ABSTRACT
Heterogeneous biocatalysts were prepared by adsorbing T. lanuginosus lipase (TLL) onto uncalcined (SBAUC-TLL) and calcined (SBAC-TLL) SBA-15, using ammonium fluoride as a pore expander to facilitate TLL immobilization. At an enzyme load of 1 mg/g, high immobilization yields (>90 %) and recovered activities (>80 % for SBAUC-TLL and 70 % for SBAC-TLL) were achieved. When increasing the enzyme load to 5 mg/g, the immobilization yield of SBAUC-TLL was 80 %, and the recovered activity was 50 %, while SBAC-TLL had a yield of 100 % and a recovered activity of 36 %. Crosslinking with glutaraldehyde (GA) was conducted to improve stability (SBAUC-TLL-GA and SBAC-TLL-GA). Although SBAC-TLL-GA lost 25 % of initial activity after GA modifications, it exhibited the highest thermal (t1/2 = 5.7 h at 65 °C), when compared to SBAC-TLL (t1/2 = 12 min) and the soluble enzyme (t1/2 = 36 min), and operational stability (retained 100 % activity after 5 cycles). Both biocatalysts presented high storage stability since they retained 100 % of initial activity for 30 days. These results highlight SBA-15's potential as an enzyme support and the protocol's efficacy in enhancing stability, with implications for industrial applications in the food, chemical, and pharmaceutical sectors.
Subject(s)
Biocatalysis , Enzyme Stability , Enzymes, Immobilized , Lipase , Silicon Dioxide , Enzymes, Immobilized/chemistry , Enzymes, Immobilized/metabolism , Lipase/chemistry , Lipase/metabolism , Silicon Dioxide/chemistry , Porosity , Temperature , Adsorption , Hydrogen-Ion Concentration , Eurotiales/enzymology , Kinetics , Glutaral/chemistryABSTRACT
Assembling metal-organic frameworks (MOFs) into ordered multidimensional porous superstructures promises the encapsulation of enzymes for heterogeneous biocatalysts. However, the full potential of this approach has been limited by the poor stability of enzymes and the uncontrolled assembly of MOF nanoparticles onto suitable supports. In this study, a novel and exceptionally robust Ni-imidazole-based MOF was synthesized in water at room temperature, enabling in situ enzyme encapsulation. Based on this MOF platform, we developed a DNA-directed assembly strategy to achieve the uniform placement of MOF nanoparticles onto bacterial cellulose nanofibers, resulting in a distinctive "branch-fruit" structure. The resulting hybrid materials demonstrated remarkable versatility across various catalytic systems, accommodating natural enzymes, nanoenzymes, and multienzyme cascades, thus showcasing enormous potential as universal microbioreactors. Furthermore, the hierarchical composites facilitated rapid diffusion of the bulky substrate while maintaining the enzyme stability, with â¼3.5-fold higher relative activity compared to the traditional enzyme@MOF immobilized in bacterial cellulose nanofibers.
Subject(s)
Enzymes, Immobilized , Nanofibers , Enzymes, Immobilized/chemistry , Cellulose , Fruit , DNA/chemistryABSTRACT
ß-d-Galactosidase is an important enzyme in the dairy industry, and the enzyme from the yeast Kluyveromyces lactis is most widely used. Here, we report immobilization of the enzyme on a silica/chitosan composite support, devised to have 10% and 20% chitosan (SiQT10 and SiQT20, respectively). Morphological and textural characterizations showed that chitosan is dispersed in micrometric regions in silica. For comparison, a silica organofunctionalized with 3-aminopropyltrimethoxysilane (SiO2aptms) was prepared. Performance of the biocatalysts was tested for lactose hydrolysis, and the enzyme immobilized in SiQT10 and SiQT20 composites showed higher efficiency (62% and 47%, respectively) compared with the enzyme in SiO2aptms. Operational stability in this system was evaluated for the first time. After 200â¯h of continuous use in a fixed-bed reactor, SiQT10 remained with approximately 90% activity. Thus, in addition to demonstrating compatibility for food processing, these results align the enzyme stabilization properties of chitosan with the mechanical resistance of silica.
Subject(s)
Chitosan/chemistry , Enzymes, Immobilized/chemistry , Silicon Dioxide/chemistry , beta-Galactosidase/chemistry , beta-Galactosidase/metabolism , Enzyme Stability , Enzymes, Immobilized/metabolism , Food Handling , Hydrolysis , Kluyveromyces/enzymology , Lactose/metabolismABSTRACT
Immobilized enzyme reactors based on nanoparticulate carriers are becoming increasingly popular. A toolbox of methods is usually utilized for their characterization in order to be capable of assessing their suitability for the intended purpose. In this work, as a model system pepsin was conjugated to gold nanoparticles (GNPs) by a straightforward adsorptive immobilization process. The success of the immobilization procedure was monitored by Vis spectroscopy via shifts of the localized surface plasmon resonance (LSPR) band, size characterization by dynamic light scattering (DLS), and ζ-potential determinations by electrophoretic light scattering. DLS revealed a significantly different hydrodynamic diameter for unmodified GNPs and protein-coated GNPs. However, the hydrodynamic diameters of pepsin-coated GNPs obtained with various concentrations of pepsin in the coating solution were not significantly different. In contrast, Taylor dispersion analysis allowed measuring the slight differences in the hydrodynamic radius. It provided also information on the viscosity of GNP suspensions and diffusion coefficients for the various pepsin@GNP preparations. For the determination of the pepsin surface coverage on the GNPs results from indirect protein quantitation of non-immobilized pepsin by Lowry assay were compared to direct measurement of immobilized pepsin by resonant mass measurements. Reasonable agreement was found. Accurate information on enzyme coverage is of utmost importance for a representative comparison of the turnover numbers and catalytic efficiencies of nanoparticulate immobilized enzyme reactors, which is shown by the adsorptively immobilized pepsin@GNP as model system.
Subject(s)
Enzymes, Immobilized/chemistry , Enzymes, Immobilized/metabolism , Gold/chemistry , Metal Nanoparticles/chemistry , Pepsin A/chemistry , Pepsin A/metabolism , Animals , Particle Size , Surface Plasmon ResonanceABSTRACT
This research suggests the use of new hybrid biomaterials based on methylotrophic yeast cells covered by an alkyl-modified silica shell as biocatalysts. The hybrid biomaterials are produced by sol-gel chemistry from silane precursors. The shell protects microbial cells from harmful effects of acidic environment. Potential use of the hybrid biomaterials based on methylotrophic yeast Ogataea polymorpha VKM Y-2559 encapsulated into alkyl-modified silica matrix for biofilters is represented for the first time. Organo-silica shells covering yeast cells effectively protect them from exposure to harmful factors, including extreme values of pH. The biofilter based on the organic silica matrix encapsulated in the methylotrophic yeast Ogataea polymorpha BKM Y-2559 has an oxidizing power of 3 times more than the capacity of the aeration tanks used at the chemical plants during methyl alcohol production. This may lead to the development of new and effective industrial wastewater treatment technologies.