Immobilization-Stabilization of β-Glucosidase for Implementation of Intensified Hydrolysis of Cellobiose in Continuous Flow Reactors

Alvarez-Gonzalez, Celia; Santos, Victoria E.; Ladero, Miguel; Bolívar, Juan M.

doi:10.3390/catal12010080

Cited by 12 publications

(12 citation statements)

References 56 publications

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“…Thus, immobilization reduces, if not eliminates, this inhibition. This inhibitory effect, however, was also observed in a recent paper by our group when working with cross-linked agarose beads activated with polyethylenemine (PEI), or glyoxyl groups (Gly) [14], suggesting that support and immobilization chemistry play a role in the inhibitory role of cellobiose. The kinetic models proposed, and fitted to all data, are Michaelis-Menten models with competitive inhibition by glucose, a type of inhibition very common to hydrolases acting on poly-, oligo-and disaccharides.…”

Section: Cellobiose Hydrolysis: Kinetic Modellingmentioning

confidence: 53%

“…Due to its industrial potential, there are many recent reports on fungal β-glucosidase immobilization on different supports by several immobilization methods such as the following: β-glucosidase of Aspergillus versicolor immobilized on magnetic MnO 2 nanomaterials [8], β-glucosidase from Aspergillus niger immobilized on diverse amino agarose beads and cross-linked with glutaraldehyde [9], β-glucosidase from Aspergillus awamori using commercial gelatin as support and glutaraldehyde as crosslinker [10], β-glucosidase of Aspergillus niger on amino-based silica via biotin-streptavidin affinity [11], β-glucosidase of Aspergillus niger immobilized on Eupergit ® C (an epoxy-activated support) [12], βglucosidase of Aspergillus japonicus immobilized on anionic exchanger supports (MANAEagarose and DEAE-cellulose) [13], and β-glucosidase of Aspergillus fumigatus immobilized on cross-linked agarose beads and polymethacrylate Lifetech™ECR8209F particles (Purolite) activated with amino groups (monoaminoethyl-N-aminoethyl: MANAE), polyethylenemine (PEI), or glyoxyl groups (Gly) [14], to name a few. Among all types of immobilization methods, covalent immobilization is the most used in industry, and different activated supports for that purpose have been developed, based on Eupergit ® , Sepabeads™ and ReliZyme™.…”

Section: Introductionmentioning

confidence: 99%

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Immobilization of an Industrial β-Glucosidase from Aspergillus fumigatus and Its Use for Cellobiose Hydrolysis

et al. 2022

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In this study, several covalent methods of immobilization based on acrylic supports, Schiff bases and epoxides have been applied to a commercial cocktail with a high β-glucosidase activity secreted by Aspergillus fumigatus. This cocktail was preliminary compared to a commercial secretome of Aspergillus niger, which was also subjected to the aforementioned immobilization methods. Due to its higher activity, the cocktail from A. fumigatus immobilized on ReliZyme™ HA403 activated with glutaraldehyde was employed for pNPG and cellobiose hydrolysis in diverse operational conditions and at diverse enzyme loadings, showing a very high activity at high enzyme load. A kinetic model based on the Michaelis–Menten hypothesis, in which double inhibition occurs due to glucose, has been selected upon fitting it to all experimentally retrieved data with the lowest-activity immobilized enzyme. This model was compared to the one previously established for the free form of the enzyme, observing that cellobiose acompetitive inhibition does not exist with the immobilized enzyme acting as the biocatalyst. In addition, stability studies indicated that the immobilized enzyme intrinsically behaves as the free enzyme, as expected for a one-bond low-interaction protein-support immobilization.

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Section: Cellobiose Hydrolysis: Kinetic Modellingmentioning

confidence: 53%

Section: Introductionmentioning

confidence: 99%

Immobilization of an Industrial β-Glucosidase from Aspergillus fumigatus and Its Use for Cellobiose Hydrolysis

et al. 2022

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“…We also tested the tri-enzymatic nanobiocatalyst for the cascade where cellobiose hydrolysis is the initial step; the results for different reaction temperatures are shown in Figure 12 b. The highest catalytic activity was observed at 50 °C, which is known to be the optimal operating temperature for β -glucosidases towards cellobiose hydrolysis [ 48 ]. It is interesting to note that contrary to p NPG hydrolysis, in this cascade reaction, the tri-enzymatic nanobiocatalytic system is effective at 50 °C.…”

Section: Resultsmentioning

confidence: 99%

Development of a Multi-Enzymatic Biocatalytic System through Immobilization on High Quality Few-Layer bio-Graphene

et al. 2022

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In this work, we report the green production of few-layer bio-Graphene (bG) through liquid exfoliation of graphite in the presence of bovine serum albumin. Microscopic characterization evaluated the quality of the produced nanomaterial, showing the presence of 3–4-layer graphene. Moreover, spectroscopic techniques also confirmed the quality of the resulted bG, as well as the presence of bovine serum albumin on the graphene sheets. Next, for the first time, bG was used as support for the simultaneous covalent co-immobilization of three enzymes, namely β-glucosidase, glucose oxidase, and horseradish peroxidase. The three enzymes were efficiently co-immobilized on bG, demonstrating high immobilization yields and activity recoveries (up to 98.5 and 90%, respectively). Co-immobilization on bG led to an increase of apparent KM values and a decrease of apparent Vmax values, while the stability of the nanobiocatalysts prevailed compared to the free forms of the enzymes. Co-immobilized enzymes exhibited high reusability, preserving a significant part of their activity (up to 72%) after four successive catalytic cycles at 300 °C. Finally, the tri-enzymatic nanobiocatalytic system was applied in three-step cascade reactions, involving, as the first step, the hydrolysis of p-Nitrophenyl-β-D-Glucopyranoside and cellobiose.

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“…PBRs are easily scalable and applied for large-scale continuous biotransformations in diverse industry sectors, from the well-known resolution of acyl-DLamino acids employing the immobilized Aspergillus oryzae aminoacylase (Sato and Tosa, 2010), to the most recent production of biodiesel (Erdem and Woodley, 2022;Miotti et al, 2022) or fructose syrup (Neifar et al, 2020). Further recent applications include the continuous removal of urea in high polyphenol wines with an immobilized Lactobacillus fermentum acid urease to reduce ethyl carbamate formation (Fidaleo and Tavilli, 2021), and the hydrolysis of cellobiose with immobilized βglucosidases (Alvarez-Gonzalez et al, 2022). Cellobiose, a β-1,4 glucose-based disaccharide, is used as a model-molecule in many studies aimed at finding solutions to the depolymerization of cellulose from renewable lignocellulosic biomass.…”

Section: Continuous Reactors In a Nutshell: Selected Layouts And Appl...mentioning

confidence: 99%

“…Bolivar and coworkers recently reported on a sustainable cellobiose hydrolysis. By designing a glucosidase-based reactor using glyoxyl-agarose for immobilization, the full conversion (34 g L -1 ) was achieved in 20 min residence time (Alvarez-Gonzalez et al, 2022). An engineered variant of the hydrolytic enzyme β-N-acetyl-hexosaminidase from Bifidobacterium bifidum was employed to produce the precious oligosaccharide lacto-N-triose II, a component of human milk oligosaccharides used as a synthon for nutritional supplements, providing a further example of the synergistic use of protein and reaction engineering for synthetic purposes (Ruzic et al, 2020).…”

Section: Food-related Compoundsmentioning

confidence: 99%

What’s new in flow biocatalysis? A snapshot of 2020–2022

et al. 2023

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Flow biocatalysis is a key enabling technology that is increasingly being applied to a wide array of reactions with the aim of achieving process intensification, better control of biotransformations, and minimization of waste stream. In this mini-review, selected applications of flow biocatalysis to the preparation of food ingredients, APIs and fat- and oil-derived commodity chemicals, covering the period 2020-2022, are described.

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Immobilization-Stabilization of β-Glucosidase for Implementation of Intensified Hydrolysis of Cellobiose in Continuous Flow Reactors

Cited by 12 publications

References 56 publications

Immobilization of an Industrial β-Glucosidase from Aspergillus fumigatus and Its Use for Cellobiose Hydrolysis

Immobilization of an Industrial β-Glucosidase from Aspergillus fumigatus and Its Use for Cellobiose Hydrolysis

Development of a Multi-Enzymatic Biocatalytic System through Immobilization on High Quality Few-Layer bio-Graphene

What’s new in flow biocatalysis? A snapshot of 2020–2022

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