Shoji Masui scite author profile

In the endoplasmic reticulum (ER) of eukaryotic cells, Ero1 flavoenzymes promote oxidative protein folding through protein disulphide isomerase (PDI), generating reactive oxygen species (hydrogen peroxide) as byproducts. Therefore, Ero1 activity must be strictly regulated to avoid futile oxidation cycles in the ER. Although regulatory mechanisms restraining Ero1a activity ensure that not all PDIs are oxidized, its specificity towards PDI could allow other resident oxidoreductases to remain reduced and competent to carry out isomerization and reduction of protein substrates. In this study, crystal structures of human Ero1a were solved in its hyperactive and inactive forms. Our findings reveal that human Ero1a modulates its oxidative activity by properly positioning regulatory cysteines within an intrinsically flexible loop, and by fine-tuning the electron shuttle ability of the loop through disulphide rearrangements. Specific PDI targeting is guaranteed by electrostatic and hydrophobic interactions of Ero1a with the PDI b 0 -domain through its substrate-binding pocket. These results reveal the molecular basis of the regulation and specificity of protein disulphide formation in human cells.

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Synergistic cooperation of PDI family members in peroxiredoxin 4-driven oxidative protein folding

Sato

Kojima

Okumura

et al. 2013

Sci Rep

126

153

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The mammalian endoplasmic reticulum (ER) harbors disulfide bond-generating enzymes, including Ero1α and peroxiredoxin 4 (Prx4), and nearly 20 members of the protein disulfide isomerase family (PDIs), which together constitute a suitable environment for oxidative protein folding. Here, we clarified the Prx4 preferential recognition of two PDI family proteins, P5 and ERp46, and the mode of interaction between Prx4 and P5 thioredoxin domain. Detailed analyses of oxidative folding catalyzed by the reconstituted Prx4–PDIs pathways demonstrated that, while P5 and ERp46 are dedicated to rapid, but promiscuous, disulfide introduction, PDI is an efficient proofreader of non-native disulfides. Remarkably, the Prx4-dependent formation of native disulfide bonds was accelerated when PDI was combined with ERp46 or P5, suggesting that PDIs work synergistically to increase the rate and fidelity of oxidative protein folding. Thus, the mammalian ER seems to contain highly systematized oxidative networks for the efficient production of large quantities of secretory proteins.

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A pH-Regulated Quality Control Cycle for Surveillance of Secretory Protein Assembly

et al. 2013

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SummaryTo warrant the quality of the secretory proteome, stringent control systems operate at the endoplasmic reticulum (ER)-Golgi interface, preventing the release of nonnative products. Incompletely assembled oligomeric proteins that are deemed correctly folded must rely on additional quality control mechanisms dedicated to proper assembly. Here we unveil how ERp44 cycles between cisGolgi and ER in a pH-regulated manner, patrolling assembly of disulfide-linked oligomers such as IgM and adiponectin. At neutral, ER-equivalent pH, the ERp44 carboxy-terminal tail occludes the substrate-binding site. At the lower pH of the cisGolgi, conformational rearrangements of this peptide, likely involving protonation of ERp44’s active cysteine, simultaneously unmask the substrate binding site and −RDEL motif, allowing capture of orphan secretory protein subunits and ER retrieval via KDEL receptors. The ERp44 assembly control cycle couples secretion fidelity and efficiency downstream of the calnexin/calreticulin and BiP-dependent quality control cycles.

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Molecular Bases of Cyclic and Specific Disulfide Interchange between Human ERO1α Protein and Protein-disulfide Isomerase (PDI)

Masui

Vavassori

Fagioli

et al. 2011

Journal of Biological Chemistry

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In the endoplasmic reticulum (ER) of human cells, ERO1␣ and protein-disulfide isomerase (PDI) constitute one of the major electron flow pathways that catalyze oxidative folding of secretory proteins. Specific and limited PDI oxidation by ERO1␣ is essential to avoid ER hyperoxidation. To investigate how ERO1␣ oxidizes PDI selectively among more than 20 ERresident PDI family member proteins, we performed docking simulations and systematic biochemical analyses. Our findings reveal that a protruding ␤-hairpin of ERO1␣ specifically interacts with the hydrophobic pocket present in the redox-inactive PDI b-domain through the stacks between their aromatic residues, leading to preferred oxidation of the C-terminal PDI a-domain. ERO1␣ associated preferentially with reduced PDI, explaining the stepwise disulfide shuttle mechanism, first from ERO1␣ to PDI and then from oxidized PDI to an unfolded polypeptide bound to its hydrophobic pocket. The interaction of ERO1␣ with ERp44, another PDI family member protein, was also analyzed. Notably, ERO1␣-dependent PDI oxidation was inhibited by a hyperactive ERp44 mutant that lacks the C-terminal tail concealing the substrate-binding hydrophobic regions. The potential ability of ERp44 to inhibit ERO1␣ activity may suggest its physiological role in ER redox and protein homeostasis.

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Radically Different Thioredoxin Domain Arrangement of ERp46, an Efficient Disulfide Bond Introducer of the Mammalian PDI Family

et al. 2014

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The mammalian endoplasmic reticulum (ER) contains a diverse oxidative protein folding network in which ERp46, a member of the protein disulfide isomerase (PDI) family, serves as an efficient disulfide bond introducer together with Peroxiredoxin-4 (Prx4). We revealed a radically different molecular architecture of ERp46, in which the N-terminal two thioredoxin (Trx) domains with positively charged patches near their peptide-binding site and the C-terminal Trx are linked by unusually long loops and arranged extendedly, forming an opened V-shape. Whereas PDI catalyzes native disulfide bond formation by the cooperative action of two mutually facing redox-active sites on folding intermediates bound to the central cleft, ERp46 Trx domains are separated, act independently, and engage in rapid but promiscuous disulfide bond formation during early oxidative protein folding. Thus, multiple PDI family members likely contribute to different stages of oxidative folding and work cooperatively to ensure the efficient production of multi-disulfide proteins in the ER.

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Shoji Masui

Crystal structures of human Ero1α reveal the mechanisms of regulated and targeted oxidation of PDI

Synergistic cooperation of PDI family members in peroxiredoxin 4-driven oxidative protein folding

A pH-Regulated Quality Control Cycle for Surveillance of Secretory Protein Assembly

Molecular Bases of Cyclic and Specific Disulfide Interchange between Human ERO1α Protein and Protein-disulfide Isomerase (PDI)

Radically Different Thioredoxin Domain Arrangement of ERp46, an Efficient Disulfide Bond Introducer of the Mammalian PDI Family

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