Bleach Activates a Redox-Regulated Chaperone by Oxidative Protein Unfolding

Winter, Jeannette; Ilbert, Marianne; Graf, Paul C. F.; Özcelik, Dennis; Jakob, Ursula

doi:10.1016/j.cell.2008.09.024

Cited by 334 publications

(382 citation statements)

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“…(4,6,38). As has been shown for many other proteins, incubation of FGN or LDL with hypochlorite induces their self-aggregation into high-molecular mass complexes (1,39,40). In contrast, α 2 M is able to withstand high concentrations of hypochlorite without self-aggregating (Fig.…”

Section: Resultsmentioning

confidence: 91%

“…Our results support the conclusion that α 2 M is a specialized chaperone that prevents the extracellular accumulation of misfolded and potentially pathogenic proteins, particularly during innate immune system activity. molecular chaperone | inflammation | protein folding | clearance H ypochlorite, a potent oxidant produced by immune cells through the myeloperoxidase-H 2 O 2 -chloride system, kills invading microbes predominately by inducing the misfolding and aggregation of their proteins (1). The effects of hypochlorite, however, are nonspecific; therefore, when generated in vivo, the host organism suffers collateral damage (reviewed in refs.…”

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confidence: 99%

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Hypochlorite-induced structural modifications enhance the chaperone activity of human α₂-macroglobulin

Wyatt

Kumita

Mifsud

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Hypochlorite, an oxidant generated in vivo by the innate immune system, kills invading pathogens largely by inducing the misfolding of microbial proteins. Concomitantly, the nonspecific activity of hypochlorite also damages host proteins, and the accumulation of damaged (misfolded) proteins is implicated in the pathology of a variety of debilitating human disorders (e.g., Alzheimer's disease, atherosclerosis, and arthritis). It is well-known that cells respond to oxidative stress by up-regulating proteostasis machinery, but the direct activation of mammalian chaperones by hypochlorite has not, to our knowledge, been previously reported. In this study, we show that hypochlorite-induced modifications of human α 2 -macroglobulin (α 2 M) markedly increase its chaperone activity by generating species, particularly dimers formed by dissociation of the native tetramer, which have enhanced surface hydrophobicity. Moreover, dimeric α 2 M is generated in whole-blood plasma in the presence of physiologically relevant amounts of hypochlorite. The chaperone activity of hypochlorite-modified α 2 M involves the formation of stable soluble complexes with misfolded client proteins, including heat-denatured enzymes, oxidized fibrinogen, oxidized LDL, and native or oxidized amyloid β-peptide (Aβ 1-42 ). Here, we show that hypochlorite-modified α 2 M delivers its misfolded cargo to lipoprotein receptors on macrophages and reduces Aβ 1-42 neurotoxicity. Our results support the conclusion that α 2 M is a specialized chaperone that prevents the extracellular accumulation of misfolded and potentially pathogenic proteins, particularly during innate immune system activity. molecular chaperone | inflammation | protein folding | clearance H ypochlorite, a potent oxidant produced by immune cells through the myeloperoxidase-H 2 O 2 -chloride system, kills invading microbes predominately by inducing the misfolding and aggregation of their proteins (1). The effects of hypochlorite, however, are nonspecific; therefore, when generated in vivo, the host organism suffers collateral damage (reviewed in refs. 2 and 3). During inflammation, hypochlorite production is accompanied by additional stresses, which are themselves capable of inducing protein misfolding (e.g., increased temperature and lowered pH); it is, therefore, not surprising that, in a large number of diseases [e.g., atherosclerosis (4), Alzheimer's disease (5, 6), age-related macular degeneration (7), and arthritis (8)], inflammatory pathology is associated with the accumulation of misfolded proteins.α 2 -Macroglobulin (α 2 M) is a highly abundant secreted protein that is best known for its ability to trap proteases (9); α 2 M can, however, interact with a broad range of molecules, and consequently, many other biological roles have been suggested, including targeting cytokines for clearance, sequestration of zinc, and opsonization of bacteria (reviewed in ref. 10). Furthermore, α 2 M has been identified as one of a small number of abundant extracellular chaperones (11). Although our un...

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Section: Resultsmentioning

confidence: 91%

mentioning

confidence: 99%

Hypochlorite-induced structural modifications enhance the chaperone activity of human α₂-macroglobulin

Wyatt

Kumita

Mifsud

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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“…They govern the functions of various proteins, including redox-sensitive chaperone Hsp33 and calcium/calmodulin-dependent protein kinase CaMKII, through regulation of disulfide bond formation or oxidation of methionine residues (49,50). Oxidizing agents enhance the guanyltransferase activity of flavivirus NS5 or alphavirus nsP1 in vitro (51).…”

Section: Discussionmentioning

confidence: 99%

Harnessing host ROS-generating machinery for the robust genome replication of a plant RNA virus

Hyodo

Hashimoto

Kuchitsu

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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As sessile organisms, plants have to accommodate to rapid changes in their surrounding environment. Reactive oxygen species (ROS) act as signaling molecules to transduce biotic and abiotic stimuli into plant stress adaptations. It is established that a respiratory burst oxidase homolog B of Nicotiana benthamiana (NbRBOHB) produces ROS in response to microbe-associated molecular patterns to inhibit pathogen infection. Plant viruses are also known as causative agents of ROS induction in infected plants; however, the function of ROS in plant-virus interactions remains obscure. Here, we show that the replication of red clover necrotic mosaic virus (RCNMV), a plant positive-strand RNA [(+)RNA] virus, requires NbRBOHB-mediated ROS production. The RCNMV replication protein p27 plays a pivotal role in this process, redirecting the subcellular localization of NbRBOHB and a subgroup II calcium-dependent protein kinase of N. benthamiana (NbCDPKiso2) from the plasma membrane to the p27-containing intracellular aggregate structures. p27 also induces an intracellular ROS burst in an RBOH-dependent manner. NbCDPKiso2 was shown to be an activator of the p27-triggered ROS accumulations and to be required for RCNMV replication. Importantly, this RBOH-derived ROS is essential for robust viral RNA replication. The need for RBOHderived ROS was demonstrated for the replication of another (+) RNA virus, brome mosaic virus, suggesting that this characteristic is true for plant (+)RNA viruses. Collectively, our findings revealed a hitherto unknown viral strategy whereby the host ROS-generating machinery is diverted for robust viral RNA replication.positive-strand RNA virus | viral RNA replication | reactive oxygen species | respiratory burst oxidase homolog | calcium-dependent protein kinase P lants have evolved complicated and sophisticated strategies to survive environmental changes. The rapid generation of reactive oxygen species (ROS) is one of the hallmarks of plant responses to various biotic and abiotic stresses (1). Plant NADPH oxidase, termed RBOHs (respiratory burst oxidase homologs), localize at the plasma membrane (PM) and intracellular compartments including the Golgi apparatus (2, 3) and play a key role in ROS production upon the perception of environmental stresses (4). In Nicotiana benthamiana, an RBOHB (NbRBOHB) plays important roles in ROS production triggered by microbe-associated molecular patterns (MAMPs), such as bacterial flagellin and fungal chitin, and facilitates plant immunity against biotrophic pathogens including an oomycete pathogen Phytophthola infestance and tobacco mosaic virus (5-8). RBOH activity is tightly and coordinately regulated posttranslationally [e.g., activation by Ca 2+ , phosphatidic acid (PA), G proteins, or protein kinases] (9-12). It has recently been shown that receptor-like cytoplasmic kinases and calciumdependent protein kinases (CDPKs) regulate RBOHs activity via direct phosphorylation or through modulating regulators of RBOHs during recognition of MAMPs via corresponding surface-loca...

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“…Other studies reported oxidation-induced loss of secondary structure in several proteins (9,36,51,52). A recent study suggested oxidative unfolding and consequent aggregation as a major mechanism of HOCl-mediated protein inactivation (40). As sulfoxides are more hydrophilic than Met residues, their formation can change the overall surface charge of a protein (8,38).…”

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confidence: 99%

Synergistic Roles of Helicobacter pylori Methionine Sulfoxide Reductase and GroEL in Repairing Oxidant-damaged Catalase

Mahawar¹,

Tran

Sharp

et al. 2011

Journal of Biological Chemistry

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Hypochlorous acid (HOCl) produced via the enzyme myeloperoxidase is a major antibacterial oxidant produced by neutrophils, and Met residues are considered primary amino acid targets of HOCl damage via conversion to Met sulfoxide. Met sulfoxide can be repaired back to Met by methionine sulfoxide reductase (Msr). Catalase is an important antioxidant enzyme; we show it constitutes 4 -5% of the total Helicobacter pylori protein levels. msr and katA strains were about 14-and 4-fold, respectively, more susceptible than the parent to killing by the neutrophil cell line HL-60 cells. Catalase activity of an msr strain was much more reduced by HOCl exposure than for the parental strain. Treatment of pure catalase with HOCl caused oxidation of specific MS-identified Met residues, as well as structural changes and activity loss depending on the oxidant dose. Treatment of catalase with HOCl at a level to limit structural perturbation (at a catalase/HOCl molar ratio of 1:60) resulted in oxidation of six identified Met residues. Msr repaired these residues in an in vitro reconstituted system, but no enzyme activity could be recovered. However, addition of GroEL to the Msr repair mixture significantly enhanced catalase activity recovery. Neutrophils produce large amounts of HOCl at inflammation sites, and bacterial catalase may be a prime target of the host inflammatory response; at high concentrations of HOCl (1:100), we observed loss of catalase secondary structure, oligomerization, and carbonylation. The same HOCl-sensitive Met residue oxidation targets in catalase were detected using chloramine-T as a milder oxidant.

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Bleach Activates a Redox-Regulated Chaperone by Oxidative Protein Unfolding

Cited by 334 publications

References 33 publications

Hypochlorite-induced structural modifications enhance the chaperone activity of human α₂-macroglobulin

Hypochlorite-induced structural modifications enhance the chaperone activity of human α₂-macroglobulin

Harnessing host ROS-generating machinery for the robust genome replication of a plant RNA virus

Synergistic Roles of Helicobacter pylori Methionine Sulfoxide Reductase and GroEL in Repairing Oxidant-damaged Catalase

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Bleach Activates a Redox-Regulated Chaperone by Oxidative Protein Unfolding

Cited by 334 publications

References 33 publications

Hypochlorite-induced structural modifications enhance the chaperone activity of human α2-macroglobulin

Hypochlorite-induced structural modifications enhance the chaperone activity of human α2-macroglobulin

Harnessing host ROS-generating machinery for the robust genome replication of a plant RNA virus

Synergistic Roles of Helicobacter pylori Methionine Sulfoxide Reductase and GroEL in Repairing Oxidant-damaged Catalase

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Hypochlorite-induced structural modifications enhance the chaperone activity of human α₂-macroglobulin

Hypochlorite-induced structural modifications enhance the chaperone activity of human α₂-macroglobulin