High-Resolution Crystal Structure of Manganese Peroxidase:  Substrate and Inhibitor Complexes<sup>,</sup>

Sundaramoorthy, Munirathinam; Youngs, Heather; Gold, Michael H.; Poulos, T.L.

doi:10.1021/bi047318e

Cited by 76 publications

(59 citation statements)

References 47 publications

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“…The Mn(II) is located in a cation-binding site at the surface of the protein and coordinates to the carboxylate oxygens of Glu35, Glu39, and Asp179, the heme propionate oxygen, and two water oxygens. The site has considerable flexibility to accommodate the binding of a wide variety of metal ions [119,120]. Two heptacoordinate structural calcium ions, one tightly bound on the proximal side and the other bound on the distal side of the heme, are important for thermal stabilization of the active site of the enzyme [119].…”

Section: Molecular Structurementioning

confidence: 99%

Structure and Action Mechanism of Ligninolytic Enzymes

Wong

2008

Appl Biochem Biotechnol

699

457

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Lignin is the most abundant renewable source of aromatic polymer in nature, and its decomposition is indispensable for carbon recycling. It is chemically recalcitrant to breakdown by most organisms because of the complex, heterogeneous structure. The white-rot fungi produce an array of extracellular oxidative enzymes that synergistically and efficiently degrade lignin. The major groups of ligninolytic enzymes include lignin peroxidases, manganese peroxidases, versatile peroxidases, and laccases. The peroxidases are heme-containing enzymes with catalytic cycles that involve the activation by H2O2 and substrate reduction of compound I and compound II intermediates. Lignin peroxidases have the unique ability to catalyze oxidative cleavage of C-C bonds and ether (C-O-C) bonds in non-phenolic aromatic substrates of high redox potential. Manganese peroxidases oxidize Mn(II) to Mn(III), which facilitates the degradation of phenolic compounds or, in turn, oxidizes a second mediator for the breakdown of non-phenolic compounds. Versatile peroxidases are hybrids of lignin peroxidase and manganese peroxidase with a bifunctional characteristic. Laccases are multi-copper-containing proteins that catalyze the oxidation of phenolic substrates with concomitant reduction of molecular oxygen to water. This review covers the chemical nature of lignin substrates and focuses on the biochemical properties, molecular structures, reaction mechanisms, and related structures/functions of these enzymes.

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Section: Molecular Structurementioning

confidence: 99%

Structure and Action Mechanism of Ligninolytic Enzymes

Wong

2008

Appl Biochem Biotechnol

699

457

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“…Mn 2+ performs the role of mediator for MnP. High resolution crystal structure has revealed that MnP catalyzes the peroxide dependent oxidation of Mn 2+ to Mn 3+ and Mn 3+ is released from the enzyme in complex with oxalate or with other chelators (Sundramoorthy et al 2005). Along with pyrophosphate, the various Mn 2+ chelators that enhance the activity are malonate, oxalate, L-tartrate, oxaloacetate, Lmalate, and methylmalonate (Mäkelä et al 2005).…”

Section: Enzyme System Of White Rot Fungimentioning

confidence: 99%

Recent developments in biodegradation of industrial pollutants by white rot fungi and their enzyme system

et al. 2008

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Increasing discharge and improper management of liquid and solid industrial wastes have created a great concern among industrialists and the scientific community over their economic treatment and safe disposal. White rot fungi (WRF) are versatile and robust organisms having enormous potential for oxidative bioremediation of a variety of toxic chemical pollutants due to high tolerance to toxic substances in the environment. WRF are capable of mineralizing a wide variety of toxic xenobiotics due to non-specific nature of their extracellular lignin mineralizing enzymes (LMEs). In recent years, a lot of work has been done on the development and optimization of bioremediation processes using WRF, with emphasis on the study of their enzyme systems involved in biodegradation of industrial pollutants. Many new strains have been identified and their LMEs isolated, purified and characterized. In this review, we have tried to cover the latest developments on enzyme systems of WRF, their low molecular mass mediators and their potential use for bioremediation of industrial pollutants.

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“…(1a) (1b) Other examples of such mononuclear redox-active enzymes include the manganese peroxidase responsible for lignin degradation by white-rot fungus [10][11][12]; a unique Mndependent form of lipoxygenase [13][14][15][16]; oxalate decarboxylase [17,18]; as well as an extradiol catechol dioxygenase [19][20][21]. …”

Section: Mn-containing Biological Systemsmentioning

confidence: 99%

“…Many Mn-dependent enzymes take advantage o f the rich redox chemistry available to the metal, accessing the +2, +3, +4, and perhaps even the +5 oxidation states during their turnover. For example, Mn-superoxide dismutase (MnSOD), which detoxifies the cell of the superoxide radical , cycles between the Mn(II) and Mn(III) oxidation states via the ping-pong type mechanism shown below [5][6][7][8][9].(1a) (1b) Other examples of such mononuclear redox-active enzymes include the manganese peroxidase responsible for lignin degradation by white-rot fungus [10][11][12]; a unique Mndependent form of lipoxygenase [13][14][15][16]; oxalate decarboxylase [17,18]; as well as an extradiol catechol dioxygenase [19][20][21]. …”

mentioning

confidence: 99%

Multifrequency pulsed EPR studies of biologically relevant manganese(II) complexes

et al. 2007

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Electron paramagnetic resonance studies at multiple frequencies (MF EPR) can provide detailed electronic structure descriptions of unpaired electrons in organic radicals, inorganic complexes, and metalloenzymes. Analysis of these properties aids in the assignment of the chemical environment surrounding the paramagnet and provides mechanistic insight into the chemical reactions in which these systems take part. Herein, we present results from pulsed EPR studies performed at three different frequencies (9, 31, and 130 GHz) on [Mn(II)(H 2 O) 6 ] 2+ , Mn(II) adducts with the nucleotides ATP and GMP, and the Mn(II)-bound form of the hammerhead ribozyme (MnHH). Through line shape analysis and interpretation of the zero-field splitting values derived from successful simulations of the corresponding continuous-wave and field-swept echodetected spectra, these data are used to exemplify the ability of the MF EPR approach in distinguishing the nature of the first ligand sphere. A survey of recent results from pulsed EPR, as well as pulsed electron-nuclear double resonance and electron spin echo envelope modulation spectroscopic studies applied to Mn(II)-dependent systems, is also presented. Mn-Containing Biological SystemsManganese operates as a cofactor in numerous proteins, serving both catalytic and structural roles [1][2][3][4]. Many Mn-dependent enzymes take advantage o f the rich redox chemistry available to the metal, accessing the +2, +3, +4, and perhaps even the +5 oxidation states during their turnover. For example, Mn-superoxide dismutase (MnSOD), which detoxifies the cell of the superoxide radical , cycles between the Mn(II) and Mn(III) oxidation states via the ping-pong type mechanism shown below [5][6][7][8][9].(1a) (1b) Other examples of such mononuclear redox-active enzymes include the manganese peroxidase responsible for lignin degradation by white-rot fungus [10][11][12]; a unique Mndependent form of lipoxygenase [13][14][15][16]; oxalate decarboxylase [17,18]; as well as an extradiol catechol dioxygenase [19][20][21]. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author ManuscriptIn order to help minimize kinetic and thermodynamic penalties associated with electron transfer events and the execution of chemical reactions, two or more metal centers can be coupled together to provide active sites capable of conducting multiple electrons while still operating within a physiologically accessible range of reduction potentials [22]. Only three such examples of redox-active polynuclear Mn enzymes are known: Mn-catalase that disproportionates hydrogen peroxide [23][24][25][26]; a Mn form of ribonucleotide reductase (Mn-RNR) [27,28]; and, arguably the most recognized Mn-dependent enzyme, the photosynthetic core of green plants, algae, and certain cyanobacteria termed photosystem II (PSII) [29,30]. Through a series of photoinitiated electron transfer events, oxidizing equivalents are stored on the tetranuclear Mn core of PSII -the oxygen-evolving complex (OEC) -which then extracts four electr...

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High-Resolution Crystal Structure of Manganese Peroxidase: Substrate and Inhibitor Complexes^,

Cited by 76 publications

References 47 publications

Structure and Action Mechanism of Ligninolytic Enzymes

Structure and Action Mechanism of Ligninolytic Enzymes

Recent developments in biodegradation of industrial pollutants by white rot fungi and their enzyme system

Multifrequency pulsed EPR studies of biologically relevant manganese(II) complexes

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High-Resolution Crystal Structure of Manganese Peroxidase: Substrate and Inhibitor Complexes,

Cited by 76 publications

References 47 publications

Structure and Action Mechanism of Ligninolytic Enzymes

Structure and Action Mechanism of Ligninolytic Enzymes

Recent developments in biodegradation of industrial pollutants by white rot fungi and their enzyme system

Multifrequency pulsed EPR studies of biologically relevant manganese(II) complexes

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Product

Resources

About

High-Resolution Crystal Structure of Manganese Peroxidase: Substrate and Inhibitor Complexes^,