Kenta Iwai scite author profile

Reactive oxygen species (ROS) generated during cellular metabolism are toxic to cells. As a result, cells must be able to identify ROS as a stress signal and induce stress response pathways that protect cells from ROS toxicity. Recently, peroxiredoxin (Prx)-induced relays of disulfide bond formation have been identified in budding yeast, namely the disulfide bond formation of Yap1, a crucial transcription factor for oxidative stress response, by a specific Prx Gpx3 and by a major Prx Tsa1. Here, we show that an atypical-type Prx Ahp1 can act as a receptor for alkylhydroperoxides, resulting in activation of the Cad1 transcription factor that is homologous to Yap1. We demonstrate that Ahp1 is required for the formation of intermolecular Cad1 disulfide bond(s) in both an in vitro redox system and in cells treated with alkylhydroperoxide. Furthermore, we found that Cad1-dependent transcriptional activation of the HSP82 gene is dependent on Ahp1. Our results suggest that, although the Gpx3-Yap1 pathway contributes more strongly to resistance than the Ahp1-Cad1 pathway, the Ahp1-induced activation of Cad1 can function as a defense system against stress induced by alkylhydroperoxides, possibly including lipid peroxides. Thus, the Prx family of proteins have an important role in determining peroxide response signals and in transmitting the signals to specific target proteins by inducing disulfide bond formation.

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HSC90 is required for nascent hepatitis C virus core protein stability in yeast cells

Kubota¹,

Inayoshi²,

Satoh³

et al. 2012

FEBS Letters

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Edited by Hans-Dieter KlenkKeywords: Hepatitis C virus (HCV) core protein Yeast growth defect caused by core protein HSP90 inhibitor Stability nascent polypeptide HSC90 High-throughput screening a b s t r a c t Hepatitis C virus core protein (Core) contributes to HCV pathogenicity. Here, we demonstrate that Core impairs growth in budding yeast. We identify HSP90 inhibitors as compounds that reduce intracellular Core protein level and restore yeast growth. Our results suggest that HSC90 (Hsc82) may function in the protection of the nascent Core polypeptide against degradation in yeast and the C-terminal region of Core corresponding to the organelle-interaction domain was responsible for Hsc82-dependent stability. The yeast system may be utilized to select compounds that can direct the C-terminal region to reduce the stability of Core protein.

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Redox-dependent Regulation of Gluconeogenesis by a Novel Mechanism Mediated by a Peroxidatic Cysteine of Peroxiredoxin

Irokawa

Tachibana

Watanabe

et al. 2016

Sci Rep

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Peroxiredoxin is an abundant peroxidase, but its non-peroxidase function is also important. In this study, we discovered that Tsa1, a major peroxiredoxin of budding yeast cells, is required for the efficient flux of gluconeogenesis. We found that the suppression of pyruvate kinase (Pyk1) via the interaction with Tsa1 contributes in part to gluconeogenic enhancement. The physical interactions between Pyk1 and Tsa1 were augmented during the shift from glycolysis to gluconeogenesis. Intriguingly, a peroxidatic cysteine in the catalytic center of Tsa1 played an important role in the physical Tsa1-Pyk1 interactions. These interactions are enhanced by exogenous H2O2 and by endogenous reactive oxygen species, which is increased during gluconeogenesis. Only the peroxidatic cysteine, but no other catalytic cysteine of Tsa1, is required for efficient growth during the metabolic shift to obtain maximum yeast growth (biomass). This Tsa1 function is separable from the peroxidase function as an antioxidant. This is the first report to demonstrate that peroxiredoxin has a novel nonperoxidase function as a redox-dependent target modulator and that pyruvate kinase is modulated via an alternative mechanism.

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Synthetic fluorescent probes capable of selective recognition of 3′-overhanging nucleotides for siRNA delivery imaging

Sato

Iwai

et al. 2015

Chem. Commun.

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Fluorescence Imaging of siRNA Delivery by Peptide Nucleic Acid-based Probe

Sato

Iwai

et al. 2015

ANAL. SCI.

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We report on the use of a peptide nucleic acid (PNA)-based fluorescent probe for the analysis of siRNA delivery to living cells. The probe, Py-AA-TO, possesses thiazole orange (TO) and pyrene moieties in the C-and N-termini of PNA, and can function as a light-up probe capable of selective binding to 3′-overhanging nucleotides of target siRNAs. The affinitylabeling of the siRNAs with Py-AA-TO facilitates fluorescence imaging of cellular uptake of polymer-based carriers encapsulating the siRNAs (polyplexes) through endocytosis and subsequent sequestration into lysosome. In addition, flow cytometric measurements reveal that the monitoring of Py-AA-TO fluorescence inside the cells is successfully applicable to the analysis of the polyplex disassembly. These promising functions of Py-AA-TO are presented and discussed as a basis for the design of molecular probes for fluorescent imaging and quantitative analysis of the siRNA delivery process.

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Kenta Iwai

Peroxiredoxin Ahp1 Acts as a Receptor for Alkylhydroperoxides to Induce Disulfide Bond Formation in the Cad1 Transcription Factor

HSC90 is required for nascent hepatitis C virus core protein stability in yeast cells

Redox-dependent Regulation of Gluconeogenesis by a Novel Mechanism Mediated by a Peroxidatic Cysteine of Peroxiredoxin

Synthetic fluorescent probes capable of selective recognition of 3′-overhanging nucleotides for siRNA delivery imaging

Fluorescence Imaging of siRNA Delivery by Peptide Nucleic Acid-based Probe

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