Production of L-lysine by immobilized trypsin. Study of DL-lysine methyl ester resolution

The possibility of producing L-lysine from chemically synthesized DL-lysine has been investigated. Optical resolution of racemic DK-lysine may be achieved by using the stereospecific esterasic activity of trypsin on DL-lysine methyl ester, which gives L-lysine and unchanged D-lysine methyl ester. SL-lysine methyl ester spontaneous hydrolysis may be neglected when operating at pH 5.5 and 30 degrees C. Effect of pH and substrate concentration on hydrolysis rate has been investigated when using as a catalyst either soluble or immobilized trypsin. For this purpose, trypsin was coupled onto an amine porous silica, Spherosil, activated with glutaraldehyde. The optimal pH is 5.8 for soluble trypsin and 6.0 for immobilized trypsin. It was yet possible to lower the parent optimal pH of immobilized trypsin, and thus increase its activity at 5.5, by co-grafting onto Spherosil an aminosilane, for enzyme coupling via glutaraldehyde activation and a positively charged diethyl amino ethyl (DEAE) silane, for decreasing the pH of trypsin microenvironment.     

Modes of inhibition of activities of trypsin and chymotrypsin by potassium thiocyanate

Potassium thiocyanate inhibited the activities of trypsin and chymotrypsin. The inhibition was mixed type on both enzymes with casein as substrate and on trypsin with tosyl-L-arginine methyl ester as substrate, but was uncompetitive on chymotrypsin with benzoyl-L-tyrosine p-nitroanilide as substrate.     

Properties of lactate dehydrogenase from the isopod, Saduria entomon

An anionic trypsin from pyloric caeca of chum salmon (Oncorhynchus keta) was purified by ammonium sulfate and acetone fractionation followed by affinity chromatography, gel-filtration, and DEAE-anion exchange chromatography. The apparent molecular mass was about 24 kDa as determined by SDS-PAGE. The anionic chum salmon trypsin was moderately active toward esterase substrates such as tosyl-L-arginine methyl ester and tosyl-L-lysine methyl ester. Its amidase activity for benzoyl-L-arginine p-nitroanilide was comparative to those of bovine and Streptomyces griseus trypsins. Kinetic characteristics of anionic chum salmon, bovine, and Streptomyces griseus trypsins toward inverse substrate (p-amidinophenyl ester) were compared. Inverse substrate behaved as a specific substrate for anionic chum salmon trypsin with specific binding, efficient acylation, and relatively slow deacylation.     

Kinetics of low molecular weight substrate hydrolysis by immobilized trypsin]

The catalytic properties of trypsin immoblized on silochrome were studied in a flow reactor with replacement. The hydrolysis of methyl ester N-n-tosyl-L-arginine obeys the Michaelis--Menten kinetics. The apparent K'm value for the system with immobilized trypsin is considerably lower than for native trypsin. The K'm value was decreased with an increase in the rate of the substrate flow through the reactor or when smaller-sized silochrome granules were used. It is assumed that the apparent K'm value for the immobilized system is due to diffusion. The effects of diffusion on the catalytic properties of the immobilized enzyme were estimated.     

Substrate activation of rat trypsins 1 and 2

Qualitative differences in the active center of rat trypsins 1 and 2 resulted in different ratios of K_cat for N¹-tosyl-l-arginine methyl ester vs K_cat for N¹-benzoyl-l-arginine ethyl ester. These ratios were 2.5 for trypsin 1 and 1.2 for trypsin 2.Substrate activation with N¹-tosyl-l-arginine methyl ester enhanced the catalytic rate constant of rat trypsin 1 2.5-fold and that of rat trypsin 2 only 1.5-fold. The increase in the catalytic rate constant found with N¹-benzoyl-l-arginine ethyl ester was the same (1.5-fold) for both trypsins. Consequently, at 20 mm substrate concentration, trypsin 1 catalyzed the esterolysis of N¹-tosyl-l-arginine methyl ester 4.5 times faster than that of N¹-benzoyl-l-arginine ethyl ester, while trypsin 2 was only 1.3 times more efficient with the first substrate.Furthermore, the activation of both rat enzymes by N-acetyl-l-tyrosine ethyl ester was even more effective than that obtained with the two cationic esters; the maximum rates of hydrolysis of this neutral substrate by trypsins 1 and 2 were enhanced 120- and 50-fold, respectively, by high concentrations of N-acetyl-l-tyrosine ethyl ester.     

Kinetics and mechanism of catalysis by proteolytic enzymes. The kinetics of hydrolysis of esters of γ-guanidino-l-α-toluene-p-sulphonamidobutyric acid by bovine trypsin and thrombin

1. Esters of gamma-guanidino-l-alpha-toluene-p-sulphonamidobutyric acid (alpha-N-toluene-p-sulphonyl-l-norarginine) have been synthesized and shown to be hydrolysed by bovine trypsin and thrombin. As substrates for these enzymes, they were better than esters of alpha-N-toluene-p-sulphonyl-l-homoarginine or of alpha-N-toluene-p-sulphonyl-l-ornithine but not as good as esters of alpha-N-toluene-p-sulphonyl-l-arginine. 2. With trypsin as catalyst, the methyl and propyl esters are hydrolysed at the same rate at high substrate concentrations and hence deacylation of the acyl-enzyme appears to be rate-determining. In the presence of thrombin, however, the methyl ester is hydrolysed much faster than the n-propyl ester. 3. The variation of k(0) with pH indicates that groups with pK((app.)) values of 7.05+/-0.02 and 6.53+/-0.02 must be dissociated in trypsin and thrombin respectively for hydrolysis to proceed. 4. Activation constants have been determined for the trypsin-catalysed hydrolysis of methyl gamma-guanidino-l-alpha-toluene-p-sulphonamidobutyrate and have been compared with the corresponding constants for the hydrolysis of homologous substrates. 5. Cholate increases k(0) and decreases K(m); the effects are more pronounced with thrombin than with trypsin.     

Activation of fibroblast procollagenase by mast cell proteases.

Proteases capable of activating procollagenase from gingiva and from fibroblast and macrophage monolayer cultures were harvested from homogenates of canine tumor mast cells. The mast cell proteases lysed casein and Azocoll but not native collagen. In low salt concentrations the enzymes existed at high molecular weight complexes, which were dissociated by increasing the salt concentration above 1.0 M (NaCl, KCl). Gel filtration in 1.4 M KCl separated the protease activity into three peaks, all of which activated procollagenase. Two of the enzymes showed substrate specificities (hydrolysis of p-tosyl-L-arginine methyl ester and benzoyl-tyrosine ethyl ester) and reactive center reactivities similar to pancreatic trypsin and chymotrypsin. Based on gel filtration, apparent molecular weights of 160 000 (p-tosyl-L-arginine methyl ester esterase), 90 000 (main procollagenase activator) and 36 000 benzoyl-tyrosine ethyl ester esterase) were determined. Activation of procollagenase resulted in a 18-20 000 decrease of the molecular weight. The activation was directly related to the amount of activator added within certain limits. Further addition of activator resulted in proteolytic inactivation of collagenase.     

Kinetics of hydrolysis of phenylthiazolones of arginine, homoarginine, norarginine, and canaavanine by trypsin.

Phenylthiazolones (PTAs) of arginine and its homologs and analogs, homoarginine, norarginine (alpha-amino-gamma-guanidinobutyric acid), canavanine, and gamma-hydroxyarginine, were prepared. A steady-state kinetic analysis of the trypsin [EC 3.4.21.4]-catalyzed hydrolysis reactions was carried out and the kinetic parameters for these internal thioesters were compared with those for normal linear ester substrates. PTA-gamma-hydroxyarginine was so labile that hydrolysis by the enzyme could not be followed. PTA-arginine has a specificity constant (Kcat/Km) comparable to that for the Nalpha-unblocked arginine ester substrate, though the value is about 0.1% of that for a specific ester substrate, Nalpha-tosylarginine methyl ester. PTA derivatives of canavanine and homoarginine were hydrolyzed with Kcat/Km walues of the same order of magnitude as that for PTA-arginine. However, PTA-noraginine was much less susceptible to tryptic hydrolysis that PTA-homoarginine, while the linear esters of norarginine are known to be more susceptible than those of homoarginine.     

Characterization of azidobenzamidines as photoaffinity labels for trypsin

Meta- and para-azidobenzamidine have been prepared and evaluated as photoaffinity labels. The compounds inhibit trypsin reversible in the dark and are competitive with substrate binding. Upon photolysis, irreversible noncompetitive inhibition is observed and is dependent upon concentration, photolysis time, and pH. Specificity of the probes is indicated by experiments in which p-tosyl-l-arginine methyl ester, a trypsin substrate, is used to protect against photoinactivation. Maximum inactivation of trypsin is achieved at pH 6.2 using either azidobenzamidine derivative. Evaluation of the pH dependence of photoaffinity labeling may provide a sensitive tool for probing conformational changes in inhibitor binding sites. These studies provide a basis for the use of azidobenzamidines as photoaffinity analogs of lysine and arginine side chains.     

Striking susceptibility of a kinin-yielding pentadeca-peptide to tryptic hydrolysis

Hydrolysis of Lys-Arg-Pro-Gly-Phe-Ser-Pro-Phe-Arg-Ser-Val-Gln-Val-Ser by trypsin (EC 3.4.21.4) yields lysyl-bradykinin by rupture of the Arg-Ser bond. The k_cat/K_m value found for this hydrolysis was 1.4 × 10¹⁰ M^?1 × sec^?1, which is 10^?5-fold higher than that obtained for the hydrolysis of bradykinyl-Ser-Val-Gln-Val-Ser. This effect was abolished by acetylation of the lysine amino groups of the pentadecapeptide. Contrarywise, the esterolytic activity of trypsin on bradykinin methyl ester was the same as in lysyl-bradykinin methyl ester. The high susceptibility of Lys-bradykinyl-Ser-Val-Gln-Val-Ser to trypsin catalysis is striking because: a) it constitutes the first example that an amino acid residue distant from the bond split may enhance trypsin catalysis; b) this pentadecapeptide is the best synthetic substrate so far described for trypsin and c) the value of k_cat/K_m for its hydrolysis is unusually high for proteases.     

Isolation and properties of enzyme preparations from the whale pancreas

A simple and convenient technique was developed for isolation of the proteolytic enzyme complexes from the whale (Balaenoptera) pancreas. The proposed techniques enables the proteolytic complexes to be obtained with the protein yield 2.6 times higher than the classical procedure. The proteolytic activity increased 3.2 times (casein as a substrate), esterase activities, 1.4 times (N-benzoyl-L-tyrosine methyl ester as a substrate) and 1.2 times (N-alpha-benzoyl-L-arginine ethyl ester as a substrate). Soybean and barley trypsin inhibitors and ovomycoid in free and immobilized state inhibit the esterase activities of the proteolytic complexes. An additional purification of the proteolytic complexes was carried out using the affinity sorbent Soybean trypsin inhibitor--Sepharose 4B. The molecular weight of the enzymes determined by means of PAAG electrophoresis was found to be 20 000-20 500. The hydrolysis of some synthetic substrates by the proteolytic enzyme complexes obtained according to the proposed techniques was being studied.     

N-glycohydrolysis of adenosine diphosphoribosyl arginine linkages by dinitrogenase reductase activating glycohydrolase (activating enzyme) from Rhodospirillum rubrum

The reaction catalyzed by the activating enzyme for dinitrogenase reductase from Rhodospirillum rubrum has been studied using an ADP-ribosyl hexapeptide, obtained from proteolysis of inactive dinitrogenase reductase, and synthetic analogs such as N alpha-dansyl-N omega-ADP-ribosylarginine methyl ester. The activating enzyme catalyzed N-glycohydrolysis of the ribosyl-guanidinium linkage releasing ADP-ribose and regenerating an unmodified arginyl guanidinium group. Optimal glycohydrolysis of the low molecular weight substrates occurred at pH 6.6 and required 1 mM MnCl2, but did not require ATP. The ADP-ribosyl hexapeptide (Km 11 microM), N alpha-dansyl-N omega-ADP-ribosylarginine methyl ester (Km 12 microM), N alpha-dansyl-N omega-ADP-ribosylarginine (Km 12 microM), N alpha-dansyl-N omega-1,N6-etheno-ADP-ribosylarginine methyl ester (Km 11 microM), and N alpha-dansyl-N omega-GDP-ribosylarginine methyl ester (Km 11 microM) were comparable substrates. N omega-ADP-ribosylarginine (Km 2 mM) was a poor substrate, and the activating enzyme did not catalyze N-glycohydrolysis of N alpha-dansyl-N omega-5'-phosphoribosylarginine methyl ester or N alpha-dansyl-N omega-ribosylarginine methyl ester. 13C NMR of N alpha-tosyl-N omega-ADP-ribosylarginine methyl ester established that the activating enzyme specifically hydrolyzed the alpha-ribosyl-guanidinium linkage. The beta-linked anomer was hydrolyzed only after anomerization to the alpha configuration. We recommend [arginine(N omega-ADP-alpha-ribose)]dinitrogenase reductase N-glycohydrolase (dinitrogenase reductase activating) and dinitrogenase reductase activating glycohydrolase as the systematic and working names for the activating enzyme.     

A Microtiter Plate Assay for the Characterization of Serine Proteases by Their Esterase Activity

The action of serine (and cysteine) proteases on peptide esters proceeds, as a generalization, orders of magnitude faster than the corresponding enzymatic hydrolysis of peptide bonds or peptide amides. Esterolysis liberates an alcohol while generating a free carboxyl group on the peptide; the proton produced can be detected by the use of an appropriate indicator. The action of trypsin on benzyloxycarbonylalanylarginine methyl ester was used as a model for the development of a simple microtiter plate assay procedure that takes advantage of the speed of these reactions and the ease of detection afforded by the color change of the indicator. A family of ester substrates of the form benzyloxycarbonylalanyl-X-methyl ester, in which X is one of the 20 common amino acids, was synthesized to allow the determination of the primary specificity profiles of serine proteases. Using a 96-well microtiter plate the specificity profiles of four enzymes with all 20 substrates can be carried out in approximately 4 h per enzyme, including setting up and data processing. The primary substrate preferences of trypsin, chymotrypsin, thrombin, pancreatic elastase, α-lytic protease, subtilisin, and proteinase K were determined to demonstrate the method and were found to be in good general agreement with reported specificities established by more conventional means.     

The secretory nature of the excretory gland cells of Strephanurus dentatus. 3. Proteinase inhibitors

A proteinase inhibitor(s) was found in extracts of the excretory gland cells, intestines, esophagi, reproductive organs, and body walls from Stephanurus dentatus adults. The specific activity of the inhibitor(s) in the excretory gland cell extract was 45–175 times greater than in the other tissues. It is heat stable at pH 5.0 and inhibits the esterolytic activity of trypsin and chymotrypsin using p-toluenesulfonyl-l-arginine methyl ester hydrochloride (TAME) and benzoyl-l-tyrosine ethyl ester (BTEE) as the substrates, respectively, and also the proteolytic activity of both chymotrypsin and trypsin using casein as the substrate. S. dentatus adults maintained in NCTC 109 medium, secreted a trypsin inhibitor.     

Tonin, an esteroprotease from rat submaxillary glands

Tonin is an enzyme found in the rat submaxillary glands which liberates angiotensin II from angiotensinogen, the Skeggs tetradecapeptide renin substrate, and angiotensin I. Tonin hydrolyzes benzoyl-arginine ethyl ester, benzoyl-arginine methyl ester, tosyl-arginine methyl ester, benzoyl-arginine p-nitroanilide and other small synthetic substrates at an optimum ph of 9.0. Tonin shows, however, a great specificity with respect to angiotensin I. Tonin is inhibited by diisopropyl fluorophosphate and phenylmethylsulfonyl fluoride at high concentrations (greater than 10(-2) M) and by soybean trypsin inhibitor and aprotinin. Tonin is thus an esteroprotease of the class of the serine protease with trypsin- and chymotrypsin-like activity. Tonin belongs to the same family of enzyme as glandular kallikrein and the gamma subunit of the nerve growth factor.     

Insights from molecular dynamics simulations into pH-dependent enantioselective hydrolysis of ibuprofen esters by Candida rugosa lipase

An interesting observation was found during our continued studies on the hydrolysis of ibuprofen esters by Candida rugosa lipase (CRL). An important role is played by pH in the stereospecific hydrolysis of these esters. The flap region of CRL plays a significant role in the access of the substrate to the active site of the enzyme. At pH 5.6, 48% of the methyl ester and 5% of the butyl ester of ibuprofen were hydrolysed in 5.5 h, whereas at pH 7.2, 9% of methyl ester and 45% of the butyl ester of ibuprofen was hydrolysed in a identical reaction time using CRL. This lead us to assume that CRL prefers the methyl ester of ibuprofen as a substrate at an acidic pH and the butyl ester of ibuprofen at a neutral pH. Therefore, in order to understand the role of pH in the substrate selection by CRL for the esters of ibuprofen we used the crystallographic coordinates of the open form of the CRL (1CRL) for molecular dynamics (MD) simulations under acidic and neutral conditions for 2 ns using GROMACS. The final structures obtained after simulation in acidic and neutral conditions were compared with the energy-minimized structure, and the root-mean-square deviations (r.m.s.ds) were calculated. The r.m.s.d. of the CRL flap at neutral pH was found to be greater than that of the CRL flap at acidic pH. The extent to which the flap opens at neutral pH allowed the bulkier substrate, the butyl ester of ibuprofen, to diffuse into the active site and provides the best enzyme-substrate fit for this specific substrate. At acidic pH there is a decreased opening of the flap thereby accommodating a more compact substrate, namely the methyl ester of ibuprofen. Thus, simulation experiments using MD provide reasonable insight for the pH-dependent substrate selectivity of CRL in aqueous environments.     

Kinetics of hydrolysis of amide and anilide substrates of p-guanidino-L-phenylalanine by bovine and porcine trypsins

The rates of hydrolysis of N alpha-benzoyl-p-guanidino-L-phenylalaninamide (Bz-GPA-NH2) and N alpha-substituted p-nitroanilides (pNA) of GPA (benzyloxycarbonyl(Z)-GPA-pNA, benzoyl(Bz)-GPA-pNA and acetyl(Ac)-GPA-pNA) by bovine and porcine trypsins were compared with those of arginine (Arg) substrates. The amide type substrates of GPA were hydrolyzed as fast as those of Arg by the two enzymes with much the same kcat/Km values, though significant differences were found between the kcat and Km values of GPA derivatives and those of Arg derivatives. The kinetic behavior of porcine trypsin toward GPA substrates was almost the same as that of the bovine enzyme. The ratio of the kcat value for Bz-GPA-OEt to that for Bz-GPA-NH2 was much larger than that for the ester to amide substrates of arginine, suggesting that the conformational change of the active site of trypsin induced by a benzene ring in the side chain of Bz-GPA-OEt specifically increases the velocity of the deacylation process of the ester substrate. Remarkably low values of both kcat and Km were found for the tryptic hydrolysis of Z-GPA-pNA and Ac-GPA-pNA, as well as on that of Bz-GPA-pNA (Tsunematsu, H., et al. (1983) J. Biochem. 94, 123-128). Z-GPA-pNA is the best substrate for the two trypsins among the three N alpha-substituted anilide substrates of GPA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Trypsin inactivation by intact Hymenolepis diminuta (Cestoda): some characteristics of the inactivated enzyme

In the presence of intact Hymenolepis diminuta, trypsin was inactivated; intact worms had no apparent effect on subtilisin, pepsin, or papain. Inactivation of trypsin was demonstrable using azoalbumin as a substrate, but the inactivated enzyme retained full catalytic activity against benzoyl-DL-arginine-p-nitroanilide, p-tosyl-L-arginine methyl ester (low molecular weight synthetic trypsin substrates) and p-nitro-p-guanidinobenzoate (an active site titrant). Inactivation was not reversible under conditions of heating, freezing and thawing, or prolonged dialysis of the enzyme. Analyses of inactivated 3H-trypsin by cationic and SDS-polyacrylamide gel electrophoresis, and gel chromatography failed to indicate the presence of a high molecular weight trypsin inhibitor associated with the inactivated enzyme; no low molecular weight, dissociable inhibitor was demonstrable following thermal denaturation of the inactivated enzyme. Analyses of trypsin after incubation in the presence of pulse-labeled worms also failed to demonstrate the presence of any inhibitor of worm origin associated with the inactivated enzyme. The data suggest that inactivation is the result of a small structural or conformational change in the enzyme molecule, a change which partially (rather than totally) inactivates the enzyme towards protein substrates.     

Surface-simulation synthesis of the substrate-binding site of an enzyme. Demonstration with trypsin.

From the X-ray co-ordinates of bovine trypsin and its complexes with substrate analogues (benzamidine) and with soya-bean trypsin inhibitor, a peptide (TP) was designed and synthesized by surface-simulation synthesis, a concept previously introduced by this laboratory, to mimic the binding site of trypsin. Also, a control peptide (CTP) was synthesized that contained all the amino acids present in the TP peptide, except that their order was randomized. The radioiodinated TP peptide bound specifically to adsorbents of benzamidine, whereas the control CTP peptide exhibited no binding activity. Conjugates to succinyl (3-carboxypropionyl)-lysozyme of the TP peptide, control CTP peptide and other unrelated peptides were examined by a radiometric binding assay for the ability to bind soya-bean trypsin inhibitor and human alpha 1-antitrypsin. Conjugates of the TP peptide exhibited considerable binding activity to adsorbents of soya-bean trypsin inhibitor or alpha 1-antitrypsin. None of the other peptide conjugates possessed any binding activity. Action of the active-site-directed reagents phenylmethanesulphonyl fluoride and di-isopropyl phosphorofluoridate on free TP and CTP peptides resulted in the modification of a serine residue in the TP peptide whereas the CTP peptide remained unaltered. The TP peptide, either in the free form or as a conjugate on succinyl-lysozyme, had no enzymic activity on protein substrates or on tosylarginine methyl ester. These findings indicated that the binding activity of an enzyme was well mimicked by the surface-stimulation peptide but that reproduction of the catalytic activity was not obtained.     

The behaviour of trypsin towards α-N-methyl-α-N-toluene-p-sulphonyl-l-lysine β-naphthyl ester. A new method for determining the absolute molarity of solutions of trypsin

1. alpha-N-Methyl-alpha-N-toluene-p-sulphonyl-l-lysine beta-naphthyl ester (MTLNE) was synthesized as its hydrobromide and shown to be slowly hydrolysed by bovine pancreatic trypsin. The acylation step, however, is so much faster than deacylation of the acyl-enzyme that spectrophotometric measurement of the ;burst' of beta-naphthol provides a convenient method for determining the absolute molarity of trypsin solutions. 2. By using the same stock solution of trypsin, application of this method at pH4.0 and pH7.0 as well as that of Bender et al. (1966) at pH3.7 gave concordant results. 3. Provided that [S](0)>[E](0), the size of the ;burst' is independent of substrate concentration. 4. In the trypsin-catalysed hydrolysis of alpha-N-toluene-p-sulphonyl-l-arginine methyl ester, MTLNE functions as a powerful non-competitive inhibitor. 5. There is no detectable reaction between MTLNE and either bovine pancreatic alpha-chymotrypsin at pH4.0 or bovine thrombin at pH6.0.