Competitive inhibition of a set of endoplasmic reticulum protein genes (GRP78, GRP94, and ERp72) retards cell growth and lowers viability after ionophore treatment.

GRP78, a 78-kDa protein localized in the endoplasmic reticulum (ER), has been implicated in protein processing and stress protection. Its promoter contains a 36-bp region which is conserved among GRP genes across species and has the ability to compete for trans-acting factors mediating GRP gene expression. Integration of about 800 tandem copies of this sequence into the genome of a Chinese hamster ovary cell line (DG44) results in transfectants with the following phenotypes: (i) the induction level of GRP78 by the calcium ionophore A23187 and tunicamycin is reduced 4- and 2-fold, respectively, (ii) the induction levels of two other ER luminal protein genes, GRP94 and ERp72, are simultaneously down-regulated, (iii) the growth rate of these cells is half that of transfectants without the amplified sequence, and (iv) cell viability is decreased by 25-fold after A23187 treatment. These results provide new evidence that ERp72 shares common trans-acting regulatory factors with the GRP genes and that a reduction of this set of ER proteins correlates with lower viability after ionophore treatment.     

The endoplasmic reticulum stress protein GRP94, in addition to BiP, associates with unassembled immunoglobulin chains.

The molecular chaperone BiP/GRP78 associates with various polypeptides in the endoplasmic reticulum, including immunoglobulin chains. We now show, using chemical cross-linking, that another endoplasmic reticulum stress protein, GRP94, associates with newly synthesized immunoglobulin light and heavy chains. We demonstrate the presence of ternary complexes composed of immunoglobulin chains, BiP and GRP94. Because both BiP and GRP94 associate far less with fully assembled immunoglobulin than with unassembled subunits, our data suggest that GRP94, like BiP, functions as a molecular chaperone. The presence of both BiP and GRP94 in the same complex further suggests that the two stress proteins work in concert during the folding and assembly of immunoglobulins.     

AGR2, ERp57/GRP58, and some other human protein disulfide isomerases

This review considers the major features of human proteins AGR2 and ERp57/GRP58 and of other members of the protein disulfide isomerase (PDI) family. The ability of both AGR2 and ERp57/GRP58 to catalyze the formation of disulfide bonds in proteins is the parameter most important for assigning them to a PDI family. Moreover, these proteins and also other members of the PDI family have specific structural features (thioredoxin-like domains, special C-terminal motifs characteristic for proteins localized in the endoplasmic reticulum, etc.) that are necessary for their assignment to a PDI family. Data demonstrating the role of these two proteins in carcinogenesis are analyzed. Special attention is given to data indicating the presence of biomarker features in AGR2 and ERp57/GRP58. It is now thought that there is sufficient reason for studies of AGR2 and ERp57/GRP58 for possible use of these proteins in diagnosis of tumors. There are also prospects for studies on AGR2 and ERp57/GRP58 leading to developments in chemotherapy. Thus, we suppose that further studies on different members of the PDI family using modern postgenomic technologies will broaden current concepts about functions of these proteins, and this will be helpful for solution of urgent biomedical problems.     

KAR2, a karyogamy gene, is the yeast homolog of the mammalian BiP/GRP78 gene

The yeast KAR2 gene was isolated by complementation of a mutation that blocks nuclear fusion. The predicted KAR2 protein sequence is most homologous to mammalian BiP/GRP78 and has several structural features in common with it: a functional secretory signal sequence, a yeast endoplasmic reticulum retention signal (HDEL) at the carboxyl terminus, and the absence of potential N-linked glycosylation sites. Moreover KAR2 is regulated like BiP/GRP78: the level of mRNA is increased by drug treatments and mutations that cause accumulation of secretory precursors in the endoplasmic reticulum. However, unlike BiP/GRP78, KAR2 is also regulated by heat shock. Deletion of the KAR2 gene generated a recessive lethal mutation, showing that BiP/GRP78 function is required for cell viability.     

The stress protein ERp57/GRP58 binds specific DNA sequences in HeLa cells

The protein ERp57/GRP58 is a member of the protein disulfide isomerase family and is also a glucose-regulated protein, which, together with the other GRPs, is induced by a variety of cellular stress conditions. ERp57/GRP58 is mainly located in the endoplasmic reticulum (ER), but has also been found in the cytoplasm and in the nucleus, where it can bind DNA. In order to identify a possible correlation between the stress-response and the nuclear location of ERp57/GRP58, its binding sites on DNA in HeLa cells have been searched by chromatin immunoprecipitation and cloning of the immunoprecipitated DNA fragments. Following sequencing of the cloned fragments, 10 DNA sequences have been securely identified as in vivo targets of ERp57/GRP58. Nine of them are present in the non-coding regions of identified genes, and seven of these in introns. The features of some of these DNA sequences, that is, DNase hypersensitivity, proximity of MAR regions, and homology to the non-coding regions of orthologue genes of mouse or rat, are compatible with a gene expression regulatory function. Considering the nature of the genes concerned, two of which code for DNA repair proteins, we would suggest that at least part of the mechanism of action of ERp57/GRP58 takes place through the regulation of these, and possibly other still unidentified, stress-response genes.     

Analysis in vivo of GRP78-BiP/substrate interactions and their role in induction of the GRP78-BiP gene.

The endoplasmic reticulum (ER)-localized chaperone protein, GRP78-BiP, is involved in the folding and oligomerization of secreted and membrane proteins, including the simian virus 5 hemagglutinin-neuraminidase (HN) glycoprotein. To understand this interaction better, we have constructed a series of HN mutants in which specific portions of the extracytoplasmic domain have been deleted. Analysis of these mutant polypeptides expressed in CV-1 cells have indicated that GRP78-BiP binds to selective sequences in HN and that there exists more than a single site of interaction. Mutant polypeptides have been characterized that are competent and incompetent for association with GRP78-BiP. These mutants have been used to show that the induction of GRP78-BiP synthesis due to the presence of nonnative protein molecules in the ER is dependent on GRP78-BiP complex formation with its substrates. These studies have implications for the function of the GRP78-BiP protein and the mechanism by which the gene is regulated.     

A Peptidic Unconjugated GRP78/BiP Ligand Modulates the Unfolded Protein Response and Induces Prostate Cancer Cell Death

The molecular chaperone GRP78/BiP is a key regulator of protein folding in the endoplasmic reticulum, and it plays a pivotal role in cancer cell survival and chemoresistance. Inhibition of its function has therefore been an important strategy for inhibiting tumor cell growth in cancer therapy. Previous efforts to achieve this goal have used peptides that bind to GRP78/BiP conjugated to pro-drugs or cell-death-inducing sequences. Here, we describe a peptide that induces prostate tumor cell death without the need of any conjugating sequences. This peptide is a sequence derived from the cochaperone Bag-1. We have shown that this sequence interacts with and inhibits the refolding activity of GRP78/BiP. Furthermore, we have demonstrated that it modulates the unfolded protein response in ER stress resulting in PARP and caspase-4 cleavage. Prostate cancer cells stably expressing this peptide showed reduced growth and increased apoptosis in in vivo xenograft tumor models. Amino acid substitutions that destroyed binding of the Bag-1 peptide to GRP78/BiP or downregulation of the expression of GRP78 compromised the inhibitory effect of this peptide. This sequence therefore represents a candidate lead peptide for anti-tumor therapy.     

黄芪注射液对网腔钙结合蛋白基因沉默阿霉素损伤心肌细胞内质网应激伴侣蛋白GRP78,GRP94 mRNA的作用

目的：研究黄芪注射液对网腔钙结合蛋白（calumenin）基因沉默阿霉素损伤心肌细胞内质网应激伴侣蛋白GRP78,GRP94 mRNA的作用。方法：实验将体外培养的1~3 d乳鼠心肌细胞分为5组：对照组、模型组（正常细胞+3 mg/L阿霉素）、calumenin基因沉默模型组（慢病毒感染细胞+3 mg/L阿霉素）、黄芪组1（正常细胞+3 mg/L阿霉素+200 g/L黄芪）、黄芪组2（慢病毒感染细胞+3 mg/L阿霉素+200 g/L黄芪）。构建慢病毒-calumenin质粒,转染乳鼠培养心肌细胞,采用实时荧光定量分析（real-time PCR）检测各组心肌细胞calumenin及内质网应激伴侣蛋白GRP78、GRP94 mRNA表达。结果：①与对照组比较,模型组心肌细胞calumenin mRNA表达减少（P<0.05）,而calumenin基因沉默模型组及黄芪组2心肌细胞calumenin mRNA表达明显减少（P<0.01）;与模型组比较,黄芪组1心肌细胞calumenin mRNA表达增加（P<0.05）;与calumenin基因沉默模型组比较,黄芪组2心肌细胞calumenin mRNA表达明显增加（P<0.01）。②与对照组相比较,模型组及calumenin基因沉默模型组心肌细胞内质网应激伴侣蛋白GRP78、GRP94 mRNA表达明显增多（P<0.01）;与模型组比较,黄芪组1心肌细胞GRP78、GRP94 mRNA表达明显减少（P<0.01）;与calumenin基因沉默模型组比较,黄芪组2心肌细胞内质网应激伴侣蛋白GRP78、GRP94 mRNA表达明显减少（P<0.01）。结论：①阿霉素损伤可引起心肌细胞calumenin表达减少。②Calumenin可缓解阿霉素损伤所诱导心肌细胞内质网应激。黄芪注射液可抑制阿霉素损伤所诱导心肌细胞内质网应激,这种作用可能系通过calumenin介导实现的。     

Targeting GRP78 to enhance melanoma cell death

Targeting endoplasmic reticulum stress-induced apoptosis may offer an alternative therapeutic strategy for metastatic melanoma. Fenretinide and bortezomib induce apoptosis of melanoma cells but their efficacy may be hindered by the unfolded protein response, which promotes survival by ameliorating endoplasmic reticulum stress. The aim of this study was to test the hypothesis that inhibition of GRP78, a vital unfolded protein response mediator, increases cell death in combination with endoplasmic reticulum stress-inducing agents. Down-regulation of GRP78 by small-interfering RNA increased fenretinide- or bortezomib-induced apoptosis. Treatment of cells with a GRP78-specific subtilase toxin produced a synergistic enhancement with fenretinide or bortezomib. These data suggest that combining endoplasmic reticulum stress-inducing agents with strategies to down-regulate GRP78, or other components of the unfolded protein response, may represent a novel therapeutic approach for metastatic melanoma.     

Overexpression of GRP78 and GRP94 is involved in colorectal carcinogenesis

Glucose-related proteins (GRPs) are ubiquitously expressed in the endoplasmic reticulum and assist in protein folding and assembly, consequently considered to be molecular chaperones. GRP78 and GRP94 expression was induced by glucose starvation and up-regulated in samples taken from several different malignant tissues. To clarify the roles of both molecules in tumorigenesis and progression of colorectal carcinomas, immunohistochemistry (IHC) was performed on tissue microarrays containing colorectal carcinomas, adenomas and the non-neoplastic mucosa (NNM) using antibodies against GRP78 and GRP94. Their expression was correlated with the clinicopathological parameters of carcinomas. Both proteins were also studied in colorectal carcinoma cell lines (DLD-1, HCT-15, SW480 and WiDr) by IHC and Western blot. There was a gradually increased GRP78 expression from colorectal NNMs, carcinomas, to low-grade and high-grade adenomas (P<0.05), while up-regulated GRP94 expression from NNM, low-grade adenoma, high-grade adenoma, to carcinoma (P<0.05). The expression was similar in all the carcinoma cell lines. GRP78 expression was negatively correlated with lymphatic invasion or low GRP94 expression of the carcinomas (P<0.05), while there was no correlation of GRP94 expression with other parameters of carcinomas (P>0.05). Multivariate analysis showed that venous invasion, lymph node metastasis and UICC staging (P<0.05), but not age, sex, tumor size, differentiation, depth of invasion, lymphatic invasion, GRP78 and GRP94 expression (P>0.05), were independent prognostic factors for carcinomas. It is suggested that up-regulated expression of GRP78 and GRP94 could possibly be involved in the pathogenesis of colorectal carcinomas.     

caspase抑制剂z-VAD-fmk对阿霉素损伤乳鼠心肌细胞calumenin、caspase-3、GRP78及GRP94表达的影响

目的：研究细胞凋亡限速酶caspase广谱抑制剂z-VAD-fmk对阿霉素损伤心肌细胞calumenin、caspase-3、GRP78及GRP94表达的影响,探讨心肌细胞网腔钙结合蛋白与内质网应激及心肌细胞凋亡是否存在相互调控关系。方法：原代培养乳鼠心肌细胞实验分为3组：对照组（正常细胞）、阿霉素组（3 mg/L阿霉素+心肌细胞）、Z-VAD-fmk组（3 mg/L阿霉素+ 0.1μmol/L Z-VAD-fmk +心肌细胞）,每组细胞设3个复孔,分别处理后置37℃、CO₂培养箱中培养24 h阿霉素组、z-VAD-fmk组。采用免疫组化方法检测培养乳鼠心室肌细胞α-SMA蛋白。采用Westernblot技术检测各组心肌细胞Calumenin、内质网应激伴侣蛋白GRP78、GRP94及caspase-3表达。结果：与对照组相比较,阿霉素组心肌细胞calumenin表达明显减少（P < 0.01）,GRP78、GRP94及caspase-3表达增加（P < 0.01）。与阿霉素组相比较,z-VAD-fmk组心肌细胞calumenin表达增加（P < 0.01）,而GRP7,GRP94及caspase-3减少（P < 0.01）。结论：caspase广谱抑制剂z-VAD-fmk增加阿霉素损伤心肌细胞calumenin表达进而缓解内质网应激。     

Ligand-induced conformational shift in the N-terminal domain of GRP94, an Hsp90 chaperone

GRP94 is the endoplasmic reticulum paralog of cytoplasmic Hsp90. Models of Hsp90 action posit an ATP-dependent conformational switch in the N-terminal ligand regulatory domain of the chaperone. However, crystal structures of the isolated N-domain of Hsp90 in complex with a variety of ligands have yet to demonstrate such a conformational change. We have determined the structure of the N-domain of GRP94 in complex with ATP, ADP, and AMP. Compared with the N-ethylcarboxamidoadenosine and radicicol-bound forms, these structures reveal a large conformational rearrangement in the protein. The nucleotide-bound form exposes new surfaces that interact to form a biochemically plausible dimer that is reminiscent of those seen in structures of MutL and DNA gyrase. Weak ATP binding and a conformational change in response to ligand identity are distinctive mechanistic features of GRP94 and suggest a model for how GRP94 functions in the absence of co-chaperones and ATP hydrolysis.     

Leishmania infantum: gene cloning of the GRP94 homologue, its expression as recombinant protein, and analysis of antigenicity

The complete nucleotide sequence for the Leishmania infantum homologue to the glucose-regulated protein 94 (GRP94) gene was determined from the isolation and characterization of a genomic clone. Like the mammalian and plant GRP94s, the L. infantum GRP94 sequence possesses both an N-terminal signal peptide and a putative endoplasmic reticulum retention signal, consisting of the C-terminal tetrapeptide EDDL. Thus, L. infantum is the first protozoan organism in which GRP94 has been identified. Southern blot analysis has indicated that this protein is encoded by a single-copy gene. The L. infantum GRP94 gene was expressed in Escherichia coli and the recombinant protein used to evaluate its antigenicity and immunogenicity. Eighty-four percent of sera from dogs with visceral leishmaniasis reacted with the protein, indicating that GRP94 is a potent immunogen during Leishmania infection. Given the immunogenic and antigenic properties shown by the L. infantum GRP94, we think that this protein constitutes a valuable molecule for diagnostic purposes and a potential candidate for studies of protective immunogenicity.     

The stress response in Chinese hamster ovary cells. Regulation of ERp72 and protein disulfide isomerase expression and secretion

Expression of the glucose-regulated proteins (GRPs), GRP78 and GRP94, is induced by a variety of stress conditions including treatment of cells with tunicamycin or the calcium ionophore A23187. The stimulus for induction of these resident endoplasmic reticulum (ER) proteins appears to be accumulation of misfolded or underglycosylated protein within the ER. We have studied the induction of mRNAs encoding two other resident ER proteins, ERp72 and protein disulfide isomerase (PDI), during the stress response in Chinese hamster ovary cells. ERp72 shares amino acid sequence homology with PDI within the presumed catalytic active sites. ERp72 mRNA and, to a lesser degree, PDI mRNA were induced by treatment of Chinese hamster ovary cells with tunicamycin or A23187. These results identify ERp72 as a member of the GRP family. Stable high level overproduction of ERp72 or PDI from recombinant expression vectors did not alter the constitutive or induced expression of other GRPs. High level overexpression resulted in secretion of the overproduced protein specifically but not other resident ER proteins. This suggests that the ER retention mechanism is mediated by more specific interactions than just KDEL sequence recognition.