Direct electron transfer of Trametes hirsuta laccase adsorbed at unmodified nanoporous gold electrodes

Salaj-Kośla, Urszula; Pöller, Sascha; Schuhmann, Wolfgang; Shleev, Sergey; Magner, Edmond

doi:10.1016/j.bioelechem.2012.11.001

Cited by 61 publications

(63 citation statements)

References 44 publications

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“…An example of this was demonstrated by the Butt group in 2001, where NarGH NR (free of its NarI component) was studied at an electrode surface and NO Figure 11. Duca et al demonstrated the co-immobilization of NarGHI NR and Pt/Rh nanoparticles for the reduction of NO À 3 to NH 3 on a hybrid electrode, as reported in [50]. The 'Griess' assay was used to detect and quantify NO …”

Section: Inhibition Of Enzymatic Activitymentioning

confidence: 99%

Direct enzymatic bioelectrocatalysis: differentiating between myth and reality

Milton

Minteer

2017

J. R. Soc. Interface.

165

148

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Enzymatic bioelectrocatalysis is being increasingly exploited to better understand oxidoreductase enzymes, to develop minimalistic yet specific biosensor platforms, and to develop alternative energy conversion devices and bioelectrosynthetic devices for the production of energy and/or important chemical commodities. In some cases, these enzymes are able to electronically communicate with an appropriately designed electrode surface without the requirement of an electron mediator to shuttle electrons between the enzyme and electrode. This phenomenon has been termed direct electron transfer or direct bioelectrocatalysis. While many thorough studies have extensively investigated this fascinating feat, it is sometimes difficult to differentiate desirable enzymatic bioelectrocatalysis from electrocatalysis deriving from inactivated enzyme that may have also released its catalytic cofactor. This article will review direct bioelectrocatalysis of several oxidoreductases, with an emphasis on experiments that provide support for direct bioelectrocatalysis versus denatured enzyme or dissociated cofactor. Finally, this review will conclude with a series of proposed control experiments that could be adopted to discern successful direct electronic communication of an enzyme from its denatured counterpart.

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Section: Inhibition Of Enzymatic Activitymentioning

confidence: 99%

Direct enzymatic bioelectrocatalysis: differentiating between myth and reality

Milton

Minteer

2017

J. R. Soc. Interface.

165

148

View full text Add to dashboard Cite

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“…This suggests that halides bind to the TNC center, with the biggest ions having restricted access to the trinuclear cluster. [65][66][67] An accurate mechanism and the precise binding site are, however, still being established, especially as a function of pH. [38,39] Furthermore, BODs are quite stable at neutral pH.…”

Section: Enzymes For O 2 Reductionmentioning

confidence: 99%

Biohydrogen for a New Generation of H₂/O₂ Biofuel Cells: A Sustainable Energy Perspective

et al. 2014

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Among sustainable alternatives to fossil fuel, proton exchange membrane fuel cells are promising devices that deliver electricity from hydrogen and oxygen, producing only water. The transformation of the fuel and oxidant however relies on rare‐metal catalysts. H2/O2 enzymatic biofuel cells thus emerge as sustainable biotechnological devices in which chemical catalysts are replaced by hydrogenases at the anode and multicopper oxidases at the cathode. This review discusses the recent breakthroughs and the limitations in all the components of H2/O2 biofuel cells: 1) Catalytic mechanisms involved in multicopper oxidases and hydrogenases, in addition to the new potential of enzymes from the biodiversity pool, which exhibit outstanding properties. 2) The molecular basis for oriented enzyme immobilization on the electrochemical interfaces as a prerequisite for a fast direct electron‐transfer rate. 3) The requirement for 3D networks to enhance current densities. 4) The production of H2 from biomass. 5) The history of H2/O2 biofuel cells and recent devices, which also highlights the remaining issues that will allow the use of such devices in low‐power applications.

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“…Trametes hirsute laccase (ThLc) showed well-defined DET at unmodified NPG electrodes, in 15 contrast to the absence of a response at unmodified polycrystalline gold electrodes [99]. [100].…”

Section: Multi-copper Oxidasesmentioning

confidence: 99%