected to a high-fat diet (HFD) regimen. Pathogenesis of obesity and type 2 diabetes was examined by multiple approaches of metabolic phenotyping. Tissue-specific insulin sensitivity was analyzed by hyperinsulinemic-euglycemic clamps. Molecular mechanism was explored via immunoblotting and tissue culture manipulation.RESULTSGrp78 heterozygosity increases energy expenditure and attenuates HFD-induced obesity. Grp78+/− mice are resistant to diet-induced hyperinsulinemia, liver steatosis, white adipose tissue (WAT) inflammation, and hyperglycemia. Hyperinsulinemic-euglycemic clamp studies revealed that Grp78 heterozygosity improves glucose metabolism independent of adiposity and following an HFD increases insulin sensitivity predominantly in WAT. As mechanistic explanations, Grp78 heterozygosity in WAT under HFD stress promotes adaptive unfolded protein response (UPR), attenuates translational block, and upregulates ER degradation-enhancing α-mannosidase–like protein (EDEM) and ER chaperones, thus improving ER quality control and folding capacity. Further, overexpression of the active form of ATF6 induces protective UPR and improves insulin signaling upon ER stress.CONCLUSIONSHFD-induced obesity and type 2 diabetes are improved in Grp78+/− mice. Adaptive UPR in WAT could contribute to this improvement, linking ER homeostasis to energy balance and glucose metabolism.
Underglycosylation of ATF6 as a Novel Sensing Mechanism for Activation of the Unfolded Protein Response
ATF6 is a key transcriptional activator of the unfolded protein response (UPR), which allows mammalian cells to maintain cellular homeostasis when they are subjected to a variety of environmental and physiological stresses that target the endoplasmic reticulum (ER). ATF6, a 90-kDa ER transmembrane protein, contains three evolutionarily conserved N-linked glycosylation sites within its carboxyl luminal domain. Although it is well established that p90ATF6 activation requires transit from the ER to the Golgi, where it is cleaved by the S1P/S2P protease system to generate a nuclear form p60ATF6 that acts as a transcriptional activator, the functional significance of p90ATF6 N-linked glycosylation is unknown. Here we show that ER Ca 2؉ depletion stress, a triggering mechanism for the UPR, induces the formation of ATF6(f), which represents de novo partial glycosylation of newly synthesized p90ATF6. By mutating a single amino acid within the N-linked glycosylation site closest to the carboxyl terminus of p90ATF6, we recreated ATF6(f). This mutation sharply reduces p90ATF6 association with calreticulin, a major Ca 2؉ -binding chaperone for N-glycoprotein. We further determined that ATF6(f) exhibits a faster rate of constitutive transport to the Golgi, resulting in a higher level of p60ATF6 in the nucleus and stronger transactivating activity in the absence of ER stress. Additional analysis of p90ATF6 mutants targeting single or multiple N-glycosylation sites also showed higher constitutive transactivating activity than wild type ATF6. Because accumulation of underglycosylated proteins in the ER is a potent inducer for the UPR, these studies uncover a novel mechanism whereby the glycosylation status of p90ATF6 can serve as a sensor for ER homeostasis, resulting in ATF6 activation to trigger the UPR.The discovery that ATF6 is a key transcriptional activator of endoplasmic reticulum (ER) 1 -resident molecular chaperones and folding enzymes in the unfolded protein response (UPR) has revealed novel molecular mechanisms employed by mammalian cells to respond to stresses that perturb ER homeostasis. ATF6, a 670-amino acid glycoprotein with the electrophoretic mobility of a 90-kDa protein (p90ATF6), is constitutively expressed in a variety of mammalian cells (1). It contains a single transmembrane domain with 272 amino acids oriented in the ER lumen. ER stress induces proteolysis of the membrane-bound p90ATF6, releasing the soluble amino portion of p60ATF6, which relocates to the nucleus and activates the transcription of a wide variety of ER stress-inducible promoters, of which Grp78/BiP is the most well characterized (2-4). Conservation of protease cleavage sites led to the discovery that Golgi-localized S1P/S2P proteases that process sterol response element binding proteins in response to cholesterol deprivation also process ATF6 in response to ER stress (4). Specific luminal domains of p90ATF6 have been mapped which are required for translocation to the Golgi (5). It was further determined that GRP78 retains p90ATF6 in the ...
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