Self-Sufficient Heterogeneous Biocatalysis through Boronic Acid-Diol Complexation of Adenylated Cofactors

Diamanti, Eleftheria; Velasco-Lozano, Susana; Grajales-Hernández, Daniel; Orrego, Alejandro H.; Di Silvio, Desiré; Fraile, José María; López-Gallego, Fernando

doi:10.1021/acssuschemeng.3c02958

“…In contrast SP studies can inform about larger areas (μm-cm) [30] in wider operational times (from s to days). [31] A potential limitation of SM approaches is the mandatory use of fluorophore-labeled enzymes. In contrast, SP can be performed with unlabeled enzymes if particles are labeled, minimizing the effects of enzyme modification on the property under study.…”

Section: Sp/sm Assays To Profoundly Characterize Heterogeneous Biocat...mentioning

confidence: 99%

Single‐Particle and Single‐Molecule Characterization of Immobilized Enzymes: A Multiscale Path toward Optimizing Heterogeneous Biocatalysts

Diamanti,

López‐Gallego

2024

Angewandte Chemie

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Heterogeneous biocatalysis is highly relevant in biotechnology as it offers several benefits and practical uses. To leverage the full potential of heterogeneous biocatalysts, the establishment of well‐crafted protocols, and a deeper comprehension of enzyme immobilization on solid substrates are essential. These endeavors seek to optimize immobilized biocatalysts, ensuring maximal enzyme performance within confined spaces. To this aim, multidimensional characterization of heterogeneous biocatalysts is demanded. In this context, spectroscopic and microscopic methodologies conducted at different space and temporal scales can inform about the intraparticle enzyme kinetics, the enzyme spatial distribution, and mass transport issues. In this minireview, we identify enzyme immobilization, enzyme activity, and enzyme inactivation as the three fundamental processes for which advanced characterization tools unveil fundamental information. Recent advances in operando characterization of immobilized enzymes at the single‐particle (SP) and single‐molecule (SM) levels reveal valuable information on their functional properties unlocking the full potential of heterogeneous biocatalysis toward biotechnological applications.

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“…However, SM methods are generally limited to small surface areas (1–10 μm) and short reaction times (from ms to s) due to photobleaching issues. In contrast SP studies can inform about larger areas (μm‐cm) [30] in wider operational times (from s to days) [31] . A potential limitation of SM approaches is the mandatory use of fluorophore‐labeled enzymes.…”

Section: Sp/sm Assays To Profoundly Characterize Heterogeneous Biocat...mentioning

confidence: 99%

Single‐Particle and Single‐Molecule Characterization of Immobilized Enzymes: A Multiscale Path toward Optimizing Heterogeneous Biocatalysts

Diamanti,

López‐Gallego

2024

Angew Chem Int Ed

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Heterogeneous biocatalysis is highly relevant in biotechnology as it offers several benefits and practical uses. To leverage the full potential of heterogeneous biocatalysts, the establishment of well‐crafted protocols, and a deeper comprehension of enzyme immobilization on solid substrates are essential. These endeavors seek to optimize immobilized biocatalysts, ensuring maximal enzyme performance within confined spaces. To this aim, multidimensional characterization of heterogeneous biocatalysts is demanded. In this context, spectroscopic and microscopic methodologies conducted at different space and temporal scales can inform about the intraparticle enzyme kinetics, the enzyme spatial distribution, and mass transport issues. In this minireview, we identify enzyme immobilization, enzyme activity, and enzyme inactivation as the three fundamental processes for which advanced characterization tools unveil fundamental information. Recent advances in operando characterization of immobilized enzymes at the single‐particle (SP) and single‐molecule (SM) levels reveal valuable information on their functional properties unlocking the full potential of heterogeneous biocatalysis toward biotechnological applications.

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“…In the past few decades, substantial efforts have been made to construct efficient coimmobilization systems of enzymes and cofactor. − Electrostatic interaction/ion-exchange interaction through the negative-charged phosphate group of cofactors and positive-charged supports/polymers is an effective method for immobilizing cofactors since there is a dynamic association/dissociation equilibrium in ionically bound cofactor systems, guaranteeing the immobilized cofactors to access enzymes with high mobility. Lopez-Gallego and colleagues constructed a coimmobilization system with NAD + ionically adsorbed and enzymes immobilized and cross-linked .…”

Section: Introductionmentioning

confidence: 99%

Coencapsulating Anionic Cofactor and Silica Nanoparticle-Bound Enzymes in Cationic Microgel for Multienzyme Cascade Reaction with Cofactor Recycling

Liu,

Wu,

Dong

et al. 2024

ACS Sustainable Chem. Eng.

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Large-scale applications of enzymes and cofactors remain a challenge due to their fragile property, nonrecyclability, and high cost. Herein, we report a coimmobilization strategy of multienzyme and cofactor based on a combination of microgel and silica nanoparticles (SNPs) to make the biocatalysis process economical and sustainable. As exemplified by a nicotinamide adenine dinucleotide (NAD)-dependent alcohol dehydrogenase and chimeric amine dehydrogenase cascade amination reaction, the dual-enzyme coimmobilization system, with 100% immobilization yield and 76% increased cascade activity, was constructed through the site-specific immobilization of silica binding peptide. The anionic dual-enzyme@SNPs (29.7 mg g SNPs/PVCL-Vim −1) and NADH (47.3 μmol g SNPs/PVCL-Vim −1 ) are then delivered into a cationic microgel through gel swelling and electrostatic interactions/ion exchanges. The system displays a 27 to 75% enhancement in the amination yield as compared to the free counterpart, possibly due to the site-specific immobilization of enzymes, the proximity effect resulting from the coimmobilization, and the mobility and accessibility of the immobilized cofactor. Moreover, the constructed coimmobilization system shows 8−43% increased stability over the free system and retains 97% of its original activity after eight recycles. Collectively, this work has demonstrated an efficient coimmobilization strategy of a cofactor-dependent multienzyme cascade for applications of sustainable biotransformation.

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Self-Sufficient Heterogeneous Biocatalysis through Boronic Acid-Diol Complexation of Adenylated Cofactors

Cited by 6 publications

References 49 publications

Single‐Particle and Single‐Molecule Characterization of Immobilized Enzymes: A Multiscale Path toward Optimizing Heterogeneous Biocatalysts

Single‐Particle and Single‐Molecule Characterization of Immobilized Enzymes: A Multiscale Path toward Optimizing Heterogeneous Biocatalysts

Single‐Particle and Single‐Molecule Characterization of Immobilized Enzymes: A Multiscale Path toward Optimizing Heterogeneous Biocatalysts

Coencapsulating Anionic Cofactor and Silica Nanoparticle-Bound Enzymes in Cationic Microgel for Multienzyme Cascade Reaction with Cofactor Recycling

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