Controlling Redox Enzyme Orientation at Planar Electrodes

Hitaishi, Vivek Pratap; Clément, Romain; Bourassin, Nicolas; Baaden, Marc; Poulpiquet, Anne de; Sacquin-Mora, Sophie; Ciaccafava, Alexandre; Lojou, Élisabeth

doi:10.3390/catal8050192

Cited by 83 publications

(84 citation statements)

References 199 publications

(269 reference statements)

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“…We already described the contribution of microscopy to study enzyme orientation in a previous review . Therefore, we will here only briefly summarize the main articles.…”

Section: Enzyme Orientation At the Electrode Surfacementioning

confidence: 99%

“…Moreover, an effective electron coupling between the protein redox centers and the electrode is a key prerequisite to efficient devices. This latter point is not trivial due to the size of the molecules and their structural complexity . The enzyme activity relies on a redox active site mostly deeply buried in the enzyme dielectric structure, and sometimes accompanied by electronic relays that drive electrons between the active site and the surface of the molecule, which results in a huge anisotropy of enzyme electronic properties.…”

Section: Introductionmentioning

confidence: 99%

“…The enzyme activity relies on a redox active site mostly deeply buried in the enzyme dielectric structure, and sometimes accompanied by electronic relays that drive electrons between the active site and the surface of the molecule, which results in a huge anisotropy of enzyme electronic properties. The electronic communication between an enzyme and an electrode can be direct ( i. e . electrons tunnel directly from the enzyme active site or electron relays to the electrode or reciprocally) or indirect (the indirect electron transfer is also called “mediated electron transfer”) .…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Micro‐ and Nanoscopic Imaging of Enzymatic Electrodes: A Review

2019

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Redox enzymes, which catalyze electron transfer reactions in living organisms, can be used as selective and sensitive bioreceptors in biosensors, or as efficient catalysts in biofuel cells. In these bioelectrochemical devices, the enzymes are immobilized at a conductive surface, the electrode, with which they must be able to exchange electrons. Different physicochemical methods have been coupled to electrochemistry to characterize the enzyme‐modified electrochemical interface. In this Review, we summarize most efforts performed to investigate the enzymatic electrodes at the micro‐ and even nanoscale, thanks to microscopy techniques. Contrary to electrochemistry, which gives only a global information about all processes occurring at the electrode surface, microscopy offers a spatial resolution. Several techniques have been implemented; mostly scanning probe microscopies like atomic force microscopy, scanning tunneling microscopy, and scanning electrochemical microscopy, but also scanning electron microscopy and fluorescence microscopy. These studies demonstrate that various information can be obtained thanks to microscopy at different scales. Electrode imaging has been performed to confirm the presence of enzymes, to quantify and localize the biomolecules, but also to evaluate the morphology of immobilized enzymes, their possible conformation changes upon turnover, and their orientation at the electrode surface. Local redox activity has also been imaged and kinetics has been resolved.

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“…We already described the contribution of microscopy to study enzyme orientation in a previous review . Therefore, we will here only briefly summarize the main articles.…”

Section: Enzyme Orientation At the Electrode Surfacementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Micro‐ and Nanoscopic Imaging of Enzymatic Electrodes: A Review

2019

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“…One of the main issues that are addressed when investigating protein/surface interaction, is the matter of protein orientation. Controlled adsorption with ordered proteins is essential for devices such as biosensors, where antibodies should be immobilized with a specific orientation favoring the following antibody-antigen binding (2), or for bioelectrocatalysis devices (biofuel cells or bioreactors for electrosynthesis), where a correct enzyme orientation is essential for direct electron transfer between the adsorbed protein and the electrode (3,4). The adsorbed proteins' orientation depends on many factors, such as their charge, size or shape, the support properties, or external conditions like the temperature and pH (5).…”

Section: Introductionmentioning

confidence: 99%

Implicit modeling of the impact of adsorption on solid surfaces for protein mechanics and activity with a coarse-grain representation

Bourassin

Baaden

Lojou

et al. 2020

Preprint

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Surface immobilized enzymes play a key role in numerous biotechnological applications such as biosensors, biofuel cells or biocatalytic synthesis. As a consequence, the impact of adsorption on the enzyme structure, dynamics and function needs to be understood on the molecular level as it is critical for the improvement of these technologies. With this perspective in mind, we used a theoretical approach for investigating protein local flexibility on the residue scale that couples a simplified protein representation with an elastic network and Brownian Dynamics simulations. The protein adsorption on a solid surface is implicitly modeled via additional external constraints between the residues in contact with the surface. We first performed calculations on a redox enzyme, bilirubin oxidase (BOD) from M. verrucaria, to study the impact of adsorption on its mechanical properties. The resulting rigidity profiles show that, in agreement with the available experimental data, the mechanical variations observed in the adsorbed BOD will depend on its orientation and its anchor residues (i.e. residues that are in contact with the functionalized surface). Additional calculations on ribonuclease A and nitroreductase shed light on how seemingly stable adsorbed enzymes can nonetheless display an important decrease in their catalytic activity resulting from a perturbation of their mechanics and internal dynamics.

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“…Enzymes are routinely leveraged to enable unique applications throughout research, industrial production and molecular diagnostics as they are known to accelerate reactions by >10 17 fold [1]. Enzyme immobilization has been an area of great interest since it was first reported in 1916 [2], with many reviews available [3][4][5][6][7][8][9][10][11]. Immobilization is achieved by anchoring enzymes to or within solid supports in order to facilitate efficient separation from the reaction media in heterogeneous systems and increase the reusability of enzymes.…”

Section: Introductionmentioning

confidence: 99%

Enzyme Immobilization for Solid-Phase Catalysis

Fang

Zhang

et al. 2019

Catalysts

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The covalent immobilization of an enzyme to a solid support can broaden its applicability in various workflows. Immobilized enzymes facilitate catalyst re-use, adaptability to automation or high-throughput applications and removal of the enzyme without heat inactivation or reaction purification. In this report, we demonstrate a step-by-step procedure to carry out the bio-orthogonal immobilization of DNA modifying enzymes employing the self-labelling activity of the SNAP-tag to covalently conjugate the enzyme of interest to the solid support. We also demonstrate how modifying the surface functionality of the support can improve the activity of the immobilized enzyme. Finally, the utility of immobilized DNA-modifying enzymes is depicted through sequential processing of genomic DNA libraries for Illumina next-generation sequencing (NGS), resulting in improved read coverage across AT-rich sequences.

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Controlling Redox Enzyme Orientation at Planar Electrodes

Cited by 83 publications

References 199 publications

Micro‐ and Nanoscopic Imaging of Enzymatic Electrodes: A Review

Micro‐ and Nanoscopic Imaging of Enzymatic Electrodes: A Review

Implicit modeling of the impact of adsorption on solid surfaces for protein mechanics and activity with a coarse-grain representation

Enzyme Immobilization for Solid-Phase Catalysis

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