Studies on immobilized enzymes. IX. Preparation and properties of aminoacylase covalently attached to halogenoacetylcelluloses

Immobilization of mold aminoacylase (N-acylamino acid amidohydrolase, EC 3.5.1.14) was investigated by covalently binding the enzyme to halogenoacetylcelluloses. As a result, the iodoacetylcellulose was found to be the best carrier among the halogenoacetylcelluloses. The yield of activity of the insoluble aminoacylase relative to that of the native aminoacylase used was 40–50%, and the specific activities of both enzyme preparations were the same within the limits of error of the estimation.     

Acylation of Amino Acids by Aminoacylase in Non-Conventional Media

N-Acylation of amino acids by aminoacylase (EC 3.5.1.14) isolated from pig kidney was investigated. In water containing organic solutions native aminoacylase proved to be unsuitable for acylation reactions. Covalent immobilization enhanced the stability of aminoacylase in organic solvents (dimethylformamide and dioxane).

The support gel beads showed extraordinary swelling behaviour in dimethylformamide solutions of different water content with respect to their liquid uptake and the temperature sensitivity of swelling.

N-Acylation activity of immobilized enzyme proved to be sufficient in case of L-methionine as substrate and acetate as acylating agent. In addition, the peptide (Ala-Ala) formation was unambiguous but the reaction was much slower than acylation under the given conditions.     

Aminoacylase I from hog kidney: anion effects and the pH dependence of kinetic parameters

The hydrolysis of acetylamino acids by highly purified hog kidney aminoacylase I (N-acylamino acid amidohydrolase, EC 3.5.1.14) was investigated using flow injection analysis to determine reaction rates. We show that the distinctly bell-shaped pH versus activity profiles observed in previous studies do not reflect protonic equilibria in the enzyme, but were created by buffer effects. At low pH, anions such as phosphate, nitrate or chloride markedly increase Km. These effects are reversed at higher pH. In zwitterionic 'Good' buffers (Mes, Mops, and Bicine), maximal velocities are almost independent of pH between 6.5 and 9 for all substrates studied (Ac-LAla, Ac-LGlu, Ac-LMet, Ac-LPhe). Below pH 6.5, the catalytic constants decrease with pH, apparently due to the protonation of a carboxylate with a pKa of 5.5-6. The pH dependence of Km markedly varies among different substates. We conclude that the observed profiles all result from the dissociation of an active-site residue with a pKa of 8-8.5, which we tentatively identify as an active-site cysteine residue. A working model of aminoacylase catalysis is presented that accounts for most of the known facts.     

Reactivities of sulfhydryl groups in native and metal-free aminoacylase I

Aminoacylase I from porcine kidney (EC 3.5.1.14) contains seven cysteine residues per subunit. Three sulfhydryl groups are accessible to modification by 4-hydroxymercuribenzoate (p-MB). The kinetics of the reaction suggest that only one of these groups affects acylase activity when modified by p-MB. Its reaction rate increases 2-3-fold when the essential metal ion of aminoacylase is removed. Modification of metal-free apoenzyme by N-ethylmaleimide (NEM) abolishes its activity without impairing Zn2+ binding. This indicates that the sulfhydryl group reacting with NEM is not directly coordinated to the metal. DTNB (5,5'-Dithio-bis(2-nitrobenzoate), Ellman's reagent) also modifies three sulfhydryl groups per subunit. In this case, the reactivities of native aminoacylase and apoenzyme are not significantly different. N-Hydroxy-2-aminobutyrate, a strong aminoacylase inhibitor, substantially increases the reactivity of the slowest reacting sulfhydryl in both native enzyme and metal-free aminoacylase. It appears that binding of the inhibitor or removal of the metal ion induces conformational changes of the amino-acylase active site that render a buried sulfhydryl group more accessible to modification.     

Studies on continuous enzyme reactions. IV. Preparation of a DEAE-sephadex–aminoacylase column and continuous optical resolution of acyl-DL-amino acids

Conditions for the preparation of an aminoacylase column using DEAE-Sephadex as a carrier were investigated. The aminoacylase column having the highest activity was obtained when 7500 μmoles/hr. of partially purified aminoacylase was charged into a column packed with 9 ml. of DEAE-Sephadex A-25 (bead type, hydroxy form). By employing a DEAE-Sephadex–aminoacylase column, conditions for continuous optical resolution of acyl-DL -amino acids were investigated. When a solution of 0.2M acetyl-DL -methionine (pH 7.0, containing 5 × 10^?4M Co²⁺) or 0.2M acetyl-DL -phenylalanine (pH 6.0, containing 5 × 10^?4M Co²⁺) was passed through the aminoacylase column at the flow rate of SV = 2.5 or 2.0, respectively, at 50°C., the highest rate of hydrolysis of both substrates was attained. From the column effluents, enzymatically hydrolyzed L -methionine and L -phenylalanine were isolated in a good yield.     

Enzymatic preparation of optically active 3-trimethylsilylalanine

 We constructed an efficient system for preparing optically active 3-trimethylsilylalanine (TMS-Ala) by kinetic resolution with acylase I (aminoacylase; N-acylamino-acid amidohydrolase, EC 3.5.1.14). Racemic TMS-Ala was chemically synthesized and acetylated. Enantioselective deacetylation of N-acetyl-DL-TMS-Ala with acylase I from porcine kidney or from Aspergillus melleus was then attempted. Both enzymes could catalyze the deacetylation of N-acetyl-DL-TMS-Ala, and the porcine enzyme was found to have much higher activity than the enzyme from A. melleus. The optimum pH of the porcine-acylase-catalyzed reaction was 7.5, and the addition of 0.5 mM Co²⁺ accelerated the reaction. Optically pure L-TMS-Ala (>99% enantiomeric excess, ee) was obtained in 72% yield under the optimized conditions. Furthermore, highly optically pure D-TMS-Ala (96% ee) could also be obtained in 76% yield by chemically hydrolyzing the residual substrate. Received: 6 June 1995/Received revision: 3 July 1995/Accepted: 19 July 1995     

N-Acyl-L-aromatic amino acid deacylase in animal tissues

An enzyme deacylating preferentially N-acyl-L-aromatic amino acids was partially purified from rat kidney. The purification procedure included DEAE-cellulose column chromatography, (NH4)2SO4 fractionation, gel-filtration on a Sephadex G-200 column and further DEAE-cellulose chromatography. The enzyme was thus separated from aminoacylase (N-acylamino-acid amidohydrolase, EC 3.5.1.14) (acylase I). Although the enzyme preparation contained other acylases, the experimental data (effect of p-chloromercuric benzoate, heat stability and inhibition between substrates) suggest that the enzyme acts preferentially on N-acyl derivatives of L-tryptophan, L-tyrosine, L-phenylalanine and L-histidine. This enzyme appears to be present in many animal tissues.     

Enzymatic properties of immobilized beta-galactosidase from Curvularia inaequalis]

beta-Galactosidase (EC 3.2.1.23) from fungus Curvularia inaequalis was modified by active brilliant orange KH and adsorbed on DEAE-Sephadex A-50. The lactose hydrolysis was studied in a continous flow on the column packed with the immobilized enzyme. The pH and temperatures optima for the substrate hydrolysis by the immobilized enzyme were shown to remain unchanged. A certain destabilizing effect of the matrix on the enzyme resistance to hear denaturation was observed. The activation parameters of denaturation of the native enzyme as well as those of the dye-modified and immobilized preparations were determined.     

Total Hydrolysis of Xylotetraose and Xylobiose by Soluble and Cross-linked Crystalline Xylanase II from Trichoderma reesei

The ability of Trichoderma reesei xylanase II (EC 3.2.1.8) to hydrolyse the small xylo-oligomer substrates, xylotetraose and xylobiose, was studied. Xylanase was used in both soluble and cross-linked enzyme crystal (CLEC) form. Hydrolysis reactions with crystalline xylanase cross-linked with glutaraldehyde and lysine were performed in a column reactor. By using appropriate combination of column packing length and flow rate, xylotetraose and xylobiose (initial concentrations 10 mg ml &#109 1 ) were hydrolysed completely to xylose in less than 1 h. The observed reaction rate in the column depended substantially on the flow rate of the eluent, probably due to an enhanced mass-transfer with higher flow rates. With soluble xylanase, using extended reaction times of 24 h and extremely high enzyme/substrate ratios of 20 (w/w) or above, the hydrolysis reaction reached completion with both xylotetraose and xylobiose as substrates. Even with the lowest flow rate, the reaction in the column appeared to be faster than soluble enzyme hydrolysis with comparable enzyme/substrate ratios.     

Immobilization of aminoacylase by adsorption to tannin immobilized on aminohexyl cellulose.

The immobilization of aminoacylase (N-acylamino acid amidohydrolase, EC 3.5.1.14) was investigated by using tannin immobilized on aminohexyl cellulose. The most active immobilized aminoacylase was obtained when aminoacylase was adsorbed to the immobilized tannin in a weak alkaline medium containing sodium chloride and n-butanol at 37 degrees C. The activity of the immobilized tannin-aminoacylase complex per unit volume was five times higher than that of the DEAE-Sephadex-aminoacylase complex used for industrial production of L-amino acids in our plants. The half-life of the immobilized tannin-aminoacylase complex was 20 days under continuous operation at a high concentration of substrate; on the contrary, that of the DEAE-Sephadex-aminoacylase complex was 0.5 days.     

Nuclear magnetic relaxation studies of the role of the metal ion in Mn2(+)-substituted aminoacylase I

Substitution of the essential Zn2+ ions of porcine kidney aminoacylase I (EC 3.5.1.14) by Mn2+ did not markedly affect the kinetic properties of the enzyme. Using Mn2+ as a paramagnetic probe, we were able to study the conformations of bound ligands by measuring the enhancement of ligand proton relaxation in 1H NMR. In addition, the effects of inhibitors on the paramagnetic enhancement of water proton relaxation rates were examined. The results of both approaches, in agreement with kinetic evidence, suggest that the metal center of aminoacylase I is too distant from the ligand binding site to allow direct participation of the metal in substrate binding or catalysis. We, therefore, propose that the metal ion of aminoacylase I plays a purely structural role.     

Constituents of Plant Leaf Wax Contained in Rice Callus Tissues

Two enzyme preparations having both nuclease and 3′-nucleotidase activities were partially purified from an extract of tea leaves. They resemble each other in most enzymatic properties, but are separated by DEAE-cellulose column chromatography.

The enzyme activities for RNA, native DNA, heat-denatured DNA and 3′-AMP of each preparation showed a high degree of similarity with respect to the following properties: pH stability, thermal stability and response to EDTA. Both enzymes were shown to be endonucleases (EC 3.1.30.2) which liberated 5′-mononucleotides and oligonucleotides from both RNA and DNA with the following relative rate of hydrolysis: RNA > native DNA = heat-denatured DNA.     

Total Hydrolysis of Xylotetraose and Xylobiose by Soluble and Cross-linked Crystalline Xylanase II from Trichoderma reesei

The ability of Trichoderma reesei xylanase II (EC 3.2.1.8) to hydrolyse the small xylo-oligomer substrates, xylotetraose and xylobiose, was studied. Xylanase was used in both soluble and cross-linked enzyme crystal (CLEC) form. Hydrolysis reactions with crystalline xylanase cross-linked with glutaraldehyde and lysine were performed in a column reactor. By using appropriate combination of column packing length and flow rate, xylotetraose and xylobiose (initial concentrations 10 mg ml -1 ) were hydrolysed completely to xylose in less than 1 h. The observed reaction rate in the column depended substantially on the flow rate of the eluent, probably due to an enhanced mass-transfer with higher flow rates. With soluble xylanase, using extended reaction times of 24 h and extremely high enzyme/substrate ratios of 20 (w/w) or above, the hydrolysis reaction reached completion with both xylotetraose and xylobiose as substrates. Even with the lowest flow rate, the reaction in the column appeared to be faster than soluble enzyme hydrolysis with comparable enzyme/substrate ratios.     

Isolation of 5-benzyl hydroxytryptophan enantiomers by using microbial aminoacylase

The process of asymmetric deacylation of an acetyl derivative of 5-benzyl hydroxytryptophan racemate in the presence of native microbial aminoacylase was studied. The effect of pH, temperature, concentration of the enzyme and substrate were investigated. Conditions for preparation and isolation of individual amino acids were defined by optimization of N-Ac-DU-5-BOT hydrolysis.     

Kinetcs and decay of fumarase activity of immobilized Brevibacterium ammoniagenes cells for continuous production of L-malic acid

The kinetics of the reversible fumarase reaction of immobilized Brevibacterium ammoniagenes cells and the decay behavior of enzyme activity were investigated in a plug flow system. The time course of the reaction in the immobilized cell column was well explained by the time-conversion equation including the apparent kinetic constants of the immobilized cell enzyme. The decay rate of fumarase activity was faster in the upper sections of the column (inlet side of the substrate solution) compared with the lower sections when 1M sodium fumarate (pH 7.0) was continuously passed through the column at 37°C. It was shown that the decay rate of the fumarase activity in the immobilized cell column depends on the flow rate of the substrate solution. The effect of flow rate on the decay rate of enzyme activity was considered to be related to the rate of contamination of enzyme with poisonous substances derived from the substrate solution or to the rate of leakage of enzyme stabilizers and/or enzyme itself from the immobilized cells.     

Thermostable dipeptidase from Bacillus stearothermophilus: its purification, characterization, and comparison with aminoacylase

Dipeptidase (dipeptide hydrolase [EC 3.4.13.11]) has been purified to homogeneity and crystallized from the cell extract of Bacillus stearothermophilus IFO 12983. The enzyme has a molecular weight of about 86,000, and is composed of two subunits identical in molecular weight (43,000). The enzyme contains 2 g atoms of zinc per mol of protein. A variety of dipeptides consisting of glycine or only L-amino acids serve as substrates of the enzyme; Km and Vmax values for L-valyl-L-alanine are 0.5 mM and 68.0 units/mg protein, respectively. The enzyme is significantly stable not only at high temperatures but also on treatment with protein denaturants such as urea and guanidine hydrochloride. The enzyme also catalyzes hydrolysis of several N-acylamino acids with Vmax values 3-30% of those for the hydrolysis of dipeptides. The thermostable dipeptidase shares various properties with bacterial aminoacylase [EC 3.5.1.14]: their subunit molecular weight, metal content and requirement, amino acid composition, and amino acid sequence in the N-terminal region are very similar.     

On the physical properties and mechanism of action of arylsulfate sulfohydrolase II from Aspergillus oryzae.

Sedimentation equilibrium studies on arylsulfate sulfohydrolase II (EC 3.1.6.1) from Aspergillus oryzae under nondissociating conditions have resulted in a revised molecular weight of 94,900 ± 7100. Sedimentation equilibrium and gel electrophoresis data collected in the presence of the dissociating agents, urea and sodium dodecylsulfate demonstrate that the native enzyme is composed of two identical subunits as suggested by previous studies employing an irreversible inhibitor.The pH dependencies of the kinetic parameters V and $\text{V}\text{K}{}_{\mathrm{m}}$ for the enzymic hydrolysis of 4-nitrophenyl sulfate indicate that two groups of pK_a 4.7 and 6.0 control the activity of the enzyme. The product inorganic sulfate was shown to be a linear competitive inhibitor of the enzyme at pH 4.0, implying that it is a last released product along the reaction pathway. Inhibition by the phenol product was not observed. Enzymic hydrolysis of 4-nitrophenyl sulfate in ¹⁸O enriched water revealed that one atom of solvent oxygen is incorporated per molecule of inorganic sulfate, which is consistent with a mechanism featuring sulfur-oxygen bond cleavage. Evidence is presented based on stopped-flow kinetics, partitioning experiments in the presence of amine nucleophiles, and ¹⁸O exchange studies that collectively suggest that the breakdown of a covalent sulfuryl enzyme intermediate probably is not the rate-limiting step along the reaction pathway.The substrate specificity of the enzyme was examined by testing a variety of sulfate and phosphate esters as inhibitors of the hydrolysis of 4-nitrophenyl sulfate. The Cbz-l-Phe-l-Tyrosine-O-sulfate methyl ester serves as a substrate for the enzyme. Apparently substrate activity requires an aromatic sulfate ester whose binding is enhanced by incorporating the aromatic moiety in a hydrophobic matrix.     

Isolation and characterization of N-long chain acyl aminoacylase from Pseudomonas diminuta

N-Long chain acyl aminoacylase II (Enzyme II) catalyzing the hydrolysis of N-long chain acyl amino acids was purified about 2,000-fold from the cell extracts of Pseudomonas diminuta with 1.8% of activity yield. The purified enzyme was homogeneous on polyacrylamide gel electrophoresis and the molecular weight was 220,000. Enzyme II differed from N-long chain acyl aminoacylase I (Enzyme I) in molecular weight, in substrate specificity, and in behavior toward temperature and pH. Enzyme II showed broader substrate specificity than Enzyme I and catalyzed the hydrolysis of lipoamino acids containing various amino acid residues, although Enzyme I was almost specific to the lipoamino acids containing L-glutamate. The extent of hydrolysis by Enzyme II reaction varied depending on the kinds of lipoamino acids and were: 100% for palmitoyl-L-glutamate, 91% for myristoyl-L-glutamate, 85% for lauroyl-L-glutamate, 54% for lauroyl-L-aspartate, 28% for stearoyl-L-glutamate and 17.5% for lauroyl-glycine.     

Butylmalonate is a transition state analogue for aminocylase I

Butylmalonate (butyl propanedioic acid) is a slow-binding inhibitor of porcine renal aminoacylase I (EC 3.5.1.14), causing transients of activity with half-times of more than 10 min. At 25°C and pH 7.0, the dissociation rate of the complex is approximately 6 × 10⁻⁴ s⁻¹, while the rate constant of complex formation is in the order of 20 M⁻¹·s⁻¹. In good agreement with these data, steady-state kinetics yield an estimated inhibition constant around 100 μM. Molecular mechanics calculations showed that conformation and charge distribution of butylmalonate are strikingly similar to those of the putative transition state of aminoacylase catalysis.     

Kinetics of the enzymatic hydrolysis of cellulose: 2. A mathematical model for the process in a plug-flow column reactor

The kinetics of enzymatic cellulose hydrolysis in a plug-flow column reactor catalysed by cellulases [see 1,4-(1,3;1,4)-β-d-glucan 4-glucanohydrolase, EC 3.2.1.4] from Trichoderma longibrachiatum adsorbed on cellulose surface have been studied. The maximum substrate conversion achieved was 90–94%. The possibility of enzyme recovery for a reactor of this type is discussed. A mathematical model for enzymatic cellulose hydrolysis in a plug-flow column reactor has been developed. The model allows for the component composition of the cellulase complex, adsorption of cellulases on the substrate surface, inhibition by reaction products, changes in cellulose reactivity and the inactivation of enzymes in the course of hydrolysis. The model affords a reliable prediction of the kinetics of d-glucose and cellobiose formation from cellulose in a column reactor as well as the degree of substrate conversion and reactor productivity with various amounts of adsorbed enzymes and at various flow rates.