Heme-Biosynthetic Porphobilinogen Deaminase Protects Aspergillus nidulans from Nitrosative Stress

Zhou, Shengmin; Narukami, Toshiaki; Nameki, Misuzu; Ozawa, Tomoko; Kamimura, Yosuke; Hoshino, Takayuki; Takaya, Naoki

doi:10.1128/aem.06195-11

Cited by 27 publications

(26 citation statements)

References 44 publications

(58 reference statements)

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“…Identification of a novel nitrosative stress tolerance gene RIB1. In order to isolate genes involved in nitrosative stress tolerance, the screening was performed in acidified medium (pH 5.5) containing NaNO 2 , as previous studies reported 26,27 . It was previously shown that nitrite induces S-nitrosylation of proteins under acidic condition 28 .…”

Section: Resultsmentioning

confidence: 99%

A Novel Mechanism for Nitrosative Stress Tolerance Dependent on GTP Cyclohydrolase II Activity Involved in Riboflavin Synthesis of Yeast

Anam

Nasuno

2020

Sci Rep

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The biological functions of nitric oxide (NO) depend on its concentration, and excessive levels of NO induce various harmful situations known as nitrosative stress. Therefore, organisms possess many kinds of strategies to regulate the intracellular no concentration and/or to detoxify excess no. Here, we used genetic screening to identify a novel nitrosative stress tolerance gene, RIB1, encoding GTP cyclohydrolase II (GTPCH2), which catalyzes the first step in riboflavin biosynthesis. Our further analyses demonstrated that the GTPCH2 enzymatic activity of Rib1 is essential for RIB1-dependent nitrosative stress tolerance, but that riboflavin itself is not required for this tolerance. Furthermore, the reaction mixture of a recombinant purified Rib1 was shown to quench NO or its derivatives, even though formate or pyrophosphate, which are byproducts of the Rib1 reaction, did not, suggesting that the reaction product of Rib1, 2,5-diamino-6-(5-phospo-d-ribosylamino)-pyrimidin-4(3 H)-one (DARP), scavenges NO or its derivatives. Finally, it was revealed that 2,4,5-triamino-1H-pyrimidin-6-one, which is identical to a pyrimidine moiety of DARP, scavenged NO or its derivatives, suggesting that DARP reacts with n 2 o 3 generated via its pyrimidine moiety. Nitric oxide (NO) is a small signaling molecule that plays various roles in a number of biological processes 1,2. In mammalian cells, NO is generally produced by three different isoforms of NO synthase (NOS) from l-arginine and NADPH 3. NOS consists of the oxygenase domain responsible for oxidation of l-arginine and the reductase domain which transfers electrons from NADPH to the oxygenase domain 4. Some Gram-positive bacteria have enzymes called bacterial NOS (bNOS), which is homologous to the oxygenase domain of NOS, and which exerts its NOS activity via interaction with uncertain reductase proteins 5. On the other hand, nitrate and nitrite serve as NO sources in plants, in which nitrate and nitrite are reduced to NO by nitrate reductase and nitrite reductase, respectively 6. Nitrite is also reduced to NO by heme-containing proteins including hemoglobin or molybdopterin proteins such as xanthine oxidase via their nitrite reductase activity 7,8. Furthermore, reduction of nitrite to NO is also catalyzed by the mitochondrial respiratory activity complex III and/or IV 9. NO activates soluble guanylyl cyclase (sGC) by binding to the heme in sGC. Activated sGC releases cyclic GMP, which is a second messenger leading to the relaxation of smooth muscle cells in mammals 10. Additionally, NO induces the posttranslational modification of proteins, such as S-nitrosation. S-nitrosation is formed via the reaction of NO with thiyl radical or between NO + , which is one electron oxidized form of NO, and the thiol group of cysteine residues in the target protein 11. Thiol group also undergoes S-nitrosation via transnitrosation, in which NO + group is transferred from a sulfur atom in nitrosothiol compound to that in a target thiol compound. The NO-responsive transcription factor OxyR is a...

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Section: Resultsmentioning

confidence: 99%

A Novel Mechanism for Nitrosative Stress Tolerance Dependent on GTP Cyclohydrolase II Activity Involved in Riboflavin Synthesis of Yeast

Anam

Nasuno

2020

Sci Rep

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“…In addition to the flavohemoglobins, other proteins have also been found to be involved in the detoxification of NO. For example, the porphobilinogen deaminase hemC acts by promoting the activity of the flavohemoglobins through an unknown mechanism, while the NO-inducible nitrosothionein ntpA scavenges NO through S-nitrosylation in A. nidulans (Zhou et al 2012 , 2013 ). A S-nitrosoglutathione (GSNO) reductase converts GSNO into ammonia and oxidized glutathione (GSSG) in Cryptococcus neoformans and Magnaporthe oryzae (de Jesus-Berrios et al 2003 ; Zhang et al 2015b ).…”

Section: No Homeostasis In Fungimentioning

confidence: 99%

Nitric oxide in fungi: is there NO light at the end of the tunnel?

Cánovas

Marcos

et al. 2016

Curr Genet

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Nitric oxide (NO) is a remarkable gaseous molecule with multiple and important roles in different organisms, including fungi. However, the study of the biology of NO in fungi has been hindered by the lack of a complete knowledge on the different metabolic routes that allow a proper NO balance, and the regulation of these routes. Fungi have developed NO detoxification mechanisms to combat nitrosative stress, which have been mainly characterized by their connection to pathogenesis or nitrogen metabolism. However, the progress on the studies of NO anabolic routes in fungi has been hampered by efforts to disrupt candidate genes that gave no conclusive data until recently. This review summarizes the different roles of NO in fungal biology and pathogenesis, with an emphasis on the alternatives to explain fungal NO production and the recent findings on the involvement of nitrate reductase in the synthesis of NO and its regulation during fungal development.

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“…NOD activity has been described in the yeast Sa. cerevisiae (Liu et al ., ), Candida albicans (Ullmann et al ., ), Cryptococcus neoformans (de Jesus‐Berrios et al ., ), A. oryzae (Zhou et al ., ), A. nidulans (Zhou et al ., ) and B. cinerea (Turrion‐Gomez et al ., ). Flavohaemoglobins exhibit a dioxygenase activity and contain three domains: a globin domain, a FAD‐binding domain and a NAD(P)‐binding domain.…”

Section: Nitrosative Stress Response In Fungimentioning

confidence: 99%

Nitric oxide: an effective weapon of the plant or the pathogen?

Arasimowicz‐Jelonek

Floryszak‐Wieczorek

2013

Molecular Plant Pathology

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SUMMARYAn explosion of research in plant nitric oxide (NO) biology during the last two decades has revealed that NO is a key signal involved in plant development, abiotic stress responses and plant immunity. During the course of evolutionary changes, microorganisms parasitizing plants have developed highly effective offensive strategies, in which NO also seems to be implicated. NO production has been demonstrated in several plant pathogens, including fungi, but the origin of NO seems to be as puzzling as in plants. So far, published studies have been spread over multiple species of pathogenic microorganisms in various developmental stages; however, the data clearly indicate that pathogen-derived NO is an important regulatory molecule involved not only in developmental processes, but also in pathogen virulence and its survival in the host. This review also focuses on the search for potential mechanisms by which pathogens convert NO messages into a physiological response or detoxify both endo-and exogenous NO. Finally, taking into account the data available from model bacteria and yeast, a basic draft for the mode of NO action in phytopathogenic microorganisms is proposed.

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Heme-Biosynthetic Porphobilinogen Deaminase Protects Aspergillus nidulans from Nitrosative Stress

Cited by 27 publications

References 44 publications

A Novel Mechanism for Nitrosative Stress Tolerance Dependent on GTP Cyclohydrolase II Activity Involved in Riboflavin Synthesis of Yeast

A Novel Mechanism for Nitrosative Stress Tolerance Dependent on GTP Cyclohydrolase II Activity Involved in Riboflavin Synthesis of Yeast

Nitric oxide in fungi: is there NO light at the end of the tunnel?

Nitric oxide: an effective weapon of the plant or the pathogen?

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