Enzyme Aggregates Research Articles

Methylglyoxal-Induced Modifications in Human Triosephosphate Isomerase: Structural and Functional Repercussions of Specific Mutations.

Triosephosphate isomerase (TPI) dysfunction is a critical factor in diverse pathological conditions. Deficiencies in TPI lead to the accumulation of toxic methylglyoxal (MGO), which induces non-enzymatic post-translational modifications, thus compromising protein stability and leading to misfolding. This study investigates how specific TPI mutations (E104D, N16D, and C217K) affect the enzyme's structural stability when exposed to its substrate glyceraldehyde 3-phosphate (G3P) and MGO. We employed circular dichroism, intrinsic fluorescence, native gel electrophoresis, and Western blotting to assess the structural alterations and aggregation propensity of these TPI mutants. Our findings indicate that these mutations markedly increase TPI's susceptibility to MGO-induced damage, leading to accelerated loss of enzymatic activity and enhanced protein aggregation. Additionally, we observed the formation of MGO-induced adducts, such as argpyrimidine (ARGp), that contribute to enzyme inactivation and aggregation. Importantly, the application of MGO-scavenging molecules partially mitigated these deleterious effects, highlighting potential therapeutic strategies to counteract MGO-induced damage in TPI-related disorders.

Effective multi-biocatalyst system with reusable NADH for transformation of glycerol to value-added dihydroxyacetone

Glycerol-based biorefinery can be a highly profitable process by producing highly value-added products such as dihydroxyacetone via combined catalytic strategies. Here, two-enzyme system is adopted for the transformation of glycerol into highly valuable dihydroxyacetone as well as cofactor regeneration at the same time. Glycerol dehydrogenase (GDH) and alcohol dehydrogenase (ADH) are co-immobilized within magnetically separable and spherical mesocellular silica foam (Mag-S-MCF), to prepare NER-(GDH/ADH). In details, GDH and ADH are adsorbed into the mesopores of Mag-S-MCF, and further crosslinked within the mesopores of Mag-S-MCF. The resulting nanoscale enzyme reactors (NER) of crosslinked GDH and ADH molecules within the bottle-neck structured mesopores can effectively prevent larger sized crosslinked enzyme aggregates from being leached out of smaller mesopores, due to the bottle-neck mesopore structure of Mag-S-MCF, as well as stabilize the activity of GDH and ADH upon chemical crosslinking, effectively preventing the denaturation of enzyme molecules. More importantly, the proximity of GDH and ADH molecules within mesopores of NER improves the efficiency of cofactor-mediated dual-enzymatic reactions by relieving mass-transfer limitations and improving cofactor recycling in an effective way, expediting both glycerol oxidation and dihydroxyacetone generation at the same time. As a result, the DHA concentration of NER-(GDH/ADH) and the simple mixture of NER-GDH and NER-ADH were 410 μM and 336 μM, respectively. To the best of our knowledge, this report is the first demonstration of stabilized nanoscale multi-enzyme reactor system, equipped with efficient cofactor regeneration within confined mesopores, for efficient glycerol transformation to high-valued dihydroxyacetone.Graphical

Loss of endogenous Nox2-NADPH oxidase does not prevent age-induced platelet activation and arterial thrombosis in mice

BackgroundReactive oxygen species are known to contribute to platelet hyperactivation and thrombosis during aging; however, the mechanistic contribution of the specific oxidative pathway remains elusive. ObjectivesWe hypothesized that during aging, endogenous Nox2-NADPH oxidase contributes to platelet reactive oxygen species accumulation and that loss of Nox2 will protect from platelet activation and thrombosis. MethodsWe studied littermates of Nox2 knockout (Nox2-KO) and -wild-type (Nox2-WT) mice at young (3-4 months) and old (18-20 months) age. Within platelets, we examined the expression of subunits of NADPH oxidase and enzyme activity, oxidant levels, activation markers, aggregation, and secretion. We also assessed susceptibility to in vivo thrombosis in 2 experimental models. ResultsWhile aged Nox2-WT mice displayed increased mRNA levels for Nox2, aged Nox2-KO mice showed an increase in Nox4 mRNA. However, neither the protein levels of several subunits nor the activity of NADPH oxidase were found to be altered by age or genotype. Both aged Nox2-WT and aged Nox2-KO mice exhibited similar enhancement in levels of platelet oxidants, granule release, αIIbβ3 activation, annexin V binding, aggregation and secretion, and a greater susceptibility to platelet-induced pulmonary thrombosis compared with young mice. In a photochemical injury model, adoptive transfer of platelets from aged Nox2-WT or Nox2-KO mice to the aged host mice resulted in a similar time to develop occlusive thrombus in the carotid artery. These findings suggest that loss of endogenous Nox2 does not protect against age-related platelet activation and arterial thrombosis in mice. ConclusionWe conclude that Nox2 is not an essential mediator of prothrombotic effects associated with aging.

Single stage bi-substrate transglycosylation reaction for the synthesis of ascorbic acid 2 glucoside using immobilized α-glucosidase

Alpha glucosidases are multifunctional glycoside hydrolases with hydrolysis and transglycosylation ability. It can be utilized for the glycosidic bond synthesis or glycosylation of Ascorbic acid/Vitamin C to its stable analogue, Ascorbic acid 2 glucoside (AA2G), a compound with wide applications in cosmetics and pharma. The application of α-glucosidases for industrial scale transglycosylation is limited due to the low transglycosylation yield of free enzymes. Enzyme immobilization techniques could enable the development of efficient, reusable catalysts. Only a few glycoside hydrolases have been studied in immobilized form for transglycosylation reactions, and α-glucosidases are probably the least explored in this form. Transglycosylation activity of immobilized α-glucosidase from Aspergillus carbonarius BTCF 5 was studied for AA2G synthesis, where different immobilization techniques like calcium alginate encapsulation, adsorption on chitosan beads, covalent cross-linking on magnetic nanoparticles, and cross-linked enzyme aggregates (CLEA) were employed for the immobilization. The immobilization yield of calcium alginate encapsulated enzyme, enzyme immobilized on Fe-MNP support, enzyme immobilized on chitosan beads and as CLEA were 107%, 99%, 46% and 486%, respectively. CLEA was identified as the best immobilization technique for this bi-substrate reaction due to the high immobilization yield and activity retention (30% activity retained after 5 consecutive cycles). Enzyme immobilization increased the transglycosylation activity by 38%, yielding 118 mM AA2G against 72 mM by the free enzyme. This indicates the potential of immobilized α-glucosidase as a catalyst for synthesizing AA2G at an industrial scale.

Strategy in Synthesizing Longer-Chain Levan-Type Fructooligosaccharides by Selective Dextran Macromolecular Cross-Linked Bacillus lehensis G1 Endolevanase Aggregate Immobilization

The formation of cross-linked enzyme aggregates (CLEAs) using macromolecular cross-linkers improves substrate accessibility and enhances enzyme retention. However, there have been few studies exploring the use of macromolecular cross-linkers due to the challenges related to cross-linker screening. In compliance with our previous computational and experimental screening, dextran is the optimal macromolecular cross-linker to develop CLEAs of endolevanase from Bacillus lehensis G1 (rlevblg1-dex-CLEA) for levan-type-fructooligosaccharides (L-FOS) production. In this study, rlevblg1-dex-CLEAs was optimized, and the activity recovery continued to increase and reached 90.5%. Subsequently, the rlevblg1-dex-CLEAs were characterized and they displayed higher thermal stability after 1 h of incubation in comparison to the free enzyme. Moreover, the rlevblg1-dex-CLEAs were reusable for five cycles and exhibited greater storage stability over 180 days at 4 °C (60.9%) than that of free rlevblg1. In addition, the rlevblg1-dex-CLEAs demonstrated similar catalytic efficiency as the free enzyme and generated a substantial amount of L-FOS with a longer degree of polymerization, which is more beneficial for industrial use.

Utilization of laccase magnetic cross-link aggregates for decolorization of amido black 10B contained in water

Laccase has a wide range of substrates and the oxidation product is water, providing an ideal choice for the biological degradation and decolorization of dyeing wastewater. This study extracted laccase from the fruiting body of Agaricus bisporus, then used o-phthalaldehyde (OPA) as a cross-linking agent and added surface-aminated Fe3O4 nanoparticles (NH2-nanoFe3O4) to prepare magnetic cross-link enzyme aggregates (MCLEAs) of laccase, which was characterized by scanning electron microscope and vibrating sample magnetometer. The optimal temperature for the catalytic reaction of the MCLEAs was 35 °C, and the optimal pH was 3.0. The stability to temperature pH and storage stability were all enhanced. The immobilized laccase was utilized to treat amido black 10B solution, and the decolorization rate reached 92.48%. After five cycles of use, the MCLEAs of laccase could maintain 42.91% of the relative activity and 32.31% of the relative degradation ability to amido black 10B.

Immobilization of cross-linked enzymes aggregates on hierarchical covalent organic frameworks: Highly stable chemoenzymatic nanoreactor for asymmetric synthesis of optically active halohydrins

Organometallic catalyst is extensively applied for the non-enzymatic regeneration of nicotinamide adenine dinucleotide (phosphate) cofactors, but suffering from the mutual inactivation with the enzymes in one pot. The spatially separated immobilization of organometallic catalyst and enzymes on suitable carriers not only can reduce their mutual inhabitation but also can enhance their reusability. Here in this work, we present a hierarchical porous COFs (HP-TpBpy) that incorporated with [(Cp*RhCl2]2 to generate the metalized COF, Rh-HP-TpBpy. The obtained Rh-HP-TpBpy exhibited superior performance in nicotinamide adenine dinucleotide (NADH) and nicotinamide adenine dinucleotide phosphate (NADPH) regeneration using formate as the hydride donor, significantly outperforming the natural formate dehydrogenases in cofactor preference toward NADP+. Subsequently, the Lactobacillus fermentum short-chain dehydrogenase/reductase 1 (LfSDR1) was then cross-linked into enzyme aggregates (CLEA) and immobilized on hierarchical Rh-HP-TpBpy, achieving the integrated chemoenzymatic catalyst, LfSDR1@Rh-HP-TpBpy, which can catalyze the chemoenzymatic reduction of halogenated aryl ketones and give the corresponding optically active halohydrins with high conversion and enantiomeric excess (ee) value up to 99 %. The LfSDR1@Rh-HP-TpBpy also exhibits largely enhanced stability compared with the free LfSDR1 and the CLEAs-LfSDR1, enabling its excellent reusability.

Catalytic Stability of S-1-(4-Hydroxyphenyl)-Ethanol Dehydrogenase from Aromatoleum aromaticum.

Derived from the denitrifying bacterium Aromatoleum aromaticum EbN1 (Azoarcus sp.), the enzyme S-1-(4-hydroxyphenyl)-ethanol dehydrogenase (S-HPED) belongs to the short-chain dehydrogenase/reductase family. Using research techniques like UV-Vis spectroscopy, dynamic light scattering, thermal-shift assay and HPLC, we investigated the catalytic and structural stability of S-HPED over a wide temperature range and within the pH range of 5.5 to 9.0 under storage and reaction conditions. The relationship between aggregation and inactivation of the enzyme in various pH environments was also examined and interpreted. At pH 9.0, where the enzyme exhibited no aggregation, we characterized thermally induced enzyme inactivation. Through isothermal and multitemperature analysis of inactivation data, we identified and confirmed the first-order inactivation mechanism under these pH conditions and determined the kinetic parameters of the inactivation process. Additionally, we report the positive impact of glucose as an enzyme stabilizer, which slows down the dynamics of S-HPED inactivation over a wide range of pH and temperature and limits enzyme aggregation. Besides characterizing the stability of S-HPED, the enzyme's catalytic activity and high stereospecificity for 10 prochiral carbonyl compounds were positively verified, thus expanding the spectrum of substrates reduced by S-HPED. Our research contributes to advancing knowledge about the biocatalytic potential of this catalyst.

Improvement of combined cross-linked enzyme aggregates of cyclodextrin glucanotransferase and maltogenic amylase by functionalization of cross-linker for maltooligosaccharides synthesis

Combined cross-linked enzyme aggregates of cyclodextrin glucanotransferase (CGTase) and maltogenic amylase (Mag1) from Bacillus lehensis G1 (Combi-CLEAs-CM) were successfully developed to synthesis maltooligosaccharides (MOS). Yet, the poor cross-linking performance between chitosan (cross-linker) and enzymes resulting low activity recovery and catalytic efficiency. In this study, we proposed the functionalization of cross-linkers with the integration of computational analysis to study the influences of different functional group on cross-linkers in combi-CLEAs development. From in-silico analysis, O-carboxymethyl chitosan (OCMCS) with the highest binding affinity toward both enzymes was chosen and showed alignment with the experimental result, in which OCMCS was synthesized as cross-linker to develop improved activity recovery of Combi-CLEAs-CM-ocmcs (74 %). The thermal stability and deactivation energy (205.86 kJ/mol) of Combi-CLEAs-CM-ocmcs were found to be higher than Combi-CLEAs-CM (192.59 kJ/mol). The introduction of longer side chain of carboxymethyl group led to a more flexible structure of Combi-CLEAs-CM-ocmcs. This alteration significantly reduced the Km value of Combi-CLEAs-CM-ocmcs by about 3.64-fold and resulted in a greater Kcat/Km (3.63-fold higher) as compared to Combi-CLEAs-CM. Moreover, Combi-CLEAs-CM-ocmcs improved the reusability with retained >50 % of activity while Combi-CLEAs-CM only 36.18 % after five cycles. Finally, maximum MOS production (777.46 mg/g) was obtained by Combi-CLEAs-CM-ocmcs after optimization using response surface methodology.

Co-immobilization of crosslinked enzyme aggregates on lysozyme functionalized magnetic nanoparticles for enhancing stability and activity

Surface chemistry of carriers plays a key role in enzyme loading capacity, structure rigidity, and thus catalyze activity of immobilized enzymes. In this work, the two model enzymes of horseradish peroxidase (HRP) and glucose oxidase (GOx) are co-immobilized on the lysozyme functionalized magnetic core-shell nanocomposites (LYZ@MCSNCs) to enhance their stability and activity. Briefly, the HRP and GOx aggregates are firstly formed under the crosslinker of trimesic acid, in which the loading amount and the rigidity of the enzyme can be further increased. Additionally, LYZ easily forms a robust anti-biofouling nanofilm on the surface of SiO2@Fe3O4 magnetic nanoparticles with abundant functional groups, which facilitate chemical crosslinking of HRP and GOx aggregates with minimized inactivation. The immobilized enzyme of HRP-GOx@LYZ@MCSNCs exhibited excellent recovery activity (95.6 %) higher than that of the free enzyme (HRP&GOx). Specifically, 85 % of relative activity was retained after seven cycles, while 73.5 % of initial activity was also remained after storage for 33 days at 4 °C. The thermal stability and pH adaptability of HRP-GOx@LYZ@MCSNCs were better than those of free enzyme of HRP&GOx. This study provides a mild and ecofriendly strategy for multienzyme co-immobilization based on LYZ functionalized magnetic nanoparticles using HRP and GOx as model enzymes.

Synthesis and Characterization of Cross-Linked Aggregates of Peroxidase from Megathyrsus maximus (Guinea Grass) and Their Application for Indigo Carmine Decolorization.

We present the synthesis of a cross-linking enzyme aggregate (CLEAS) of a peroxidase from Megathyrsus maximus (Guinea Grass) (GGP). The biocatalyst was produced using 50%v/v ethanol and 0.88%w/v glutaraldehyde for 1 h under stirring. The immobilization yield was 93.74% and the specific activity was 36.75 U mg-1. The biocatalyst surpassed by 61% the free enzyme activity at the optimal pH value (pH 6 for both preparations), becoming this increase in activity almost 10-fold at pH 9. GGP-CLEAS exhibited a higher thermal stability (2-4 folds) and was more stable towards hydrogen peroxide than the free enzyme (2-3 folds). GGP-CLEAS removes over 80% of 0.05 mM indigo carmine at pH 5, in the presence of 0.55 mM H2O2 after 60 min of reaction, a much higher value than when using the free enzyme. The operational stability showed a decrease of enzyme activity (over 60% in 4 cycles), very likely related to suicide inhibition.

Hyperbranched Polymer-Cross-Linked Enzyme Aggregates for the Compartmentalized Coimmobilization of Enzymes and Metal Nanoparticles

Hyperbranched Polymer-Cross-Linked Enzyme Aggregates for the Compartmentalized Coimmobilization of Enzymes and Metal Nanoparticles

Genipin crosslinked L-asparaginase CLEAs effectively mitigate acrylamide in deep-fried sweet potato chips

Crosslinked enzyme aggregates of L-asparaginase (A-CLEAs) were prepared using genipin, a non-toxic crosslinker. The process parameters for the preparation of A-CLEAs were optimized using a 3-level factorial design, which predicted the optimized conditions to be 60 mg/mL BSA, 2 mg/mL genipin and a crosslinking time of 4 h. The model which was validated experimentally, resulted in a recovery of 90% activity of L-asparaginase. While the optimum pH shifted to a slightly acidic range, the optimum temperature remained unchanged. A-CLEAs displayed the best pH stability at pH 9 (48%) after 24 h of incubation. At 50 °C, the deactivation rate constant (Kd) of A-CLEA decreased by 24%. A-CLEAs showed excellent reusability, retaining 79% of their initial activity after 10 cycles of use. The formation of a dark-blue coloured pigmented A-CLEA and the presence of the carboxymethyl group of genipin in FTIR spectrum confirmed the crosslinking reaction. The increase in the β-sheet content of A-CLEA, correlated with its improved stability. The improved thermostability with regards to structural integrity was well established by TGA-DSC analyses. Morphologically, A-CLEAs showed a highly clustered ball-like appearance. As a model example, the ability of genipin crosslinked A-CLEAs to reduce acrylamide in sweet potato chips was checked. The asparagine content of sweet potato was found to be 2906 ± 15.02 mg/kg as quantified by HPTLC. Analysis of acrylamide by GC-FID showed a 94% reduction in sweet potato chips on contact of sweet potato slices with A-CLEAs for 40 min.

Enhancing the stability of a novel D-allulose 3-epimerase from Ruminococcus sp. CAG55 by interface interaction engineering and terminally attached a self-assembling peptide

D-allulose, a highly desirable sugar substitute, is primarily produced using the D-allulose 3-epimerase (DAE). However, the availability of usable DAE enzymes is limited. In this study, we discovered and engineered a novel DAE Rum55, derived from a human gut bacterium Ruminococcus sp. CAG55. The activity of Rum55 was strictly dependent on the presence of Co2+, and it exhibited an equilibrium conversion rate of 30.6 % and a half-life of 4.5 h at 50 °C. To enhance its performance, we engineered the interface interaction of Rum55 to stabilize its tetramer structure, and the best variant E268R was then attached with a self-assembling peptide to form active enzyme aggregates as carrier-free immobilization. The half-life of the best variant E268R-EKL16 at 50 °C was dramatically increased 30-fold to 135.3 h, and it maintained 90 % of its activity after 13 consecutive reaction cycles. Additionally, we identified that metal ions played a key role in stabilizing the tetramer structure of Rum55, and the dependence on metal ions for E268R-EKL16 was significantly reduced. This study provides a useful route for improving the thermostability of DAEs, opening up new possibilities for the industrial production of D-allulose.

A Critical Review on Immobilized Sucrose Isomerase and Cells for Producing Isomaltulose.

Isomaltulose is a novel sweetener and is considered healthier than the common sugars, such as sucrose or glucose. It has been internationally recognized as a safe food product and holds vast potential in pharmaceutical and food industries. Sucrose isomerase is commonly used to produce isomaltulose from the substrate sucrose in vitro and in vivo. However, free cells/enzymes were often mixed with the product, making recycling difficult and leading to a significant increase in production costs. Immobilized cells/enzymes have the following advantages including easy separation from products, high stability, and reusability, which can significantly reduce production costs. They are more suitable than free ones for industrial production. Recently, immobilized cells/enzymes have been encapsulated using composite materials to enhance their mechanical strength and reusability and reduce leakage. This review summarizes the advancements made in immobilized cells/enzymes for isomaltulose production in terms of refining traditional approaches and innovating in materials and methods. Moreover, innovations in immobilized enzyme methods include cross-linked enzyme aggregates, nanoflowers, inclusion bodies, and directed affinity immobilization. Material innovations involve nanomaterials, graphene oxide, and so on. These innovations circumvent challenges like the utilization of toxic cross-linking agents and enzyme leakage encountered in traditional methods, thus contributing to enhanced enzyme stability.

Expression of Concern: Efficient decolorization and detoxification of triarylmethane and azo dyes by porous-cross-linked enzyme aggregates of Pleurotus ostreatus laccase

Expression of Concern: Efficient decolorization and detoxification of triarylmethane and azo dyes by porous-cross-linked enzyme aggregates of Pleurotus ostreatus laccase

Production and immobilization of laccases from monoculture and co-culture of Trametes villosa and Pycnoporus sanguineus for sustainable biodegradation of ciprofloxacin

The presence of antibiotics in water systems and drinking water has detrimental effects on various organisms and poses health risks to both animals and humans. This study describes a sustainable approach using laccases to remove ciprofloxacin from water solutions. Laccases produced by monoculture of Trametes villosa and in co-culture with Pycnoporus sanguineus were immobilized using the method of cross-linked enzyme aggregates (CLEAs). The immobilization process was statistically optimized, and the biocatalysts were characterized and applied for biodegradation of ciprofloxacin at different concentrations. Laccase production was enhanced in co-culture conditions, yielding isoforms of molecular masses ranging from 55 to 45 kDa. Optimum conditions for immobilizing laccases by CLEAs were achieved with ammonium sulfate as a precipitant and glutaraldehyde as a cross-linker. Immobilization improved the thermal stability of the enzymes at 40 °C and 55 °C, and both forms of laccase CLEAs retained approximately 38% of their initial activity after five reuse cycles. Free and immobilized laccases demonstrated comparable efficiency in removing ciprofloxacin from aqueous solutions (at 2.5 mg L−1) with a 53–62% removal rate in the presence of 4-hydroxybenzoic acid as a natural redox mediator. The degradation of ciprofloxacin by laccases also reduced its antimicrobial activity against Escherichia coli.

Cross-linked enzyme aggregates of polyethylene terephthalate hydrolyse (PETase) from Ideonella sakaiensis for the improvement of plastic degradation

Polyethylene terephthalate (PET) is one of the most produced plastics globally and its accumulation in the environment causes harm to the ecosystem. Polyethylene terephthalate hydrolyse (PETase) is an enzyme that can degrade PET into its monomers. However, free PETase lacks operational stabilities and is not reusable. In this study, development of cross-linked enzyme aggregate (CLEA) of PETase using amylopectin (Amy) as cross-linker was introduced to solve the limitations of free PETase. PETase-Amy-CLEA exhibited activity recovery of 81.9 % at its best immobilization condition. Furthermore, PETase-Amy-CLEA exhibited 1.37-, 2.75-, 2.28- and 1.36-fold higher half-lives than free PETase at 50 °C, 45 °C, 40 °C and 35 °C respectively. Moreover, PETase-Amy-CLEA showed broader pH stability from pH 5 to 10 and could be reused up to 5 cycles. PETase-Amy-CLEA retained >70 % of initial activity after 40 days of storage at 4 °C. In addition, lower Km of PETase-Amy-CLEA indicated better substrate affinity than free enzyme. PETase-Amy-CLEA corroded PET better and products yielded was 66.7 % higher than free PETase after 32 h of treatment. Hence, the enhanced operational stabilities, storage stability, reusability and plastic degradation ability are believed to make PETase-Amy-CLEA a promising biocatalyst in plastic degradation.

Cross-linked enzyme aggregates of xylanase, XynR8(N58D), for effective degradation of untreated lignocellulosic biomass

Enzymatic degradation of biomass is preferred over chemical methods for environmental protection. However, in most cases, a chemical pretreatment is still required to help improve enzyme accessibility of the biomass. Therefore, it is necessary to develop highly efficient enzymes for those reasons and to save costs accordingly. Costs can be further reduced if the enzymes are recycled. XynR8(N58D) is an engineered and highly active xylanase originating from the rumen fungus Neocallimastix patriciarum. In this study, XynR8(N58D) was extracellularly over-expressed by Pichia pastoris. The resulting crude enzyme solution, with a purity of XynR8(N58D) of over 80%, was used to prepare the cross-linked enzyme aggregates (CLEA) of XynR8(N58D). Specific activity of the crude enzyme solution was 11,599.39 IU/mg, and that of CLEA was 6129.42 IU/mg. The immobilization yield and the immobilization efficiency were 62.68 ± 16.20% and 84.31 ± 3.11%, respectively. The thermostability, stress tolerance, and shelf life of CLEA were significantly better than those of the free enzyme. The free enzyme and CLEA both effectively decomposed insoluble xylan and autoclaved corncob powders. Therefore, XynR8(N58D) made into CLEA not only maintained high activity, but also improved its stability and permitted its reuse or recyclability. Both forms of the enzyme can effectively degrade lignocellulosic biomass without relying on chemical pretreatment to reduce recalcitrance of the biomass structure. The application of XynR8(N58D) and its CLEA to biomass degradation can help establish an eco-friendly and more cost-effective process.

A comparison of dual-enzyme immobilization by magnetic nanoparticles and magnetic enzyme aggregates for cascade enzyme reactions

Immobilized enzymes have been widely used for their efficiency, economy, and environment friendly. In this case, a simpler and effective immobilization method has been developed. In this study, the enzyme immobilized by magnetic beads with genipin (MGE) was prepared by mixing genipin-modified nano-Fe3O4 with (R)− 1-phenylethanol dehydrogenase ((R)-PEDH) and recombinant glucose dehydrogenase (rGDH), and the magnetic cross-linked enzyme aggregates (MCLEAs) was prepared by stirring a mixture of the sulfur precipitate of the (R)-PEDH and rGDH, poly-L-lysine, and cross-linkers. When o-phthalaldehyde (o-PA) was used as a cross-linking agent for the MCLEAs preparation, a protein loading of 99.9% and 62.93% recovery activity of (R)-PEDH and 70.12% of rGDH were obtained. Compared to the MGE, the MCLEAs possessed better enzyme activity recovery. Furthermore, this study tried the synthesis of (R)− 1-(furan-2-yl) ethanol by the immobilized enzymes and obtained a concentration of 1.10 mM for the MCLEAs and 0.24 mM for the MGE at 48 h. This study explored a facile method for co-immobilization of (R)-PEDH and rGDH to synthesize (R)− 1-(furan-2-yl) ethanol.