Endoplasmic reticulum oxidoreductases (Eros) are essential for the formation of disulfide bonds. Understanding disulfide bond catalysis in mammals is important because of the involvement of protein misfolding in conditions such as diabetes, arthritis, cancer, and aging. Mammals express two related Ero proteins, Ero1␣ and Ero1. Ero1 is incompletely characterized but is of physiological interest because it is induced by the unfolded protein response. Here, we show that Ero1 can form homodimers and mixed heterodimers with Ero1␣, in addition to Ero-PDI dimers. Ero-Ero dimers require the Ero active site, occur in vivo, and can be modeled onto the Ero1p crystal structure. Our data indicate that the Ero1 protein is constitutively strongly expressed in the stomach and the pancreas, but in a cell-specific fashion. In the stomach, selective expression of Ero1 occurs in the enzyme-producing chief cells. In pancreatic islets, Ero1 expression is high, but is inversely correlated with PDI and PDIp levels, demonstrating that cell-specific differences exist in the regulation of oxidative protein folding in vivo.Protein folding in the ER 5 attracts considerable interest because the failure of a protein to fold can lead to a host of genetic and acquired diseases (1), ranging from cystic fibrosis to ␣1 anti-trypsin deficiency (2). Professional secretory cells in particular must regulate the synthesis of their ER membranes and chaperones to cope with the demands of increased protein production. This is achieved through ER to nucleus signaling pathways, mediated by the trans-membrane associated proteins Ire1␣, PERK, and ATF6 (3). ATF6 and Ire1␣ induce the transcription of XBP1 and the splicing of its mRNA, culminating in the expression of UPR target genes (4). XBP1 is required for B cell maturation into antibody-producing plasma cells (5), and recently, XBP1 and chronic unfolded protein responses have been implicated in obesity and the onset of type 2 diabetes (6), suggesting that targeting physiological unfolded protein responses may have therapeutic value in this disease.Disulfide bond formation is an essential component of the protein folding process, and disulfide bonds are required for structural stability, enzymatic function, and regulation of protein activity (7). The catalytic events involving the oxidation, reduction, and isomerization of disulfide bonds take place in the ER. During protein oxidation, PDI introduces native disulfide bonds into substrate proteins, and is reoxidized by the Ero proteins (Ero1p in yeast, Ero1␣ and Ero1 in humans) (8 -11). In yeast, Pdi1p is capable of both oxidizing and isomerizing disulfide bonds, although the relative importance of each function has been debated (12). In humans, PDI also contributes to collagen biosynthesis as a component of the prolyl-4-hydroxlase complex (13) and can act as a component of the ER degradation machinery, particularly with respect to the unfolding and retro-translocation of toxins (14). Numerous PDI homologues exist in yeast (Mpd1p, Mpd2p, Eps1p, and Eug...
Oral epithelial tumour tissue, and cultured cervical epithelial carcinoma cells have been studied using synchrotron infrared microspectroscopy. Mid infrared absorption spectra collected at cellular spatial resolution from within oral tumours were found to be sufficiently distinct, when analysed by principal component analysis, to distinguish between three different cell types within the tumour. The resulting data were sufficiently robust to allow correct classification of spectra from cells within subsequent tissue samples. These results go some way to demonstrate the potential of infrared spectroscopy as a tool in the post-operative screening of oral cancer patients by the examination of exfoliated epithelial cells. To gain a better understanding of the inherent variability in the infrared spectra of such epithelial cells, we have studied A431 carcinoma cells under the stimulus of the growth-stimulating hormone EGF. We have detected key changes in the infrared spectrum that relate to the activation of the growth factor signalling mechanism.
The ER (endoplasmic reticulum) is the site of protein folding for all eukaryotic secreted and plasma membrane proteins. Disulphide bonds are formed in many of these proteins through a dithiol–disulphide exchange chain comprising two types of protein catalysts: PDI (protein disulphide-isomerase) and ERO (ER oxidoreductase) proteins. This review will examine what we know about ERO function, and will then consider ERO interactions and their implications for mammalian oxidative protein folding.
Disulfide bond catalysis is an essential component of protein biogenesis in the secretory pathway, from yeast through to man. In the endoplasmic reticulum (ER), protein-disulfide isomerase (PDI) catalyzes the oxidation and isomerization of disulfide bonds and is re-oxidized by an endoplasmic reticulum oxidoreductase (ERO). The elucidation of ERO function was greatly aided by the genetic analysis of two ero mutants, whose impairment results from point mutations in the FAD binding domain of the Ero protein. The ero1-1 and ero1-2 yeast strains have conditional and dithiothreitol-sensitive phenotypes, but the effects of the mutations on the behavior of Ero proteins has not been reported. Here, we show that these Gly to Ser and His to Tyr mutations do not prevent the dimerization of Ero1 or the non-covalent interaction of Ero1 with PDI. However, the Gly to Ser mutation abolishes disulfide-dependent PDI-Ero1 heterodimers. Both the Gly to Ser and His to Tyr mutations make Ero1 susceptible to misoxidation and aggregation, particularly during a temperature or redox stress. We conclude that the Ero FAD binding domain is critical for conformational stability, allowing Ero proteins to withstand stress conditions that cause client proteins to misfold.
The ER (endoplasmic reticulum) is the site of protein folding for all eukaryotic secreted and plasma membrane proteins. Disulphide bonds are formed in many of these proteins through a dithiol-disulphide exchange chain comprising two types of protein catalysts: PDI (protein disulphide-isomerase) and ERO (ER oxidoreductase) proteins. This review will examine what we know about ERO function, and will then consider ERO interactions and their implications for mammalian oxidative protein folding.
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