Soluble and immobilized catalase

This article examines the effect of pressure on the steady-state kinetics and long-term deactivation of the enzyme catalase supported on porous alumina. The reaction studied is the decomposition of hydrogen peroxide. The results of studies carried out in a continuous stirred-tank reactor under isothermal conditions are presented and compared with results obtained for soluble catalase. For soluble catalase, it is found that in the range of pressures studied, the oxygen flow rate increases with increase in pressure up to a certain value and then decreases. Hydrogen peroxide concentration appears to have a strong influence on pressure effects. With immobilized catalase, the pressure effects are not as prominent. Fluorescent microscopy studies of the immobilized enzyme suggest that this is probably because of pore diffusional limitations.     

固定化过氧化氢酶的制备及其抗氧化作用

以烟用醋酸纤维的生物化学改性为目标,研究了以壳聚糖为载体时,吸附交联固定化过氧化氢酶的条件,并考察了固定化酶的性质。结果表明,固定化的最佳条件为:加酶量(酶活2×104C IU/m l)6m l,3%壳聚糖20m l,乙二醛浓度6%(w/v),交联剂用量100m l,吸附时间0.5 h,交联时间2.5h,酶活收率可达42.9%。过氧化氢酶固定化后,动学参数Km值为61.7mmol/L;对活性氧具有较好清除作用。     

Electrooxidation of phenol by catalase immobilized on graphite electrodes

Electrocatalytic properties of catalase (CAT) immobilized on graphite and soot to mediate electrooxidation of phenol have been investigated. The kinetic parameters--Km, k(s), deltaG*Ar and Z0 of the process studied were calculated. Conclusions on a probable mechanism of the biocatalytic and electrochemical process observed were drawn from the calculated values of activation and kinetic parameters. A quantitative UV-spectrophotometrical approach was used as an analytical tool. The electrochemical oxidation of phenol was examined with potentiodynamic and polarization curves' method.     

Oscillatory symmetry breaking in the Soai reaction

A kinetic model of spontaneous amplification of enantiomeric excess in the autocatalytic addition of diisopropylzinc to prochiral pyrimidine carbaldehydes is extended by a negative feedback process. Simulations based on the extended model result in large-amplitude oscillations both in a continuous-flow stirred tank reactor (CSTR) and in a semibatch configuration under optimized initial conditions. When sustained oscillations are maintained in a CSTR, no enantiomeric product distribution could be observed in the calculated series; the system keeps its initial enantiomeric ratio endlessly. During damped oscillations, or steady-state conditions, however, chiral amplification from a very small initial enantiomeric excess to more than 99% occurs in a semibatch configuration. Calculations indicated spontaneous enantiomeric product enrichment (i.e., accumulation of one of the enantiomers at the cost of the other one) from strictly achiral starting conditions in a semibatch configuration due to the inherent numerical error of the integrator method, which can be regarded as a model of the statistical fluctuation in the numbers of enantiomeric molecules.     

Microcalorimetric studies on catalase reaction and inhibition of catalase by cyanide ion

As Chance et al. [1, 2 and 3] proposed, the decomposition of hydrogen peroxide catalyzed by catalase is an overall first-order reaction. In this paper, we have studied this enzyme-catalyzed reaction with a thermokinetic method. The rate constant and the molar reaction enthalpy of this reaction have been measured. At 310.15 K and pH=8.2, k_cat=1.75×10⁶ l mol⁻¹ s⁻¹, Δ_rH_m=88.99 kJ mol⁻¹. Furthermore, we have studied the competitive inhibition of catalase by cyanide ion and reported some correlated parameters.     

Some kinetic parameters and inactivation of catalase immobilized on modified polyvinylalcohol

Polyvinylalcohol crosslinked with terephthaldicarboxaldehyde and was modified with 2-amino-4,6-dichloro-s-triazine. Optimum conditions for immobilization of catalase on modified and gelatine-coated modified polyvinylalcohol were investigated. Activity variations with respect to pH, temperature, stability behavior, andk _m(appl) values were investigated for the native and immobilized catalases. Rate constants for H₂O₂ decomposition and for inactivation of immobilized catalase were determined using a discontinuous batch-type reactor. The influence of H₂O₂ concentration on the catalase inactivation was investigated.     

Study of catalase immobilized on a silicate matrix for non-aqueous biocatalysis

Catalytic activity of catalase (CAT) immobilized on a modified silicate matrix to mediate decomposition of meta-chloroperoxibenzoic acid (3-CPBA) in acetonitrile has been investigated by means of quantitative UV-spectrophotometry. Under the selected experimental conditions, the kinetic parameters: the apparent Michaelis constat (K _M ), the apparent maximum rate of enzymatic reaction (V _max ^app ), the first order specific rate constants (k _sp ), the energy of activation (E _a ) and the pre-exponential factor of the Arrhenius equation (Z₀) were calculated. Conclusions regarding the rate-limiting step of the overall catalytic process were drawn from the calculated values of the Gibbs energy of activation ΔG^*, the enthalpy of activation ΔH^*, and the entropy of activation ΔS^*.     

Biodiesel fuel production by the transesterification reaction of soybean oil using immobilized lipase

The enzymatic alcoholysis of soybean oil with methanol and ethanol was investigated using a commercial, immobilized lipase (Lipozyme RMIM). The effect of alcohol (methanol or ethanol), enzyme concentration, molar ratio of alcohol to soybean oil, solvent, and temperature on biodiesel production was determined. The best conditions were obtained in a solvent-free system with ethanol/oil molar ratio of 3.0, temperature of 50 degrees C, and enzyme concentration of 7.0% (w/w). Three-step batch ethanolysis was most effective for the production of biodiesel. Ethyl esters yield was about 60% after 4 h of reaction.     

Asymmetric Cu-catalyzed Henry reaction using chiral camphor Schiff bases immobilized on a macromolecular chain

Immobilized catalysts have attracted chemists’ attention for long time because of convenient recycling, which is very important for some special catalyst even immobilizations accompanying the decrease of catalytic activity and selectivity. Our group focused on the developing chiral catalysts with camphor framework to catalyze various asymmetric reactions for long time. For easily recycling the unique chiral catalysts, a series of polymer catalysts with chiral camphor unit were synthesized by RAFT polymerization. Herein, the performance of the synthesized polymer chiral catalysts was reported by catalyzing asymmetric Henry reaction. After optimizing the reaction conditions, the synthesized chiral polymer catalyst provides a good yield and enantioselectivity to the reaction of p-nitrobenzaldehyde and nitromethane. In the meantime, the recycles and reused properties of synthesized polymer catalysts were examination by the model asymmetric Henry reaction. The catalyzed activities and enantioselectivities did not show obviously decrease until recycling five times.     

Enzyme sequence and competition electrodes based on immobilized glucose oxidase,peroxidase and catalase

The toxicologically important peroxidase substrates bilirubin and aminopyrine can be determined by combination of immobilized glucose oxidase, horseradish peroxidase and catalase, forming so-called enzyme sequence and enzyme competition electrodes. Bilirubin and aminopyrine are determined in the concentration range 5–50 μM.     

Characterization of immobilized glucose oxidase—catalase and their deactivation in a fluid-bed reactor

2-Amino-4-chloro-s-triazine, a derivative of DEAE-cellulose, and acrolein/styrene copolymer were used as supports for the immobilization of glucose oxidase and catalase after being modified with diaminohexane followed by glutaraldehyde. Immobilization was carried out with optimum glucose oxidase-catalase ratios. The activity variations of the immobilized dual-enzyme systems were investigated in relation to pH and temperature. Time-dependent gluconic acid production resulting from the oxidation of glucose was monitored in a recycling fluid-bed reactor. The deactivation rates of glucose oxidase and catalase were investigated according to the first-order reaction kinetics depending on the presence of the intermediate product H₂O₂.     

Selection of bovine catalase aptamers using non-SELEX

In this research, we used the non-SELEX method to successfully select an aptamer that binds to the protein target (bovine catalase) with a K(D) value in the low micro molar range. The time window was determined for the target and aptamer library by optimizing the buffer conditions using 3 × Tris-glycine-potassium phosphate (TGK) buffer as the run buffer and 1× TGK as the selection buffer to give the biggest complex peak. Fractions were collected by multistep nonequilibrium capillary electrophoresis of equilibrium mixtures (NECEEM)-based partitioning for three rounds of selection. The fractions from each round were enriched using PCR and the progress of selection was monitored using bulk affinity analysis. Fraction 2 was determined to have the optimal bulk affinity (0.75 μM) and this enriched library was cloned and sequenced giving four aptamer sequences. These sequences were verified using affinity capillary electrophoresis (CAT 1 0.237 μM) and fluorescence intensity measurements (CAT 1 0.430 μM). The specificity of the aptamer was also determined by fluorescence intensity measurements. The results showed that the aptamer with the highest binding affinity showed at least a 100-fold decrease in affinity toward four other proteins (i.e. lysozyme, trypsinogen, chymotrypsinogen A, and myoglobin) tested and this confirmed that the aptamer exhibited a distinct specificity toward bovine catalase. This aptamer will be useful in biosensing, Western blot, and biomarker identification.     

Oscillatory and stationary convective patterns in a reaction driven gravity current

Horizontally propagating chemical fronts are studied in a thin solution layer of the acid-catalyzed chlorite-tetrathionate reaction. Unusual cellular patterns develop when significant amount of autocatalyst is bound to polyelectrolyte with low mobility: both oscillatory and stationary patterns evolve as a result of the interaction between the reaction front and the superposed gravity current. The concentration of the polyelectrolyte regulating the velocity of front propagation serves as a bifurcation parameter for switching between the two basic patterns.     

Polymer ultrathin films with immobilized photosynthetic reaction center proteins

Properties of mixed monolayers of lipid-photosynthetic reaction center proteins (RC) were studied and the optimum conditions for stable films fabrication were determined. The following synthetic: N-acryloylphosphatidylethanolamine (ACPE), tetracosa-11, 13-diinoic acid (TDA), pentacosa-10, 12-diinoic acid (PDA), dioctadecyldienoylphosphatidylcholine (DODL) and natural lipids: L-α-phosphatidylethanolamine (PE), L-α-phosphatidylcholine (PC) were used. The rate of polymerization of the mixed ACPE-RC and TDA-RC monolayers is lower in comparison with corresponding values for pure lipid-like monomers on air/water interface. The optical and photoelectrical measurements provide evidence for an orientation of RCs on interface. Hydrophilic H-subunit in monomeric and polymeric ACPE-RCs, and monomeric DODL-RCs monolayers is preferentially oriented towards water as in the pure RC monolayers. Opposite orientation was found with TDA-RCs and PDA-RCs films. No preferential orientation for lipid-RCs from C. aurantiacus monolayers was found because of the RCs having low assymmetry of hydrophobic subunits (M and L).     

Modification of milk using immobilized enzymes

The preparation and use of immobilized enzyme systems for the modification of the principle components of milk—casein, lactose, and butterfat—are discussed. Design of a pilot-scale bioreactor is described. Also the use of tea polyphenols as a crosslinking agent is reported. A review of methods for hydrolyzing lactose and characteristics of a concentrated liquid sweetener derived from dairy byproducts is presented. Further, the application of immobilized esterases to modify milk, cream, and butterfat is reported.     

Recovery of uranium using immobilized polyhydroxybenzene

In order to develop a new adsorbent for uranium, the adsorption of uranium from seawater by immobilized polyhydroxybenzene compounds has been investigated. Polyhydroxybenzene compounds having adjacent hydroxy groups, such as catechol and pyrogallol, form stable five-membered chelate ring with uranyl ion. The immobilized polyhydroxybenzene compounds have an excellent ability to adsorb uranium from seawater. Especially, the immobilized pyrogallol, having two chelating positions for uranyl ion, is the most suitable adsorbent for uranium recovery from seawater. This adsorbent also has a selectivity for uranium.     

High temporal resolution monitoring of enzyme reaction and inhibition using optically gated vacancy capillary electrophoresis and immobilized enzyme

A novel method for monitoring of enzyme reaction and inhibition with high temporal resolution was developed by using optically gated vacancy capillary electrophoresis (OGVCE) with laser-induced fluorescence (LIF) detection and immobilized enzyme. Trypsin cleavage reaction and inhibition were investigated by the presented OGVCE-LIF assay, using carboxyfluorescein (FAM) end-labeled Angiotensin as the substrate and commercially available immobilized trypsin. The substrate and the product were continuously loaded into the capillary by the electroosmotic flow while the immobilized enzyme remained in the sample vial. Substrate consumption and product formation were monitored simultaneously at 5 s interval during the whole reaction time. The enzymatic reaction rates obtained from the substrate and the product were highly consistent. The enzyme activity and the Michaelis constants of trypsin cleavage reaction, as well as the inhibition constant (for reversible competitive inhibitor) and the inhibition fraction (for irreversible inhibitor), were obtained. It was showed that the reported OGVCE-LIF method can perform fast, accurate, sensitive and reproducible CE enzyme assay with high temporal resolution, thus has great potential in application of the enzyme-substrate systems with fast reaction rate and the fluorescent substrate and products.     

Affinity purification of antibodies using immobilized FB domain of protein A.

A continuous method for the efficient digestion of protein A into active fragments (FB, Mr = 7000) using immobilized trypsin was developed. These fragments originate from almost identical five-repeated monovalent Fc-binding units of 58 residues each. The fragments obtained were found to be similar to the recently described genetically engineered fragment B. Antibody-binding characteristics of the FB domain and also of intact protein A, immobilized on to adipic dihydrazide-modified Eupergit CB6200 beads, were investigated. Based on the experimental data obtained, a high-performance liquid chromatographic column containing C30N Eupergit C-immobilized FB domain was prepared and its performance in antibody purification was compared with that of Eupergit C-immobilized intact protein A.