Your search keyword '"oxidative protein folding"' showing total 14 results

1. Oxidative protein folding fidelity and redoxtasis in the endoplasmic reticulum.

Author

Wang, Lei and Wang, Chih-chen

Subjects

*PROTEIN folding, *PROTEIN disulfide isomerase, *POST-translational modification, *EUKARYOTIC cells, *DIVISION of labor, *HOMEOSTASIS

Abstract

In eukaryotic cells, oxidative protein folding occurs in the lumen of the endoplasmic reticulum (ER), catalyzed by ER sulfhydryl oxidase 1 (Ero1) and protein disulfide isomerase (PDI). The efficiency and fidelity of oxidative protein folding are vital for the function of secretory cells. Here, we summarize oxidative protein folding in yeast, plants, and mammals, and discuss how the conformation and activity of human Ero1-PDI machinery is regulated through various post-translational modifications (PTMs). We propose that oxidative protein folding fidelity and ER redox homeostasis are maintained by both the precise control of Ero1 oxidase activity and the division of labor between PDI family members. We also discuss how deregulated Ero1-PDI functions contribute to human diseases and can be leveraged for therapeutic interventions. The endoplasmic reticulum (ER) sulfhydryl oxidase 1 (Ero1) and protein disulfide isomerase (PDI) family constitute a conserved and pivotal pathway through which oxidative protein folding is catalyzed in the ER of eukaryotic cells. Loss of Ero1 activity in different species causes intolerance to reductive stress, while loss of a PDI protein usually results in the failure of native disulfide formation. The conformation and activity of the human Ero1-PDI machinery is regulated by various PTMs, and therefore this machine sensitively responds to redox fluctuations in the ER. Different proteins of the PDI family exhibit a different division of labor during oxidative protein folding and work synergistically to guarantee efficient and faithful disulfide formation. Deregulated Ero1-PDI functions contribute to various human diseases, including diabetes, cancers, and cardiovascular diseases, and therefore Ero1-PD1 may be a target for therapeutic interventions. [ABSTRACT FROM AUTHOR]

Published

2023

2. Peroxiredoxin 4 deficiency induces accelerated ovarian aging through destroyed proteostasis in granulosa cells.

Author

Zou, Xiaofei, Liang, Xiuru, Dai, Wangjuan, Zhu, Ting, Wang, Chaoyi, Zhou, Yutian, Qian, Yi, Yan, Zhengjie, Gao, Chao, Gao, Li, Cui, Yugui, Liu, Jiayin, and Meng, Yan

Subjects

*GRANULOSA cells, *CELLULAR aging, *HORMONE receptors, *PROTEIN folding, *FOLLICLE-stimulating hormone, *ENDOPLASMIC reticulum

Abstract

Ovarian aging, a complex and challenging concern within the realm of reproductive medicine, is associated with reduced fertility, menopausal symptoms and long-term health risks. Our previous investigation revealed a correlation between Peroxiredoxin 4 (PRDX4) and human ovarian aging. The purpose of this research was to substantiate the protective role of PRDX4 against ovarian aging and elucidate the underlying molecular mechanism in mice. In this study, a Prdx4 −/− mouse model was established and it was observed that the deficiency of PRDX4 led to only an accelerated decline of ovarian function in comparison to wild-type (WT) mice. The impaired ovarian function observed in this study can be attributed to an imbalance in protein homeostasis, an exacerbation of endoplasmic reticulum stress (ER stress), and ultimately an increase in apoptosis of granulosa cells. Furthermore, our research reveals a noteworthy decline in the expression of Follicle-stimulating hormone receptor (FSHR) in aging Prdx4 −/− mice, especially the functional trimer, due to impaired disulfide bond formation. Contrarily, the overexpression of PRDX4 facilitated the maintenance of protein homeostasis, mitigated ER stress, and consequently elevated E2 levels in a simulated KGN cell aging model. Additionally, the overexpression of PRDX4 restored the expression of the correct spatial conformation of FSHR, the functional trimer. In summary, our research reveals the significant contribution of PRDX4 in delaying ovarian aging, presenting a novel and promising therapeutic target for ovarian aging from the perspective of endoplasmic reticulum protein homeostasis. • Granulosa cell endoplasmic reticulum proteostasis is pivotal for ovarian aging. • PRDX4 protects against ovarian aging by sustaining granulosa cell ER proteostasis. • Deficiency of PRDX4 has a detrimental impact on the expression of FSHR. [ABSTRACT FROM AUTHOR]

Published

2024

3. ‘Something in the way she moves’: The functional significance of flexibility in the multiple roles of protein disulfide isomerase (PDI).

Author

Freedman, Robert B., Desmond, Jasmine L., Byrne, Lee J., Heal, Jack W., Howard, Mark J., Sanghera, Narinder, Walker, Kelly L., Wallis, A. Katrine, Wells, Stephen A., Williamson, Richard A., and Römer, Rudolf A.

Subjects

*PROTEIN disulfide isomerase, *ENDOPLASMIC reticulum, *OXIDATION-reduction reaction, *CATALYSTS, *LIGAND binding (Biochemistry)

Abstract

Protein disulfide isomerase (PDI) has diverse functions in the endoplasmic reticulum as catalyst of redox transfer, disulfide isomerization and oxidative protein folding, as molecular chaperone and in multi-subunit complexes. It interacts with an extraordinarily wide range of substrate and partner proteins, but there is only limited structural information on these interactions. Extensive evidence on the flexibility of PDI in solution is not matched by any detailed picture of the scope of its motion. A new rapid method for simulating the motion of large proteins provides detailed molecular trajectories for PDI demonstrating extensive changes in the relative orientation of its four domains, great variation in the distances between key sites and internal motion within the core ligand-binding domain. The review shows that these simulations are consistent with experimental evidence and provide insight into the functional capabilities conferred by the extensive flexible motion of PDI. [ABSTRACT FROM AUTHOR]

Published

2017

4. Unconventional Targeting of a Thiol Peroxidase to the Mitochondrial Intermembrane Space Facilitates Oxidative Protein Folding.

Author

Kritsiligkou, Paraskevi, Chatzi, Afroditi, Charalampous, Georgia, Jr.Mironov, Aleksandr, Grant, Chris M., and Tokatlidis, Kostas

Abstract

Summary Thiol peroxidases are conserved hydrogen peroxide scavenging and signaling molecules that contain redox-active cysteine residues. We show here that Gpx3, the major H 2 O 2 sensor in yeast, is present in the mitochondrial intermembrane space (IMS), where it serves a compartment-specific role in oxidative metabolism. The IMS-localized Gpx3 contains an 18-amino acid N-terminally extended form encoded from a non-AUG codon. This acts as a mitochondrial targeting signal in a pathway independent of the hitherto known IMS-import pathways. Mitochondrial Gpx3 interacts with the Mia40 oxidoreductase in a redox-dependent manner and promotes efficient Mia40-dependent oxidative protein folding. We show that cells lacking Gpx3 have aberrant mitochondrial morphology, defective protein import capacity, and lower inner membrane potential, all of which can be rescued by expression of a mitochondrial-only form of Gpx3. Together, our data reveal a novel role for Gpx3 in mitochondrial redox regulation and protein homeostasis. [ABSTRACT FROM AUTHOR]

Published

2017

5. Oxidative folding in the mitochondrial intermembrane space: A regulated process important for cell physiology and disease.

Author

Chatzi, Afroditi, Manganas, Phanee, and Tokatlidis, Kostas

Subjects

*MITOCHONDRIAL membranes, *IRON-sulfur compounds, *MITOCHONDRIAL physiology, *CELL respiration, *PROTEIN folding, *MITOCHONDRIAL pathology

Abstract

Mitochondria are fundamental organelles with a complex internal architecture that fulfill important diverse functions including iron–sulfur cluster assembly and cell respiration. Intense work for more than 30 years has identified the key protein import components and the pathways involved in protein targeting and assembly. More recently, oxidative folding has been discovered as one important mechanism for mitochondrial proteostasis whilst several human disorders have been linked to this pathway. We describe the molecular components of this pathway in view of their putative redox regulation and we summarize available evidence on the connections of these pathways to human disorders. [ABSTRACT FROM AUTHOR]

Published

2016

6. Physiological and pathological views of peroxiredoxin 4.

Author

Fujii, Junichi, Ikeda, Yoshitaka, Kurahashi, Toshihiro, and Homma, Takujiro

Subjects

*PEROXIREDOXINS, *THIOREDOXIN, *HYDROGEN peroxide, *EXTRACELLULAR enzymes, *MAMMALIAN cell cycle

Abstract

Peroxiredoxins (PRDXs) form an enzyme family that exhibits peroxidase activity using electrons from thioredoxin and other donor molecules. As the signaling roles of hydrogen peroxide in response to extracellular stimuli have emerged, the involvement of PRDX in the hydrogen peroxide-mediated signaling has become evident. Among six PRDX members in mammalian cells, PRDX4 uniquely possesses a hydrophobic signal peptide at the amino terminus, and, hence, it undergoes either secretion or retention by the endoplasmic reticulum (ER) lumen. The role of PRDX4 as a sulfoxidase in ER is now attracting much attention regarding the oxidative protein folding of nascent proteins. Contrary to this role in the ER, the functional significance of PRDX4 in the extracellular milieu is virtually unknown despite its implications as a biomarker under pathological conditions in some diseases. Other than its systemically expressed form, a variant form of PRDX4 is transcribed from the upstream promoter/exon 1 of the systemic promoter/exon 1 and is uniquely expressed in sexually matured testes. Circumstantial evidence, together with deduced functions from the systemic form, suggests that there are potential roles for testicular PRDX4 in the reproductive processes such as the regulation of hormonal signals and the oxidative packaging of sperm chromatin. Elucidation of these PRDX4 functions under in vivo situations is expected to show the whole picture of how PRDX4 has evolved in multicellular organisms. [ABSTRACT FROM AUTHOR]

Published

2015

7. Structures and functions of protein disulfide isomerase family members involved in proteostasis in the endoplasmic reticulum.

Author

Okumura, Masaki, Kadokura, Hiroshi, and Inaba, Kenji

Subjects

*PROTEIN disulfide isomerase, *ENDOPLASMIC reticulum, *HYDROGEN peroxide, *CHEMICAL bonds, *PROTEIN folding

Abstract

The endoplasmic reticulum (ER) is an essential cellular compartment in which an enormous number of secretory and cell surface membrane proteins are synthesized and subjected to cotranslational or posttranslational modifications, such as glycosylation and disulfide bond formation. Proper maintenance of ER protein homeostasis (sometimes termed proteostasis) is essential to avoid cellular stresses and diseases caused by abnormal proteins. Accumulating knowledge of cysteine-based redox reactions catalyzed by members of the protein disulfide isomerase (PDI) family has revealed that these enzymes play pivotal roles in productive protein folding accompanied by disulfide formation, as well as efficient ER-associated degradation accompanied by disulfide reduction. Each of PDI family members forms a protein–protein interaction with a preferential partner to fulfill a distinct function. Multiple redox pathways that utilize PDIs appear to function synergistically to attain the highest quality and productivity of the ER, even under various stress conditions. This review describes the structures, physiological functions, and cooperative actions of several essential PDIs, and provides important insights into the elaborate proteostatic mechanisms that have evolved in the extremely active and stress-sensitive ER. [ABSTRACT FROM AUTHOR]

Published

2015

8. Protein disulfide–isomerase, a folding catalyst and a redox-regulated chaperone.

Author

Wang, Lei, Wang, Xi, and Wang, Chih-chen

Subjects

*PROTEIN disulfide isomerase, *PROTEIN folding, *CHEMICAL bonds, *OXIDOREDUCTASES, *ENDOPLASMIC reticulum, *X-ray scattering

Abstract

Protein disulfide–isomerase (PDI) was the first protein-folding catalyst to be characterized, half a century ago. It plays critical roles in a variety of physiological events by displaying oxidoreductase and redox-regulated chaperone activities. This review provides a brief history of the identification of PDI as both an enzyme and a molecular chaperone and of the recent advances in studies on the structure and dynamics of PDI, the substrate binding and release, and the cooperation with its partners to catalyze oxidative protein folding and maintain ER redox homeostasis. In this review, we highlight the structural features of PDI, including the high interdomain flexibility, the multiple binding sites, the two synergic active sites, and the redox-dependent conformational changes. [ABSTRACT FROM AUTHOR]

Published

2015

9. ERO1: A protein disulfide oxidase and H2O2 producer.

Author

Zito, Ester

Subjects

*PROTEIN disulfide isomerase, *PROTEIN folding, *EUKARYOTIC cells, *ENDOPLASMIC reticulum, *FREE radicals

Abstract

Oxidative protein folding in the endoplasmic reticulum (ER) is an essential function of eukaryotic cells that requires the relaying of electrons between the proteinaceous components of the pathway. During this process, protein disulfide isomerase (PDI) chaperones oxidatively fold their client proteins before endoplasmic reticulum oxireductin 1 (ERO1) oxidase transfers electrons from the reduced PDI to the terminal acceptor, which is usually molecular oxygen and is subsequently reduced to H 2 O 2 . ERO1 function is essential for disulfide bond formation in yeast, whereas in mammals its function is compensated for by alternative pathways. ERO1 activity is allosterically and transcriptionally regulated by the ER unfolded protein response (UPR). The ER stress-induced upregulation of ERO1 and other genes contributes to a cell’s ability to cope with ER stress as a result of an adaptive homeostatic response, but the stress persists if a “maladaptive UPR” fails to reestablish ER homeostasis. As the oxidative activity of ERO1 is related to the production of H 2 O 2 and consequently burdens cells with potentially toxic reactive oxygen species, deregulated ERO1 activity is likely to impair cell fitness under certain conditions of severe ER stress and may therefore lead to a change from an adaptive to a maladaptive UPR. This review summarizes the evidence of the double-edged sword activity of ERO1 by highlighting its role as a protein disulfide oxidase and H 2 O 2 producer. [ABSTRACT FROM AUTHOR]

Published

2015

10. The H2O2-sensitive HyPer protein targeted to the endoplasmic reticulum as a mirror of the oxidizing thiol–disulfide milieu

Author

Mehmeti, Ilir, Lortz, Stephan, and Lenzen, Sigurd

Subjects

*HYDROGEN peroxide, *ENDOPLASMIC reticulum, *OXIDATION of thiols, *PANCREATIC beta cells, *PROTEIN folding, *PEROXIREDOXINS

Abstract

Abstract: Oxidative protein folding in the endoplasmic reticulum (ER) is associated with the formation of native disulfide bonds, which inevitably results in the formation of hydrogen peroxide (H2O2). Particularly in pancreatic β-cells with their high secretory activity and extremely low antioxidant capacity, the H2O2 molecules generated during oxidative protein folding could represent a significant oxidative burden. Therefore this study was conducted to elucidate the H2O2 generation during disulfide bond formation in insulin-producing RINm5F cells by targeting and specifically expressing the H2O2-sensitive biosensor HyPer in the ER (ER-HyPer). In addition the influence of overexpression of the H2O2-metabolizing ER-resident peroxiredoxin IV (PRDXIV) on H2O2 levels was examined. The ER-HyPer fluorescent protein was completely oxidized, whereas HyPer expressed in cytosol, peroxisomes, and mitochondria was prevalently in the reduced state, indicating a high basal H2O2 concentration in the ER lumen. These results could also be confirmed in non-insulin-producing COS-7 cells. Overexpression of PRDXIV in RINm5F cells effectively protected against H2O2-mediated toxicity; however, it did not affect the fluorescence signal of ER-HyPer. Moreover, the inhibition of de novo protein synthesis and the associated H2O2 generation by cycloheximide had no influence on the ER-HyPer redox state. Taken together, these findings strongly suggest that the H2O2-sensitive biosensor reflects exclusively the oxidative milieu in the ER and not the H2O2 concentration in the ER lumen. [Copyright &y& Elsevier]

Published

2012

11. Oxidative protein folding in the endoplasmic reticulum: Tight links to the mitochondria-associated membrane (MAM)

Author

Simmen, Thomas, Lynes, Emily M., Gesson, Kevin, and Thomas, Gary

Subjects

*PROTEIN folding, *ENDOPLASMIC reticulum, *MITOCHONDRIA, *METABOLITES, *OXIDATIVE stress, *APOPTOSIS, *MOLECULAR chaperones, *CELL membranes

Abstract

Abstract: The production of secretory proteins at the ER (endoplasmic reticulum) depends on a ready supply of energy and metabolites as well as the close monitoring of the chemical conditions that favor oxidative protein folding. ER oxidoreductases and chaperones fold nascent proteins into their export-competent three-dimensional structure. Interference with these protein folding enzymes leads to the accumulation of unfolded proteins within the ER lumen, causing an acute organellar stress that triggers the UPR (unfolded protein response). The UPR increases the transcription of ER chaperones commensurate with the load of newly synthesized proteins and can protect the cell from ER stress. Persistant stress, however, can force the UPR to commit cells to undergo apoptotic cell death, which requires the emptying of ER calcium stores. Conversely, a continuous ebb and flow of calcium occurs between the ER and mitochondria during resting conditions on a domain of the ER that forms close contacts with mitochondria, the MAM (mitochondria-associated membrane). On the MAM, ER folding chaperones such as calnexin and calreticulin and oxidoreductases such as ERp44, ERp57 and Ero1α regulate calcium flux from the ER through reversible, calcium and redox-dependent interactions with IP3Rs (inositol 1,4,5-trisphophate receptors) and with SERCAs (sarcoplasmic/endoplasmic reticulum calcium ATPases). During apoptosis progression and depending on the identity of the ER chaperone and oxidoreductase, these interactions increase or decrease, suggesting that the extent of MAM targeting of ER chaperones and oxidoreductases could shift the readout of ER–mitochondria calcium exchange from housekeeping to apoptotic. However, little is known about the cytosolic factors that mediate the on/off interactions between ER chaperones and oxidoreductases with ER calcium channels and pumps. One candidate regulator is the multi-functional molecule PACS-2 (phosphofurin acidic cluster sorting protein-2). Recent studies suggest that PACS-2 mediates localization of a mobile pool of calnexin to the MAM in addition to regulating homeostatic ER calcium signaling as well as MAM integrity. Together, these findings suggest that cytosolic, membrane and lumenal proteins combine to form a two-way switch that determines the rate of protein secretion by providing ions and metabolites and that appears to participate in the pro-apoptotic ER–mitochondria calcium transfer. [Copyright &y& Elsevier]

Published

2010

12. A unique leucine-valine adhesive motif supports structure and function of protein disulfide isomerase P5 via dimerization.

Author

Okumura, Masaki, Kanemura, Shingo, Matsusaki, Motonori, Kinoshita, Misaki, Saio, Tomohide, Ito, Dai, Hirayama, Chihiro, Kumeta, Hiroyuki, Watabe, Mai, Amagai, Yuta, Lee, Young-Ho, Akiyama, Shuji, and Inaba, Kenji

Subjects

*PROTEIN disulfide isomerase, *PROTEIN structure, *LEUCINE zippers, *DIMERIZATION, *ADHESIVES, *X-ray crystallography, *ISOMERASES

Abstract

P5, also known as PDIA6, is a PDI family member involved in the ER quality control. Here, we revealed that P5 dimerizes via a unique adhesive motif contained in the N-terminal thioredoxin-like domain. Unlike conventional leucine zipper motifs with leucine residues every two helical turns on ∼30-residue parallel α helices, this adhesive motif includes periodic repeats of leucine/valine residues at the third or fourth position spanning five helical turns on 15-residue anti-parallel α helices. The P5 dimerization interface is further stabilized by several reciprocal salt bridges and C-capping interactions between protomers. A monomeric P5 mutant with the impaired adhesive motif showed structural instability and local unfolding, and behaved as aberrant proteins that induce the ER stress response. Disassembly of P5 to monomers compromised its ability to inactivate IRE1α via intermolecular disulfide bond reduction and its Ca2+-dependent regulation of chaperone function in vitro. Thus, the leucine-valine adhesive motif supports structure and function of P5. [Display omitted] • P5 dimerizes via a unique leucine-valine adhesive motif in the first Trx-like domain • The adhesive motif is radically different from conventional coiled-coil motifs • The dimeric structure serves to promote P5-mediated inactivation of IRE1α • Ca2+-binding regions and Ca2+-dependent functional regulation were clarified for P5 Using SAXS and X-ray crystallography, Okumura et al. determined the structure of a protein disulfide isomerase P5, in which the N-terminal thioredoxin-like domain dimerizes via a unique leucine-valine adhesive motif. A monomeric P5 mutant displayed structural instability and compromised functions, indicating the structural and functional essentiality of this motif. [ABSTRACT FROM AUTHOR]

Published

2021

13. Generating disulfides with the Quiescin-sulfhydryl oxidases

Author

Heckler, Erin J., Rancy, Pumtiwitt C., Kodali, Vamsi K., and Thorpe, Colin

Subjects

*OXIDASES, *ENZYMES, *PROTEINS, *ENZYMOLOGY

Abstract

Abstract: The Quiescin-sulfhydryl oxidase (QSOX) family of flavoenzymes catalyzes the direct and facile insertion of disulfide bonds into unfolded reduced proteins with concomitant reduction of oxygen to hydrogen peroxide. This review discusses the chemical mechanism of these enzymes and the involvement of thioredoxin and flavin-binding domains in catalysis. The variability of CxxC motifs in the QSOX family is highlighted and attention is drawn to the steric factors that may promote efficient thiol/disulfide exchange during oxidative protein folding. The varied cellular location of these multi-domain sulfhydryl oxidases is reviewed and potential intracellular and extracellular roles are summarized. Finally, this review identifies important unresolved questions concerning this ancient family of sulfhydryl oxidases. [Copyright &y& Elsevier]

Published

2008

14. The Protein Disulfide Isomerase Family: from proteostasis to pathogenesis.

Author

Matsusaki, Motonori, Kanemura, Shingo, Kinoshita, Misaki, Lee, Young-Ho, Inaba, Kenji, and Okumura, Masaki

Subjects

*PROTEIN disulfide isomerase, *ISOMERASES, *PROTEIN folding, *ENDOPLASMIC reticulum, *MOLECULAR chaperones

Abstract

In mammalian cells, nearly one-third of proteins are inserted into the endoplasmic reticulum (ER), where they undergo oxidative folding and chaperoning assisted by approximately 20 members of the protein disulfide isomerase family (PDIs). PDIs consist of multiple thioredoxin-like domains and recognize a wide variety of proteins via highly conserved interdomain flexibility. Although PDIs have been studied intensely for almost 50 years, exactly how they maintain protein homeostasis in the ER remains unknown, and is important not only for fundamental biological understanding but also for protein misfolding- and aggregation-related pathophysiology. Herein, we review recent advances in structural biology and biophysical approaches that explore the underlying mechanism by which PDIs fulfil their distinct functions to promote productive protein folding and scavenge misfolded proteins in the ER, the primary factory for efficient production of the secretome. Unlabelled Image • Oxidative folding and chaperoning in the ER are assisted by ~20 PDI family members. • PDIs recognize and act on clients via conserved interdomain flexibility. • Exactly how PDIs maintain protein homeostasis remains to be uncovered. • Aberrant PDI activity leads to protein misfolding- and aggregation-related pathology. [ABSTRACT FROM AUTHOR]

Published

2020