O<sub>2</sub> and N<sub>2</sub>O Activation by Bi-, Tri-, and Tetranuclear Cu Clusters in Biology

Solomon, Edward I.; Sarangi, Ritimukta; Woertink, Julia S.; Augustine, Anthony J.; Yoon, Jungjoo; Ghosh, Santanu

doi:10.1021/ar600060t

Cited by 162 publications

(124 citation statements)

References 45 publications

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“…For example, pausing at H 2 O 2 relaxes the four-electron problem but introduces an overpotential requirement of up to 0.54 V in both directions (nevertheless, a lower cost than pausing at either radical state). Specific binding of the intermediate helps further: Indeed, spectroscopic studies of blue Cu oxidases have detected a peroxy-intermediate (37), and X-ray diffraction has revealed an O-O species coordinated between three Cu atoms (38) (see Scheme 1,5).…”

Section: •−mentioning

confidence: 99%

Reversibility and efficiency in electrocatalytic energy conversion and lessons from enzymes

Armstrong

Hirst²

2011

Proc. Natl. Acad. Sci. U.S.A.

318

294

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Enzymes are long established as extremely efficient catalysts. Here, we show that enzymes can also be extremely efficient electrocatalysts (catalysts of redox reactions at electrodes). Despite being large and electronically insulating through most of their volume, some enzymes, when attached to an electrode, catalyze electrochemical reactions that are otherwise extremely sluggish (even with the best synthetic catalysts) and require a large overpotential to achieve a useful rate. These enzymes produce high electrocatalytic currents, displayed in single bidirectional voltammetric waves that switch direction (between oxidation and reduction) sharply at the equilibrium potential for the substrate redox couple. Notoriously irreversible processes such as CO 2 reduction are thereby rendered electrochemically reversible-a consequence of molecular evolution responding to stringent biological drivers for thermodynamic efficiency. Enzymes thus set high standards for the catalysts of future energy technologies.electrocatalysis | catalysis | electrochemistry | electron transport | solar fuels A n electrocatalyst catalyzes a redox "half reaction" in which a chemical transformation is coupled to electron transfer at an electrode (1). The active sites of surface electrocatalysts such as platinum are integral to the electrode and contribute to the Fermi level, whereas molecular electrocatalysts are distinct entities with their own electronic and chemical properties. Molecular electrocatalysts can be attached to the electrode surface or diffuse freely in solution, but depend upon interfacial electron transfer (IET). Enzymes, a special category of molecular electrocatalysts, are distinguished by their extraordinary activities, yet limited by their size and fragility. Driven by industrial and technological needs for significant improvements in rates and efficiency, enzymes can provide crucial insights into the principles underpinning the design and performance of synthetic molecular electrocatalysts.The efficiency of enzyme catalysis is widely accepted (2-4): Enzymes have highly selective substrate binding sites, avoid releasing reactive intermediates, and decrease activation energies (here, substrate refers to the species being transformed, not the supporting material). Traditional definitions of enzyme efficiency focus on how closely the rate approaches diffusion control (4). Recently, electrochemistry has revealed a hitherto unquantified dimension in enzyme catalysis; many redox enzymes minimize the energy needed to drive a reaction-a quantity that is easily visualized electrochemically and that we refer to as the overpotential requirement. The energy efficiency of enzyme catalysis is expected because biology must fully exploit available energy resources and minimize energy losses.The performance of an electrocatalyst is readily visualized by cyclic voltammetry, a technique for driving reactions, measuring kinetics and thermodynamics, detecting activation/inactivation processes, and observing catalytic efficiency-all in a single...

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Section: •−mentioning

confidence: 99%

Reversibility and efficiency in electrocatalytic energy conversion and lessons from enzymes

Armstrong

Hirst²

2011

Proc. Natl. Acad. Sci. U.S.A.

318

294

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“…Dimeric copper sites play an important role in the activation of biological oxygen [2][3][4], and the study of structural and functional aspects of copper metalloenzymes via model systems is a subject of intense research [5][6][7][8][9][10]. A member of the family of dicopper proteins is catechol oxidase, which features a type 3 copper center with two proximate copper ions coordinated primarily by histidine donors [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Structural and spectroscopic studies of a model for catechol oxidase

et al. 2008

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A binuclear copper complex, [Cu 2 (BPMP) (OAc) 2 ][ClO 4 ]ÁH 2 O, has been prepared using the binucleating ligand 2,6-bis[bis(pyridin-2-ylmethylamino)methyl]-4-methylphenol (H-BPMP). The X-ray crystal structure reveals the copper centers to have a five-coordinate square pyramidal geometry, with the acetate ligands bound terminally. The bridging phenolate occupies the apical position of the square-based pyramids and magnetic susceptibility, electron paramagnetic resonance (EPR) and variable-temperature variable-field magnetic circular dichroism (MCD) measurements indicate that the two centers are very weakly antiferromagnetically coupled (J = -0.6 cm -1 ). Simulation of the dipole-dipole-coupled EPR spectrum showed that in solution the Cu-O-Cu angle was increased from 126°to 160°and that the internuclear distance was larger than that observed crystallographically. The high-resolution spectroscopic information obtained has been correlated with a detailed ligand-field analysis to gain insight into the electronic structure of the complex. Symmetry arguments have been used to demonstrate that the sign of the MCD is characteristic of the tetragonally elongated environment. The complex also displays catecholase activity (k cat = 15 ± 1.5 min -1 , K M = 6.4 ± 1.8 mM), which is compared with other dicopper catechol oxidase models.

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“…Therefore, two electrons must enter the enzyme and two protonation steps have to occur in order for the enzyme to return to its initial state. This is accomplished through efficient electron pathways [69][70][71].…”

Section: Nitrous Oxide Reductasementioning

confidence: 99%

Enzymatic activity mastered by altering metal coordination spheres

2008

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Metalloenzymes control enzymatic activity by changing the characteristics of the metal centers where catalysis takes place. The conversion between inactive and active states can be tuned by altering the coordination number of the metal site, and in some cases by an associated conformational change. These processes will be illustrated using heme proteins (cytochrome c nitrite reductase, cytochrome c peroxidase and cytochrome cd 1 nitrite reductase), non-heme proteins (superoxide reductase and [NiFe]-hydrogenase), and copper proteins (nitrite and nitrous oxide reductases) as examples. These examples catalyze electron transfer reactions that include atom transfer, abstraction and insertion.

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O₂ and N₂O Activation by Bi-, Tri-, and Tetranuclear Cu Clusters in Biology

Cited by 162 publications

References 45 publications

Reversibility and efficiency in electrocatalytic energy conversion and lessons from enzymes

Reversibility and efficiency in electrocatalytic energy conversion and lessons from enzymes

Structural and spectroscopic studies of a model for catechol oxidase

Enzymatic activity mastered by altering metal coordination spheres

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O2 and N2O Activation by Bi-, Tri-, and Tetranuclear Cu Clusters in Biology

Cited by 162 publications

References 45 publications

Reversibility and efficiency in electrocatalytic energy conversion and lessons from enzymes

Reversibility and efficiency in electrocatalytic energy conversion and lessons from enzymes

Structural and spectroscopic studies of a model for catechol oxidase

Enzymatic activity mastered by altering metal coordination spheres

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O₂ and N₂O Activation by Bi-, Tri-, and Tetranuclear Cu Clusters in Biology