Shigefumi Tsukamoto scite author profile

All plants examined to date possess non-symbiotic hemoglobin whose physiological role remains unclear. The present study explored the catalytic function of three representative classes of the plant hemoglobin from Arabidopsis thaliana: AtGLB1, AtGLB2, and AtGLB3. Purified recombinant proteins of these hemoglobins displayed hydrogen peroxide-dependent oxidation of several peroxidase substrates that was sensitive to cyanide, revealing intrinsic peroxidase-like activity. In the presence of nitrite and hydrogen peroxide, AtGLB1 was the most efficient at mediating tyrosine nitration of its own and other proteins via the formation of reactive nitrogen species as a result of nitrite oxidation. AtGLB1 mRNA significantly accumulated in Arabidopsis seedlings exposed to nitrite, supporting the physiological relevance of its function to nitrite and nitritederived reactive nitrogen species.

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A Novel cis-Element That Is Responsive to Oxidative Stress Regulates Three Antioxidant Defense Genes in Rice

Tsukamoto

Morita

Hirano

et al. 2005

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All organisms have defense systems against oxidative stress that include multiple genes of antioxidant defense. These genes are induced by reactive oxygen species under condition of oxidative stress. In this study, we found that a 28-bp motif is conserved on the promoter regions of three antioxidant defense genes in rice (Oryza sativa): cytosolic superoxide dismutase (sodCc1), cytosolic thioredoxin (trxh), and glutaredoxin (grx). We demonstrated that the 28-bp sequence acts as a cis-element responsive to oxidative stress by transient expression assay and designated it as CORE (coordinate regulatory element for antioxidant defense). The CORE was activated by methyl viologen treatment and induced a 3.1-fold increase in expression of the reporter gene, but it did not respond to hydrogen peroxide. The expressions of the sodCc1, trxh, and grx genes were coordinately induced by methyl viologen, suggesting that multiple genes involved in antioxidant defense are controlled by a common regulatory mechanism via CORE. Application of the mitogen-activated protein kinase kinase inhibitor caused the constitutive induction of the sodCc1, trxh, and grx genes and the activation of CORE without methyl viologen treatment. These results indicate that a mitogen-activated protein kinase cascade is involved in the gene regulation mediated by CORE.

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Functional complementation in yeast reveals a protective role of chloroplast 2‐Cys peroxiredoxin against reactive nitrogen species

et al. 2003

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SummaryThe importance of nitric oxide (NO) as a signaling molecule to various plant physiological and pathophysiological processes is becoming increasingly evident. However, little is known about how plants protect themselves from nitrosative and oxidative damage mediated by NO and NO-derived reactive nitrogen species (RNS). Peroxynitrite, the product of the reaction between NO and superoxide anion, is considered to play a central role in RNS-induced cytotoxicity, as a result of its potent ability to oxidize diverse biomolecules. Employing heterologous expression in bacteria and yeast, we investigated peroxynitrite-scavenging activity in plants of 2-Cys peroxiredoxin (2CPRX), originally identified as a hydroperoxide-reducing peroxidase that is ubiquitously distributed among organisms. The putative mature form of a chloroplastlocalized 2CPRX from Arabidopsis thaliana was overproduced in Escherichia coli as an amino-terminally hexahistidine-tagged fusion protein. The purified recombinant 2CPRX, which was catalytically active as peroxidase, efficiently prevented the peroxynitrite-induced oxidation of a sensitive compound. We also examined in vivo the ability of the Arabidopsis 2CPRX to complement the 2CPRX deficiency of a Saccharomyces cerevisiae mutant. Functional expression in the mutant strain of the Arabidopsis 2CPRX not only increased cellular tolerance to hydrogen peroxide, but also complemented the hypersensitive growth defect induced by nitrite-mediated cytotoxicity. The complemented cells significantly enhanced the capacity to reduce RNS-mediated oxidative damages. The results presented here demonstrate a new role of plant 2CPRX as a critical determinant of the resistance to RNS, and support the existence of a plant enzymatic basis for RNS metabolism.

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Differences in intron-mediated enhancement of gene expression by the first intron of cytosolic superoxide dismutase gene from rice in monocot and dicot plants

Morita

Tsukamoto

Sakamoto

et al. 2012

Plant Biotechnology

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Introns have an enhancing e ect on gene expression known as intron-mediated enhancement in various organisms, including plants. Although the mechanism of the enhancement is largely unknown, most enhancing introns are rst introns. In this study, we examined whether the rst intron of rice superoxide dismutase sodCc2 gene has an enhancing e ect in rice and other plant species. A transient expression assay revealed that the sodCc2 intron elevated reporter gene expression in rice, wheat, and maize, but not in Arabidopsis and tobacco, indicating that the sodCc2 intron has an enhancing e ect in monocot but not in dicot plants. To nd the putative signal sequences responsible for the enhancement, we carried out an in silico search and found two motifs conserved among the sodCc2 intron and 11 enhancing introns previously known in rice. e motifs contain a consensus sequence, GATCTG, which also exists in the conserved motif found in Arabidopsis enhancing introns. Our results suggest that common motifs are conserved between rice and Arabidopsis enhancing introns.

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