Presence of two DNA polymerases in Tetrahymena pyriformis.

Two DNA polymerases were detected in Tetrahymena pyriformis, strain GL. One (enzyme I) was sensitive to N-ethylmaleimide, while the other (enzyme II) was insensitive. The molecular weight of the enzymes, as determined by glycerol gradient centrifugation analysis, were approximately 130,000 and 70,000, respectively. Optimal concentration of MgCl2 was 10mM for enzyme I and 18mM for enzyme II. KCl inhibited enzyme I but stimulated enzyme II. Poly (dA-dT) served effectively as a template for enzyme I, while poly(dA).(dT)12-18 was an effective template for enzyme II. Enzyme I activity increased with cell growth and sharply declined after the cells reached the stationary phase. On the other hand, enzyme II activity appeared only at the end of log phase. In cells synchronized by starvation-refeeding technique enzyme I was markedly stimulated in correspondence to the rate of DNA synthesis, whereas the level of enzyme II activity changed to lesser extent. By ethidium bromide treatment, only enzyme I activity was induced.     

pH dependence of kinetic parameters for oxalacetate decarboxylation and pyruvate reduction reactions catalyzed by malic enzyme

Both chicken liver NADP-malic enzyme and Ascaris suum NAD-malic enzyme catalyze the metal-dependent decarboxylation of oxalacetate. Both enzymes catalyze the reaction either in the presence or in the absence of dinucleotide. The presence of dinucleotide increases the affinity of oxalacetate for the chicken liver NADP-malic enzyme, but this information could not be obtained in the case of A. suum NAD-malic enzyme because of the low affinity of free enzyme for NAD. The kinetic mechanism for oxalacetate decarboxylation by the chicken liver NADP-malic enzyme is equilibrium ordered at pH values below 5.0 with NADP adding to enzyme first. The Ki for NADP increases by a factor of 10 per pH unit below pH 5.0. An enzyme residue is required protonated for oxalacetate decarboxylation (by both enzymes) and pyruvate reduction (by the NAD-malic enzyme), but the beta-carboxyl of oxalacetate must be unprotonated for reaction (by both enzymes). The pK of the enzyme residue of the chicken liver NADP-malic enzyme decreases from a value of 6.4 in the absence of NADP to about 5.5 with Mg2+ and 4.8 with Mn2+ in the presence of NADP. The pK value of the enzyme residue required protonated for either oxalacetate decarboxylation or pyruvate reduction for the A. suum NAD-malic enzyme is about 5.5-6.0. Although oxalacetate binds equally well to protonated and unprotonated forms of the NADP-enzyme, the NAD-enzyme requires that oxalacetate or pyruvate selectively bind to the protonated form of the enzyme. Both enzymes prefer Mn2+ over Mg2+ for oxalacetate decarboxylation.(ABSTRACT TRUNCATED AT 250 WORDS)     

Lysine 199 is the general acid in the NAD-malic enzyme reaction

Site-directed mutagenesis was used to change K199 in the Ascaris suum NAD-malic enzyme to A and R and Y126 to F. The K199A mutant enzyme gives a 10(5)-fold decrease in V and a 10(6)-fold decrease in V/K(malate) compared to the WT enzyme. In addition, the ratio for partitioning of the oxalacetate intermediate toward pyruvate and malate changes from a value of 0.4 for the WT enzyme to 1.6 for K199A, and repeating the experiment with A-side NADD gives isotope effects of 3 and 1 for the WT and K199A mutant enzymes, respectively. The K199R mutant enzyme gives only a factor of 10 decrease in V, and the pK for the general acid in this mutant enzyme has increased from 9 for the WT enzyme to >10 for the K199R mutant enzyme. Tritium exchange from solvent into pyruvate is catalyzed by the WT enzyme, but not by the K199A mutant enzyme. The Y126F mutant enzyme gives a 10(3)-fold decrease in V. The oxalacetate partition ratio and isotope effect on oxalacetate reduction for the Y126F mutant enzyme are identical, within error, to those measured for the WT enzyme. Thus, Y126 is important to the overall reaction, but its role at present is unclear. Data are consistent with K199 functioning as the general acid that protonates C3 of enolpyruvate to generate the pyruvate product in the malic enzyme reaction.     

Purification and biochemical characterization of recombinant rat liver phenylalanine hydroxylase produced in Escherichia coli.

Phenylalanine hydroxylase, important in phenylalanine metabolism in mammals, is regulated through short-term (activation) and long-term (induction) mechanisms. To help elucidate the structure-function relationships involved in the activation of this enzyme, we have isolated and characterized full-length cDNA clones to rat phenylalanine hydroxylase. Recombinant rat phenylalanine hydroxylase was placed into an expression vector in Escherichia coli. The enzyme has been purified to homogeneity and its physical and catalytic properties have been characterized. The molecular weight and the fluorescence emission spectrum of the recombinant enzyme were identical to those of the native enzyme. The recombinant enzyme could be activated by incubation with phenylalanine or lysolecithin or by phosphorylation, as is the rat liver enzyme. The extent of activation is the same as that for the native enzyme in each case except for phenylalanine, which activates the recombinant enzyme only 5- to 10-fold rather than the 15- to 30-fold activation observed with the native enzyme. The kinetic constants determined for the recombinant enzyme are also essentially the same as those reported for the native enzyme. We conclude that this enzyme is essentially identical to the native enzyme and should be very useful in the future study of this important hydroxylase.     

The role of an essential histidine residue of yeast alcohol dehydrogenase.

1. Inactivation of yeast alcohol dehydrogenase for diethyl pyrocarbonate indicates that one histidine residue per enzyme subunit is necessary for enzymic activity. The inactivated enzyme regains its activity over a period of days. 2. Enzyme modified by diethyl pyrocarbonate can form the binary enzyme - NADH complex with the same maximum NADH-binding capacity as that of native enzyme. Modified enzyme cannot form normal ternary complexes of the type enzyme - NADH - acetamide and enzyme - NAD+ - pyrazole, which are characteristic of native enzyme. 3. The rate constant for the reaction of enzyme with diethyl pyrocarbonate has been determined over the pH range 5.5--9. The histidine residue involved has approximately the same pKa as free histidine, but is 10-fold more reactive than free histidine.     

Findings of trigonelline demethylating enzyme activity in various organisms and some properties of the enzyme from hog liver

Trigonelline demethylating enzyme activity was found widely in animals, plants and microorganisms. Very high enzyme activity of this enzyme was detected in hog liver. Properties of the hog liver enzyme were investigated. Optimum pH for the enzymic reaction was observed at 8.5. The Km value for trigonelline was calculated at 2.77 mM. Addition of any cofactor is not required for the reaction The enzyme activity was inhibited by heavy metal ions. The reaction product was identified as nicotinic acid. Proposed enzyme reaction mechanism and the role of this enzyme in biosynthesis and metabolism of NAD are discussed.     

Purification and properties of the activating enzyme for iron protein of nitrogenase from the photosynthetic bacterium Rhodospirillum rubrum

The oxygen-labile, activating enzyme for iron protein from the photosynthetic bacterium, Rhodospirillum rubrum, was purified 11,800-fold using a combination of chromatophore washing, DE52-cellulose chromatography, hydroxylapatite chromatography, reactive red-120 cross-linked agarose chromatography, reactive red-120 cross-linked agarose chromatography, and Sephadex G-75 gel filtration. Activating enzyme appeared homogeneous on silver-stained sodium dodecyl sulfate-polyacrylamide gels, and the staining intensity of the activating-enzyme band was correlated with the activating-enzyme activity observed in in vitro assays. Either formaldehyde fixation or higher acrylamide concentration was required to accurately assess the purity of activating enzyme on silver-stained gels. Activating enzyme was stable for 30 days at 4 degrees C. Dithiothreitol was a necessary component for the stability of partially purified activating enzyme. NaCl inhibited the coupled assay for activating enzyme. The pI of activating enzyme was determined to be 6.5. Activating enzyme is composed of a minimum of 336 amino acids and a minimum calculated Mr is 32,032. The Mr of activating enzyme was estimated to be 21,700 by analytical gel filtration and 32,800 by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. An absorption maximum at 280 nm was observed for the activating enzyme.     

Invertase covalently coupled to porous glass: preparation and characterization

The enzyme invertase has been covalently coupled to porous glass particles. The product is extremely stable over a long period of time. Kinetic values for the immobilized enzyme are similar to the native enzyme. Excellent enzymatic activity for the immobilized enzyme was exhibited over a broad pH range. The immobilized enzyme when continuously operated for one month was found to have an operational half-life of over 40 days.     

Comparative kinetic studies on the L-type pyruvate kinase from rat liver and the enzyme phosphorylated by cyclic 3', 5'-AMP-stimulated protein kinase.

The kinetics of rat liver L-type pyruvate kinase (EC 2.7.1.40), phosphorylated with cyclic AMP-stimulated protein kinase from the same source, and the unphosphorylated enzyme have been compared. The effects of pH and various concentrations of substrates, Mg2+, K+ and modifiers were studied. In the absence of fructose 1, 6-diphosphate at pH 7.3, the phosphorylated pyruvate kinase appeared to have a lower affinity for phosphoenolpyruvate (K0.5=0.8 mM) than the unphosphorylated enzyme (K0.5=0.3 mM). The enzyme activity vs. phosphoenolpyruvate concentration curve was more sigmoidal for the phosphorylated enzyme with a Hill coefficient of 2.6 compared to 1.6 for the unphosphorylated enzyme. Fructose 1, 6-diphosphate increased the apparent affinity of both enzyme forms for phosphoenolpyruvate. At saturating concentrations of this activator, the kinetics of both enzyme forms were transformed to approximately the same hyperbolic curve, with a Hill coefficient of 1.0 and K0.5 of about 0.04 mM for phosphoenolpyruvate. The apparent affinity of the enzyme for fructose 1, 6-diphosphate was high at 0.2 mM phosphoenolpyruvate with a K0.5=0.06 muM for the unphosphorylated pyruvate kinase and 0.13 muM for the phosphorylated enzyme. However, in the presence of 0.5 mM alanine plus 1.5 mM ATP, a higher fructose 1, 6-diphosphate concentration was needed for activation, with K0.5 of 0.4 muM for the unphosphorylated enzyme and of 1.4 muM for the phosphorylated enzyme. The results obtained strongly indicate that phosphorylation of pyruvate kinase may also inhibit the enzyme in vivo. Such an inhibition should be important during gluconeogenesis.     

Enzyme activity maintenance in packed-bed reactors via continuous enzyme addition

An operational scheme for using immobilized enzymes in packed-bed reactors that permits operation at a constant throughput rate and constant product quality is described. The scheme used columns operated in series with continuous enzyme addition to compensate for enzyme decay. A mathematical technique was developed to determine the enzyme addition rate, enzyme usage, and enzyme volume in the column system. Operation of columns in series is compared to operation where the flow rate is decreased to compensate for a loss of enzyme activity for both zero-and first-order decay. The analyses indicated that columns in series resulted in better enzyme utilization but larger reactor volumes than parallel reactors with decreasing flow rate.     

Effect of N-bromosuccinimide modification on dihydrofolate reductase from a methotrexate-resistant strain of Escherichia coli. Activity, spectrophotometric, fluorescence and circular dichroism studies.

When dihydrofolate reductase from a methotrexate-resistant strain of Escherichia coli B, MB 1428, is treated with approximately a 5 mol ratio of N-bromosuccinimide (NBS) to enzyme at pH 7.2 and assayed at the same pH, there is a 40% loss of activity due to the modification of 1 histidine residue and possibly 1 methionine residue before oxidation of tryptophan occurs. The initial modification is accompanied by a shift of the pH for maximal enzymatic activity from pH 7.2 to pH 5.5 Upon further treatment with N-bromosuccinimide, the activity is gradually reduced from 60 to 0% as tryptophan residues become oxidized. An NBS to enzyme mole ratio of approximately 20 results in 90% inactivation of the enzyme. When the enzyme is titrated with NBS in 6 M guanidine HCl, 5 mol of tryptophan react per mol of enzyme, a result in agreement with the total tryptophan content as determined by magnetic circular dichroism. The 40% NBS-inactivated sample posses full binding capacity for methotrexate and reduced triphosphopyridine nucleotide, and the Km values for dihydrofolate and TPNH are the same as for the native enzyme. After 90% inactivation, only half of the enzyme molecules bind methotrexate, and the dissociation constant for methotrexate is 40 nM as compared to 4 nM for native enzyme in solutions of 0.1 M ionic strength, pH 7.2 Also, TPNH is not bound as tightly to the modified enzyme-methotrexate complex as to the unmodified enzyme-methotrexate complex. Circular dichroism studies indicate the 90% NBS-inactivated enzyme has the same alpha helix content as the native enzyme but less beta structure, while the 40% inactivated enzyme is essentially the same as the native enzyme. Protection experiments were complicated by the fact that NBS reacts with the substrates and cofactors of the enzyme. Although protection of specific residues was not determined, it was clear that TPNH was partially protected from NBS reaction when bound to the enzyme, and the enzyme, and the enzyme was not inactivated by NBS until the TPNH had reacted.     

Genetic regulation of malic enzyme activity in the mouse

Cytosolic malic enzyme catalyzes the NADP(+)-dependent oxidative decarboxylation of malate to pyruvate and CO2. Additionally, this enzyme produces large amounts of reducing equivalents (NADPH) required for de novo fatty acid synthesis and provides a precursor for oxaloacetate replacement in the mitochondria. Malic enzyme is considered a key lipogenic enzyme and changes in enzyme activity parallel changes in the lipogenic rate. As would be expected, the activity of malic enzyme responds to a variety of dietary and hormonal factors acting mainly on the rate of enzyme synthesis. In the mouse, the structural locus for malic enzyme (Mod-1) is located on chromosome 9. Two alleles reflecting differences in electrophoretic mobility have been identified. This report demonstrates that the amount of hepatic malic enzyme activity is strain-dependent and is regulated by a malic enzyme regulator locus (Mod1r) located on the proximal end of chromosome 12. Two alleles have been identified: Mod1ra, conferring high enzyme activity (C57BL/6J), and Mod1rb, conferring low enzyme activity (C57BL/KsJ). Biochemical studies have demonstrated differences in the apparent Km and Vmax and in specific activity on purification and immunoprecipitation, features that suggest changes in enzyme structure even though no differences were observed by electrophoresis and isoelectric focusing. These combined data suggest that differences in both enzyme quantity and structure may be involved in the genetic regulation of malic enzyme activity in mice.     

Escherichia coli E-39 ADPglucose synthetase has different activation kinetics from the wild-type allosteric enzyme

Kinetic and binding studies have shown that Lys39 of Escherichia coli ADPglucose synthetase is involved in binding of the allosteric activator. In order to study structure-function relationships at the activator binding site, this lysine residue was substituted by glutamic acid (Lys39----Glu) by site-directed mutagenesis. The resultant mutant enzyme (E-39) showed activation kinetics different from those of the wild-type enzyme. The level of activation of the E-39 enzyme by the major activators of E. coli ADPglucose synthetase, 2-phosphoglycerate, pyridoxal phosphate, and fructose-1,6-phosphatase was only approximately 2-fold compared to activation of 15- to 28-fold respectively, for the wild-type enzyme. NADPH, an activator of the wild-type enzyme, was unable to activate the mutant enzyme. In addition, the concentrations of the above activators necessary to obtain 50% of the maximal stimulation of enzyme activity (A0.5) were 5-, 9-, and 23-fold higher, respectively, than those for the wild-type enzyme. The E-39 enzyme also had a lower apparent affinity (S0.5) for the substrates ATP and MgCl2 than the wild-type enzyme and the values obtained in the presence or absence of activator were similar. The concentration of inhibitor giving 50% of enzyme activity (I0.5) was also similar for the E-39 enzyme in the presence or absence of activator. These results indicate that the E-39 mutant enzyme is not effectively activated by the major activators of the E. coli ADPglucose synthetase wild-type enzyme, and that this amino acid substitution also prevents the allosteric effect that the activator has on the wild-type enzyme kinetics, either increasing its apparent affinity for the substrates or modulating the enzyme's sensitivity to inhibition.     

Differences in redox and kinetic properties between NAD-dependent and O2-dependent types of rat liver xanthine dehydrogenase

Reductive titrations of a NAD-dependent type (type-D) and an O2-dependent type (type-O) of rat liver xanthine dehydrogenase showed that only the type-D enzyme formed a pronounced stable FAD semiquinone (FADH*). The FAD semiquinone was less stabilized in the presence of NAD. The Vmax value for xanthine-NAD activity of type-D enzyme was close to that for xanthine-O2 activity of type-O enzyme, while the Vmax value for xanthine-O2 activity of type-D enzyme was about one-fourth of that of type-O enzyme. The Km value for O2 of type-D enzyme was about five times as large as that of type-O enzyme. The absorbance spectrum of type-D enzyme during turnover with xanthine and O2 as substrates showed a considerable amount of FADH* formation, but that with xanthine and NAD as substrates showed only a negligible one. Low xanthine-O2 activity of type-D enzyme, as compared with that of type-O enzyme, seems to be explained by the conformational change occurring in conversion from type-O to type-D enzyme, which results in different reactivity of FAD to molecular oxygen and a higher fraction of FADH* during turnover. The binding of NAD may possibly increase the fraction of FADH2, resulting in a Vmax value of xanthine-NAD activity almost as high as that of xanthine-O2 activity of type-O enzyme.     

Lysine-60 in the regulatory chain of Escherichia coli aspartate transcarbamoylase is important for the discrimination between CTP and ATP

Lysine-60 in the regulatory chain of aspartate transcarbamoylase has been changed to an alanine by site-specific mutagenesis. The resulting enzyme exhibits activity and homotropic cooperativity identical with those of the wild-type enzyme. The substrate concentration at half the maximal observed specific activity decreases from 13.3 mM for the wild-type enzyme to 9.6 mM for the mutant enzyme. ATP activates the mutant enzyme to the same extent that it does the wild-type enzyme, but the concentration of ATP required to reach half of the maximal activation is reduced approximately 5-fold for the mutant enzyme. CTP at a concentration of 10 mM does not inhibit the mutant enzyme, while under the same conditions CTP at concentrations less than 1 mM will inhibit the wild-type enzyme to the maximal extent. Higher concentrations of CTP result in some inhibition of the mutant enzyme that may be due either to hetertropic effects at the regulatory site or to competitive binding at the active site. UTP alone or in the presence of CTP has no effect on the mutant enzyme. Kinetic competition experiments indicate that CTP is still able to displace ATP from the regulatory sites of the mutant enzyme. Binding measurements by equilibrium dialysis were used to estimate a lower limit on the dissociation constant for CTP binding to the mutant enzyme (greater than 1 x 10(-3) M). Equilibrium competition binding experiments between ATP and CTP verified that CTP still can bind to the regulatory site of the enzyme. For the mutant enzyme, CTP affinity is reduced approximately 100-fold, while ATP affinity is increased by 5-fold.(ABSTRACT TRUNCATED AT 250 WORDS)     

The subcellular distribution and properties of aldehyde dehydrogenases in rat liver

1. Kinetic experiments suggested the possible existence of at least two different NAD(+)-dependent aldehyde dehydrogenases in rat liver. Distribution studies showed that one enzyme, designated enzyme I, was exclusively localized in the mitochondria and that another enzyme, designated enzyme II, was localized in both the mitochondria and the microsomal fraction. 2. A NADP(+)-dependent enzyme was also found in the mitochondria and the microsomal fraction and it is suggested that this enzyme is identical with enzyme II. 3. The K(m) for acetaldehyde was apparently less than 10mum for enzyme I and 0.9-1.7mm for enzyme II. The K(m) for NAD(+) was similar for both enzymes (20-30mum). The K(m) for NADP(+) was 2-3mm and for acetaldehyde 0.5-0.7mm for the NADP(+)-dependent activity. 4. The NAD(+)-dependent enzymes show pH optima between 9 and 10. The highest activity was found in pyrophosphate buffer for both enzymes. In phosphate buffer there was a striking difference in activity between the two enzymes. Compared with the activity in pyrophosphate buffer, the activity of enzyme II was uninfluenced, whereas the activity of enzyme I was very low. 5. The results are compared with those of earlier investigations on the distribution of aldehyde dehydrogenase and with the results from purified enzymes from different sources.     

Aminoacetone oxidase from goat liver. Formation of methylglyoxal from aminoacetone

An enzyme which oxidizes aminoacetone to methylglyoxal has been purified from the particulate fraction of goat liver. Polyamines, such as spermidine and spermine, are also good substrates for this enzyme. The pH optimum for aminoacetone oxidation was found to be 8.2. The apparent Km values of the enzyme for aminoacetone and spermidine were 0.009 and 0.095 mM, respectively. The subunit molecular weight of the enzyme was 93,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The apparent molecular weight of the native enzyme was 186,000 by gel filtration. The enzyme is highly sensitive to carbonyl group reagents. The enzyme is not inhibited by monoamine and diamine oxidase inhibitors.     

A small hydrophobic domain that localizes human erythrocyte acetylcholinesterase in liposomal membranes is cleaved by papain digestion

A small hydrophobic domain in isolated human erythrocyte acetylcholinesterase is responsible for the interaction of this enzyme with detergent micelles and the aggregation of the enzyme on removal of detergent. Papain has been shown to cleave this hydrophobic domain and to generate a fully active hydrophilic enzyme that shows no tendency to interact with detergents or to aggregate [Dutta-Choudhury, T.A., & Rosenberry, T.L. (1984) J. Biol. Chem. 259, 5653-5660]. We report here that the intact enzyme could be reconstituted into phospholipid liposomes while the papain-disaggregated enzyme showed no capacity for reconstitution. More than 80% of the enzyme reconstituted into small liposomes could be released by papain digestion as the hydrophilic form. Papain was less effective in releasing the enzyme from large liposomes that were probably multilamellar. In a novel application of affinity chromatography on acridinium resin, enzyme reconstituted into small liposomes in the presence of excess phospholipid was purified to a level of 1 enzyme molecule per 4000 phospholipid molecules, a ratio expected if each enzyme molecule was associated with a small, unilamellar liposome. Subunits in the hydrophilic enzyme form released from reconstituted liposomes by papain digestion showed a mass decrease of about 2 kilodaltons relative to the intact subunits according to acrylamide gel electrophoresis in sodium dodecyl sulfate, a difference similar to that observed previously following papain digestion of the soluble enzyme aggregates. The data were consistent with the hypothesis that the same hydrophobic domain in the enzyme is responsible for the interaction of the enzyme with detergent micelles, the aggregation of the enzyme in the absence of detergent, and the incorporation of the enzyme into reconstituted phospholipid membranes.     

Limited proteolysis of maize NADP-malic enzyme

The incubation of maize malic enzyme at 37 degrees C with trypsin at a ratio of 150:1 of malic enzyme to trypsin caused rapid and complete inactivation of enzyme activity. The inactivation was caused by fairly specific cleavage of the enzyme monomer (62 kDa) into 40 kDa and 20 kDa fragments. The intensity of 40 kDa band increased with the time of treatment of enzyme with trypsin from 2 to 30 min. Substrates, especially NADP (25 microM) provided almost total protection against trypsin inactivation of the enzyme activity. The studies carried out with various other endoproteases indicated that endoprotease Lys-C was most effective in inactivating malic enzyme activity. The kinetic properties of the truncated enzyme have been studied. The Km value for malate in case of native and modified enzyme was found to be identical. Km NADP for the modified enzyme was slightly higher indicating that after proteolysis the enzyme affinity for NADP had decreased. Limited proteolysis with trypsin did not show any appreciable change in fluorescence properties of the modified enzyme. Binding of NADPH to the enzyme was not affected after modification.     

Enzymatic modification of vegetable protein: Immobilization of Penicillium duponti enzyme on reconstituted collagen and the use of the immobilized-enzyme complex for solubilizing vegetable protein in a recycle reactor

Penicillium duponti enzyme was immobilized on reconstituted collagen by macromolecular complication, impregnation, and covalent crosslinking techniques. The immobilization of the enzyme on collagen has a twofold purpose: (1) providing a protein microenvironment for the proteolytic enzyme; and (2) extending the useful life the enzyme once immobilized on the collagen matrix. Two types of collagen were used, one produced by the United States Department of Agriculture and the other produced by FMC. The USDA collagen contained unhydrolyzed telepeptide linkages and required pretreatment to reduce collagenaselike activity of the enzyme. Activity analysis of the immobilized enzyme complex showed that membranes with enzyme loading less than 10 mg enzyme/g of wet membrane in the reactor were dimensionally stable. The degree of crosslinking was an important parameter. Membranes with structural opening up to three times the initial dry thickness were found to be the maximum limit for controlled release of enzyme from the collagen membrane during enzymatic reaction. Higher activities and better stability of the enzyme in collagen membrane were found for covalent crosslinking of the enzyme to treated collagen films. The hydrolysis of soybean vegetable protein with the immobilized enzyme in a recycle reactor at enzyme loading of mg/g of wet membrane at 40°C, pH 3.4, produced 56.5% of soluble protein in 10h. The production is equivalent to 1.84 h total contact time between the substrate and the immobilized enzyme. The average productivity based on a stable enzyme activity and 20g of dry membrane was 329 mg of protein/g/mg of active enzyme immobilized. The productivity of the free enzyme in a batch reactor was 62.5 mg protein/h/mg enzyme.