Plant Sulfite Oxidase as Novel Producer of H2O2

Hänsch, Robert; Lang, Christina; Riebeseel, Erik; Lindigkeit, Rainer; Geßler, Arthur; Rennenberg, Heinz; Mendel, Ralf R.

doi:10.1074/jbc.m513054200

Cited by 124 publications

(43 citation statements)

References 31 publications

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“…It has been shown that the molybdenum center of the plant enzyme reacts with O 2 directly, with H 2 O 2 as the ultimate product of the reaction. 313 It has subsequently been demonstrated, however, that O 2 •− is the immediate product of the reaction, and that H 2 O 2 is formed only indirectly by the spontaneous disproportionation of O 2 •−.314 The observed rate constant for the reaction of reduced enzyme with O 2 exhibits a linear dependence on [O 2 ] ( k ox = 5.3 × 10 4 M −1 s −1 at pH 8.0); given that the rate of reduction of the plant enzyme by sulfite exceeds that accessible by stopped-flow, 308 the oxidative half-reaction is clearly rate-limiting for overall turnover with the plant enzyme. Plant sulfite oxidase is localized in the peroxisome, and it is possible that the superoxide it generates is involved in antimicrobial generation of reactive oxygen species, although an appropriate source of sulfite to provide the reducing equivalents necessary for generation of a superoxide burst upon infection has not been identified.…”

Section: The Sulfite Oxidase Familymentioning

confidence: 99%

The Mononuclear Molybdenum Enzymes

2014

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Section: The Sulfite Oxidase Familymentioning

confidence: 99%

The Mononuclear Molybdenum Enzymes

2014

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“…In this process, substrate-derived electrons are transferred to molecular oxygen with formation of superoxide anions (Byrne et al, 2009) and hydrogen peroxides (Haensch et al, 2006). In the physiological context, SO represents a part of an intracellular sulfite homeostasis network required to prevent plant cells from the toxic effects of endogenously arising sulfite (Brychkova et al, 2007; Lang et al, 2007).…”

Section: Molybdenum Cofactor and Molybdenum-dependent Enzymesmentioning

confidence: 99%

Molybdenum metabolism in plants and crosstalk to iron

Bittner

2014

Front. Plant Sci.

134

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In the form of molybdate the transition metal molybdenum is essential for plants as it is required by a number of enzymes that catalyze key reactions in nitrogen assimilation, purine degradation, phytohormone synthesis, and sulfite detoxification. However, molybdate itself is biologically inactive and needs to be complexed by a specific organic pterin in order to serve as a permanently bound prosthetic group, the molybdenum cofactor, for the socalled molybdo-enyzmes. While the synthesis of molybdenum cofactor has been intensively studied, only little is known about the uptake of molybdate by the roots, its transport to the shoot and its allocation and storage within the cell. Yet, recent evidence indicates that intracellular molybdate levels are tightly controlled by molybdate transporters, in particular during plant development. Moreover, a tight connection between molybdenum and iron metabolisms is presumed because (i) uptake mechanisms for molybdate and iron affect each other, (ii) most molybdo-enzymes do also require iron-containing redox groups such as iron-sulfur clusters or heme, (iii) molybdenum metabolism has recruited mechanisms typical for iron-sulfur cluster synthesis, and (iv) both molybdenum cofactor synthesis and extramitochondrial iron-sulfur proteins involve the function of a specific mitochondrial ABC-type transporter.

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“…In bacteria, sulfite oxidation is often linked to energy-generating processes during chemolithotrophic growth on reduced sulfur compounds (2, 3), whereas both plant and vertebrate sulfite oxidases have been shown to detoxify sulfite arising from the degradation of methionine and cysteine and exposure to sulfur dioxide (4,5).…”

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Molecular Basis for Enzymatic Sulfite Oxidation

Bailey

Rapson

Johnson‐Winters

et al. 2009

Journal of Biological Chemistry

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Sulfite dehydrogenases (SDHs) catalyze the oxidation and detoxification of sulfite to sulfate, a reaction critical to all forms of life. Sulfite-oxidizing enzymes contain three conserved active site amino acids (Arg-55, His-57, and Tyr-236) that are crucial for catalytic competency. Here we have studied the kinetic and structural effects of two novel and one previously reported substitution (R55M, H57A, Y236F) in these residues on SDH catalysis. Both Arg-55 and His-57 were found to have key roles in substrate binding. An R55M substitution increased K m(sulfite)(app) by 2-3 orders of magnitude, whereas His-57 was required for maintaining a high substrate affinity at low pH when the imidazole ring is fully protonated. R55M has sulfate bound at the active site, a fact that coincides with a significant increase in the inhibitory effect of sulfate in SDH R55M . Thus, Arg-55 also appears to be involved in enabling discrimination between the substrate and product in SDH.Sulfite-oxidizing enzymes protect cells against potentially fatal damage to DNA and proteins caused by exposure to sulfite, and consequently they are found in all forms of life (1). In bacteria, sulfite oxidation is often linked to energy-generating processes during chemolithotrophic growth on reduced sulfur compounds (2, 3), whereas both plant and vertebrate sulfite oxidases have been shown to detoxify sulfite arising from the degradation of methionine and cysteine and exposure to sulfur dioxide (4, 5).All known sulfite-oxidizing enzymes belong to the same family of mononuclear molybdenum enzymes. Their active sites contain one molybdopterin unit per molybdenum atom, and these enzymes may also contain heme groups as accessory redox centers (6 -9). Examples of different types of sulfite-oxidizing molybdoenzymes are the homodimeric plant sulfite oxidase, which does not contain a heme group and uses oxygen as its preferred electron acceptor (9), the homodimeric chicken and human liver sulfite oxidases (CSO 3 and HSO, respectively) (10), which are also able to use oxygen as an electron acceptor, and the bacterial sulfite dehydrogenase (SDH) isolated from the soil bacterium Starkeya novella (11, 12), which cannot donate electrons directly to oxygen. Each monomer of CSO and HSO contains a heme b center in addition to the molybdenum center, and the redox centers are located within separate, flexibly linked domains of the same protein subunit. In contrast, the bacterial enzyme is a heterodimer where each subunit of the enzyme contains one redox center. The molybdopterin cofactor is located in the larger 40.2-kDa SorA subunit, and the c-type heme is located in the smaller, 8.8-kDa SorB subunit (12). The SDH quaternary structure thus differs clearly from that of the human and chicken sulfite oxidases.Crystal structures are available for plant sulfite oxidase, CSO, and the bacterial SDH (10,11,(13)(14)(15) and have revealed molecular details of the sulfite-oxidizing enzymes. In the CSO structure, the mobile heme b domain occupies a position too removed from the...

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Plant Sulfite Oxidase as Novel Producer of H2O2

Cited by 124 publications

References 31 publications

The Mononuclear Molybdenum Enzymes

The Mononuclear Molybdenum Enzymes

Molybdenum metabolism in plants and crosstalk to iron

Molecular Basis for Enzymatic Sulfite Oxidation

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