Amphiphilic hollow carbonaceous microsphere-encapsulated enzymes: Facile immobilization and robust biocatalytic properties

This study reports a general strategy for the encapsulation of various enzymes in amphiphilic hollow carbonaceous microspheres (CMs). We found that enzymes could be spontaneously encapsulated in the interior cavity of the CMs via hydrophobic interactions. Due to strong hydrophobic interactions and robust confinement, leaching of the physically adsorbed enzymes is substantially restricted. As a novel immobilization matrix, the CMs display many significant advantages. They are capable of encapsulating a wide range of proteins/enzymes of different sizes, which can then be used in both aqueous and organic media and retain high activity, stability, and excellent reusability. Moreover, CMs could be considered as efficient microreactors that provide a favorable microaqueous environment for enzymes in organic systems. Therefore, this doubly effective and simple immobilization approach can be easily expanded to many other enzymes and has great potential in a variety of enzyme applications.     

Improving the properties of chitosan as support for the covalent multipoint immobilization of chymotrypsin

Changing gel structure and immobilization conditions led to a significant improvement in the covalent multipoint attachment of chymotrypsin on chitosan. The use of sodium alginate, gelatin, or kappa-carrageenan, activation with glutaraldehyde, glycidol, or epichlorohydrin, and addition of microorganisms followed by cellular lysis allowed the modification of the gel structure. Immobilization yields, recovered activities, and stabilization factors at 55 and 65 degrees C were evaluated. Enzyme immobilization for 72 h at pH 10.05, 25 degrees C and reduction with NaBH 4 in chitosan 2.5%-carrageenan 2.5%, with addition of S. cerevisiae 5% and activation with epichlorohydrin led to the best derivative, which was 9900-fold more stable than the soluble enzyme. This support allowed an enzyme load up to 40 mg chymotrypsin x g gel (-1). The number of covalent bonds, formed by active groups in the support and lysine residues of the enzyme, can explain the obtained results. SEM images of the gel structures corroborate these conclusions.     

Polyclonal anti-chymotrypsin antibodies suitable for oriented immobilization of chymotrypsin

Summary Polyclonal antibodies obtained from the serum of pig immunized by DIP-chymotrypsin were separated into two fractions, anti-chymotrypsin IgG I and anti-chymotrypsin IgG II, by the use of chromatography on biospecific adsorbents prepared by chymotrypsin (CHT) immobilization in different ways. IgG I, which did not decrease the proteolytic activity of CHT, was obtained by biospecific affinity chromatography on a column of Sepharose with CHT attached through an immobilized polyvalent inhibitor, antilysin (AL). IgG II was isolated from the fraction unretarded on the column of CHT-AL-Sepharose by chromatography on a column with CHT directly attached to AH-Sepharose activated by glutaraldehyde. IgG II strongly decreased the proteolytic activity of CHT. Comparison of the proteolytic activity of CHT covalently bound to AH-Sepharose with that of CHT noncovalently intercepted by biospecific sorption to Sepharose with attached anti-CHT-IgG I showed a great advantage of the immobilization of CHT by oriented adsorption.     

Functionalized polymeric liposomes. Efficient immobilization of alpha chymotrypsin

A polymerizable phospholipid has been synthesized having a latent aldehyde moiety in the head group (1). Photopolymerized vesicles which have been prepared from this phosphatidylcholine have been successfully conjugated to alpha chymotrypsin. A high degree of loading was achieved with significant retention of enzymatic function.     

Asymmetric hydrolysis of dimethyl 3-phenylglutarate catalyzed by Lecitase Ultra: Effect of the immobilization protocol on its catalytic properties

The asymmetric hydrolysis of dimethyl 3-phenylglutarate (1) by different immobilized preparations of a phospholipase A₁ (Lecitase Ultra (LECI)) at pH 7 and 25 °C has been studied. Agarose beads coated with octyl, cyanogen bromide (CNBr), polyethylenimine (PEI) or glyoxyl groups were used as supports for the immobilization of LECI. The different derivatives behaved very differently in terms of activity, discrimination between 1 and methyl 3-phenylglutarate (2) resulting from the hydrolysis of 1, enantioselectivity (in the hydrolysis of 1 to produce R or S-2) and enantiospecificity in the hydrolysis of R-2 and S-2. Using 1 mM of 1, CNBr-LECI showed the highest activity (13 × 10⁻³ μmol/min mg protein) while octyl-LECI was about 20 times less active. All the enzyme preparations mainly produced (S)-2, but with different enantioselectivity. CNBr-Lecitase was the most enantioselective, producing the S-2 10 fold more rapidly than the R-2, while octyl-Lecitase gave only half of that difference.LECI adsorbed on octyl-agarose allowed to get a yield up to 99% of S-2 (ee was 66%). The reaction stopped in the monoester and no isomer of this compound was further hydrolyzed by the enzyme. However, when the reaction was catalyzed by the other immobilized LECI preparations, the enzyme was able to hydrolyze mainly the minority isomer, permitting to improve the ee of the remaining S-2. The best results were obtained using CNBr-LECI, which gave (S)-methyl-3-phenylglutarate with a yield of 80% and an ee exceeding 99%.     

Asymmetric hydrolysis of dimethyl 3-phenylglutarate catalyzed by Lecitase Ultra®: Effect of the immobilization protocol on its catalytic properties

The asymmetric hydrolysis of dimethyl 3-phenylglutarate (1) by different immobilized preparations of a phospholipase A₁ (Lecitase Ultra (LECI)) at pH 7 and 25 °C has been studied. Agarose beads coated with octyl, cyanogen bromide (CNBr), polyethylenimine (PEI) or glyoxyl groups were used as supports for the immobilization of LECI. The different derivatives behaved very differently in terms of activity, discrimination between 1 and methyl 3-phenylglutarate (2) resulting from the hydrolysis of 1, enantioselectivity (in the hydrolysis of 1 to produce R or S-2) and enantiospecificity in the hydrolysis of R-2 and S-2. Using 1 mM of 1, CNBr-LECI showed the highest activity (13 × 10⁻³ μmol/min mg protein) while octyl-LECI was about 20 times less active. All the enzyme preparations mainly produced (S)-2, but with different enantioselectivity. CNBr-Lecitase was the most enantioselective, producing the S-2 10 fold more rapidly than the R-2, while octyl-Lecitase gave only half of that difference.LECI adsorbed on octyl-agarose allowed to get a yield up to 99% of S-2 (ee was 66%). The reaction stopped in the monoester and no isomer of this compound was further hydrolyzed by the enzyme. However, when the reaction was catalyzed by the other immobilized LECI preparations, the enzyme was able to hydrolyze mainly the minority isomer, permitting to improve the ee of the remaining S-2. The best results were obtained using CNBr-LECI, which gave (S)-methyl-3-phenylglutarate with a yield of 80% and an ee exceeding 99%.     

Some kinetic properties of dogfish chymotrypsin

A comparison of some kinetic properties was made between bovine chymotrypsin and chymotrypsin isolated from the spiny dogfish (Squalus acanthias). The major difference between the two enzymes was observed in the molecular activity (kcat), with the dogfish enzyme being two to three times more active than the bovine enzyme. The exact difference was dependent on the substrate and assay conditions. The two enzymes showed similar kinetic properties with respect to the following: similar inhibition by indole and naphthol derivatives, activities vs BTEE and a series of n-fatty acid esters of p-nitrophenol, KM values, optimal pH and temperature and activation energies.     

Biological sulfide oxidation using autotrophic Thiobacillus sp.: evaluation of different immobilization methods and bioreactors

Aims:  Evaluation of various immobilization methods and bioreactors for sulfide oxidation using Thiobacillus sp. was studied.
Methods and Results:  Ca-alginate, K-carrageenan and agar gel matrices (entrapment) and polyurethane foam and granular activated carbon (adsorption) efficacy was tested for the sulfide oxidation and biomass leakage using immobilized Thiobacillus sp. Maximum sulfide oxidation of 96% was achieved with alginate matrix followed by K-carrageenan (88%). Different parameters viz. alginate concentration (1%, 2%, 3%, 4% and 5%), CaCl₂ concentration (1%, 2%, 3%, 4% and 5%), bead diameter (1, 2, 3, 4 and 5 mm), and curing time (1, 3, 6, 12 and 18 h) were studied for optimal immobilization conditions. Repeated batch experiments were carried out to test reusability of Ca-alginate immobilized beads for sulfide oxidation in stirred tank reactor and fluidized bed reactor (FBR) at different sulfide concentrations.
Conclusions:  The results proved to be promising for sulfide oxidation using Ca-alginate gel matrix immobilized Thiobacillus sp. for better sulfide oxidation with less biomass leakage.
Significance and Impact of the Study:  Biological sulfide oxidation is gaining more importance because of its simple operation. Present investigations will help in successful design and operation of pilot and industrial level FBR for sulfide oxidation.     

Effect of immobilization on stability and kinetic properties of alpha-L-fucosidase from Turbo cornutus

An amount of alpha-L-fucosidase from T. cornutus liver was copolymerized with glutaraldehyde using bovine serum albumin as the carrier protein. The properties of the native, the soluble enzyme polymer complex, and the insoluble enzyme polymer complex were studied and compared under various conditions of pH, temperature, substrate, and inhibitor concentration. Native alpha-L-fucosidase was heat labile and lost more than 85% of its activity when incubated at 55 degrees C for 5 min. In contrast, under equivalent incubation conditions, both the soluble and the insoluble enzyme polymer complexes exhibited enhanced resistance to thermal inactivation and after 5 min lost only 65 and 40% of their original activity, respectively. Polymerzation also resulted in the shift of pH optima towards the acidic range, a decrease in activation energy and a change in the apparent K(m) values towards the p-nitrophenyl-alpha-L-fucopyranoside substrate.     

Enzyme immobilization by fouling in ultrafiltration membranes: Impact of membrane configuration and type on flux behavior and biocatalytic conversion efficacy

Enzyme-immobilization in membranes accomplished by fostering membrane fouling was evaluated. Four different membrane configurations and five membranes were compared for immobilization of alcohol dehydrogenase (ADH) in terms of enzyme loading, permeate flux and final biocatalytic conversion. The membrane configuration impacted the efficiency of the enzyme-immobilization as well as the biocatalytic-membrane reaction, and the “sandwich mode”, with an extra polypropylene support above the membrane skin layer, worked best due to its high flux and stable conversion. Among the membranes, a GR51PP polysulphone membrane allowed for the highest flux during the reaction with the enzyme-immobilized membrane. At the same time, the lowest enzyme loading and low reaction stability were achieved for this membrane. Satisfactory enzyme loadings, stable conversions, but low flux rates were obtained for the PLTK and PLGC regenerated cellulose membranes. With these two highly hydrophilic membranes, the ADH enzyme activity was fully retained even after 24 h of storage of the membrane. Filtration blocking and resistance models were used to analyze the fouling/immobilization mechanisms and give explanations for the different results. The work confirms that fouling-induced enzyme immobilization is a promising option for enhancing biocatalytic productivity, and highlights the significance of the membrane type and configuration for optimal performance.     

Multi-faceted strategy based on enzyme immobilization with reactant adsorption and membrane technology for biocatalytic removal of pollutants: A critical review

In the modern era, the use of sustainable, environmentally friendly alternatives for removal of recalcitrant pollutants in streams resulting from industrial processes is of key importance. In this context, biodegradation of phenolic compounds, pharmaceuticals and dyes in wastewater by using oxidoreductases offers numerous benefits. Tremendous research efforts have been made to develop novel, hybrid strategies for simultaneous immobilization of oxidoreductase and removal of toxic compounds. The use of support materials with the options for combining enzyme immobilization with adsorption technology focused on phenolic pollutants and products of biocatalytic conversion seems to be of particular interest. Application of enzymatic reactors based on immobilized oxidoreductases for coupling enzyme-aided degradation and membrane separation also attract still growing attention. However, prior selection of the most suitable support/sorbent material and/or membrane as well as operational mode and immobilization technique is required in order to achieve high removal efficiency. Thus, in the framework of this review, we present an overview of the impact of support/sorbent material on the catalytic properties of immobilized enzymes and sorption of pollutants as well as parameters of membranes for effective bioconversion and separation. Finally, future perspectives of the use of processes combining enzyme immobilization and sorption technology as well as application of enzymatic reactors for removal of environmental pollutants are discussed.     

Effect of tree species and soil properties on nutrient immobilization in the forest floor

To investigate the effect of tree species and soil properties on organic matter accumulation and associated nutrients, an area-based sampling of the forest floor was carried out in a 28 years old species trial including Norway spruce, Douglas fir, beech, and common oak at two sites, a poor and sandy soil, and a fertile loamy soil.The accumulation of C, N and P in the forest floor was significantly higher at the sandy site than at the loamy site under all species. At the loamy site, oak was characterized by lesser accumulation of C, N and P than the other species. Remarkably, the C/N-ratios showed no substantial differences, whereas the C/P-ratios were significantly higher at the sandy site for all species. pH was significantly lower at the sandy site for all species, and among the species, pH was lower in the conifer forest floors than in the broadleave forest floors. The concentration of ammonium, nitrate and phosphate in the soil solution was much higher at the loamy site under all species showing a stronger microbial activity. It is therefore hypothesized that the differences in accumulation rates were, at least partly, caused by differences in the mineralization regimes. Strong root infiltration in the forest floors at the sandy site compared to almost none at the loamy site, is probably responsible for the differences in mineralization rate due to competition between the organic matter decomposers and the tree-roots/mycorrhiza for nutrients.     

Influence of immobilization on properties of polyphosphate glucokinase

Polyphosphate glucokinase from Mycobacterium tuberculosis H37Ra was covalently bound to the glutaraldehyde-activated collagen coating silica gel, to the nylon, and to the CNBr-activated Sepharose. After immobilization kinetic properties of the enzyme were altered.     

Effect of immobilization on the physical and kinetic properties of soluble and insoluble trypsin-albumin polymers

Bovine trypsin was crosslinked to human serum albumin (HSA) with glutaraldehyde to form soluble and insoluble copolymers. The physical and kinetic properties of trypsin and trypsin-HSA polymers were compared. Trypsin was heat labile, retaining only 24% of its enzymic activity after heating for 5 min at 60 degrees C. In contrast, under the same condition both the soluble and insoluble trypsin-HSA polymers showed enhanced resistance to heat in-activation, retaining 81 and 100% of their original activities, respectively. The trypsin-HSA polymers also showed shifts in pH optima, an increase in activation energy, and a broadening of their pH stability profiles.