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.     

Enzyme immobilization on fibrin.

The following conclusions can be drawn concerning the utilization of fibrin to immobilized enzyme systems. Fibrin can be used both as a powder or membrane, to covalently immobilize trypsin with retention of activity. Carbon-14 labeled trypsin can be used to estimate the amount of immobilized enzyme on a proteinaceous support. Significant amounts of noncovalently coupled (adsorbed) enzyme are present on the surface of the support. Esterase activity of the immobilized labeled trypsin was inversely proportional to the amount of attached enzyme. Optimum TAME hydrolysis occurred at pH 8-8.4. The storage stability of trypsin was enhanced. Inhibition of trypsin esterase activity occurred at substrate concentrations greater than 30mM.     

棉铃虫幼虫中肠主要蛋白酶活性的鉴定

根据棉铃虫Helicoverpa armigera(Hubner)中肠酶液对蛋白酶专性底物在不同pH下的水解作用,棉铃虫中肠的3种丝氨酸蛋白酶得到鉴定。它们是：强碱性类胰蛋白酶,水 解a-N-苯甲酰-DL-精氨酸-p-硝基苯胺的最适pH在10.50以上;弱碱性类胰蛋白酶,水解p-甲苯磺酰-L-精氨酸甲酯的最适pH为8.50～9.00;类胰凝乳蛋白酶, 水解N一苯甲酰-L-酪氨酸乙酯的最适pH亦为8.50-9.00。中肠总蛋白酶活性用偶 氮酪蛋白测定,最适pH亦在10.50以上。Ca²⁺对昆虫蛋白酶无影响,Mg²⁺仅对弱碱性类胰蛋白酶有激活作用。对苯甲基磺酰氟和甲基磺酰-L-赖氨酸氯甲基酮对弱碱性类胰蛋白酶的抑制作用较强,而对强碱性类胰蛋白酶的抑制作用较弱。甲基磺酰-L苯丙氨酸氯甲基酮除能抑制类胰凝乳蛋白酶外,还能激活弱碱性类胰蛋白酶。对牛胰蛋白酶有强抑制作用的卵粘蛋白抑制剂对昆虫蛋白酶却无抑制作用。大豆胰蛋白酶抑制剂对该虫的3种丝氨酸蛋白酶均有强的抑制作用。     

Enzymic and physicochemical properties of Streptomyces griseus trypsin.

Streptomyces griseus trypsin has been isolated from Pronase by ion-exchange chromatography on CM-Sephadex and SE-Sephadex. The isolated enzyme was homogeneous by the criteria tested except for a low degree of contamination by an enzyme with nontryptic activity. The latter could be partially resolved by chromatography on Bio-Rex 70. The molar absorbancy at 280 nm was found to be 3.96 times 10-4 M-1/cm and the E1cm1% was found to be 17.3. The molecular weight was 22,800 plus or minus 800. The enzyme was found to be stable at 0 degrees from pH 2 to 10. At 30 degrees the enzyme was maximally stable at pH 3-4 and significantly stabilized in the neutral and alkaline range by 15 mM Ca2+. Some evidence was obtained for a reversible denaturation of the enzyme at pH 12.0 and 2.0. The K-m for N-alpha-benzoyl-L-arginine ethyl ester at pH 8.0 in 20 mM CaCl2-0.1 M KCl-10 mM Tris-HCl buffer at 30 degrees was found to be 7.7 plus or minus 1.9 times 10-6 M and the esterase activity was observed to be dependent on an ionizing group with pK-a equals 5.85. In 2H2O this pKa was increased to 6.35 and the rate of hydrolysis dicreased threefold. The rate of hydrolysis was independent of pH between 8 and 10. The inhibition of the enzyme with L-1-chloro-3-tosylamido-4-phenyl-2-butanone was shown to be associated with the alkylation of its single histidine residue. This residue is present in a homologous amino acid sequence as the active-site histidine in trypsin and chymotrypsin. Optical rotatory dispersion and circular dichroism measurements over the pH range 5.3-10.5 indicated no significant conformational change until the pH was increased above 10.1. The observation that, under the conditions tested, acetylation and carbamylation of the NH2-terminal valine were incomplete is consistent with the view that this group is buried as an ion pair and only becomes available for deprotonation and reaction upon denaturation of the enzyme at pH values greater than 10.0.     

Isolation and characterization of a trypsin fraction from the pyloric ceca of chinook salmon (Oncorhynchus tshawytscha)

A trypsin fraction was isolated from the pyloric ceca of New Zealand farmed chinook salmon (Oncorhynchus tshawytscha) by ammonium sulfate fractionation, acetone precipitation and affinity chromatography. The chinook salmon enzyme hydrolyzed the trypsin-specific synthetic substrate benzoyl-dl-arginine-p-nitroanilide (dl-BAPNA), and was inhibited by the general serine protease inhibitor phenyl methyl sulfonyl fluoride (PMSF), and also by the specific trypsin inhibitors — soybean trypsin inhibitor (SBTI) and benzamidine. The enzyme was active over a broad pH range (from 7.5 to at least pH 10.0) at 25 °C and was stable from pH 4.0 to pH 10.0 when incubated at 20 °C, with a maximum at pH 8.0. The optimum temperature for the hydrolysis of dl-BAPNA by the chinook salmon enzyme was 60 °C, however, the enzyme was unstable at temperatures above 40 °C. The molecular mass of the chinook salmon trypsin was estimated as 28 kDa by SDS–PAGE.     

Photeolytic activation of a lipolytic enzyme activity in potato leaves

Potato (Solanum tuberosum L.) leaves were shown to contain a lipolytic enzyme activity which is stimulated by treatment with purified trypsin, pronase, and to a lesser degree by chymotrypsin. This protease-stimulated activity was stable over a wide range of pH values. Lipolytic enzyme activity also appeared to be regulated by pH, with a pronounced stimulation at pH 6.0 ± 0.5 and a subsequent inactivation at pH 8.0–9.0. This pH stimulation was slightly by ethylene diamine tetracetic acid (EDTA), and was inhibited by Ca²⁺. Although leupeptin slightly inhibited the pH stimulation, two other protease inhibitors, phenylmethylsulfonyl fluoride (PMSF) and soybean trypsin inhibitor showed no effect. While some of the lipolytic enzyme activitiesn potato leaves (those detected by 1-acyl-2-[6-[(7-nitro-2,1,3 benzoxadiazol-4-yl) amino]-caproyl] phosphatidylcholine (C₆-NBD-PC) hydrolysis) are stimulated by protease or pH treatment, others (those detected by 4-methylumbelliferyl laurate (4MUL) hydrolysis) are inactivated by them. The possible physiological significance of this apparent proteolytic activation is discussed.     

Isolation and characteristics of trypsin from pyloric ceca of the starfish Asterina pectinifera

Trypsin was purified from pyloric ceca of the starfish Asterina Pectinifera by ammonium sulfate precipitation, gel filtration, and cation-exchange chromatography. Final enzyme preparation was nearly homogeneous in sodium dodecyl sulfate-polyacrylamide gel electrophoresis and its molecular weight was estimated as approximately 28000. Optimum pH and temperature of A. pectinifera trypsin for hydrolysis of N(alpha)-p-Tosyl-L-arginine methyl ester hydrochloride were approximately pH 8.0 and 55 degrees C, respectively. A. pectinifera trypsin was unstable at above 50 degrees C and below pH 5.0, and was not activated by adding Ca(2+). The N-terminal amino acid sequence of A. pectinifera trypsin, IVGGHEF, was found.     

Trypsin from Greenland cod, Gadus ogac. Isolation and comparative properties

Trypsin(ogen) was isolated from the pyloric ceca of Greenland cod. Greenland cod trypsin catalyzed hydrolysis of N alpha-benzoyl-DL-arginine p-nitroanilide, tosyl arginine methyl ester and protein and was inhibited by the serine protease inhibitor PMSF and other well-known trypsin inhibitors. Greenland cod trypsin was more stable at alkaline pH than at acid pH; and was inactivated by relatively low thermal treatment. Like other trypsins, the enzyme was rich in potential acidic amino acid residues but poor in basic amino acid residues and had a molecular weight of 23,500; but it had less potential disulfide pairs, less alpha-helix and a lower H phi ave than other trypsins previously characterized. Reactions catalyzed by Greenland cod trypsin were not very responsive to temperature change, such that specific activity was relatively high at low reaction temperature.     

Isolation of trypsin PC from the Kamchatka crab Paralithodes camtschatica and its properties]

Trypsin PC from the hepatopancreas of the king crab Paralithodes camtschatica was isolated and purified to apparent homogeneity by ion-exchange chromatography on Aminosilochrom and DEAE-Sephadex and affinity chromatography on arginine-agarose. The yield of the enzyme was 37.7%, and the purification degree was 21. Trypsin PC has a molecular mass of 29 kDa and pI < 2.5. It hydrolysis N-benzoyl-L-arginine p-nitroanilide at the optimum pH of 7.5-8.0 and at the temperature optimum of 55 degrees C (K(m) = 0.05 mM). Trypsin PC retained its activity within the pH range of 5.8-9.0 in the presence of Ca2+. The enzyme was inhibited by the specific inhibitors of serine proteases diisopropyl fluorophoshate and phenylmethylsulfonyl fluoride, by the trypsin inhibitor N-tosyl-L-lysylchloromethylketone, and by the trypsin inhibitors from soybean and potato. Trypsin PC was found to hydrolyze amide bonds formed by carboxylic groups of lysine and arginine in peptide substrates. The N-terminal sequence of this enzyme is IVGGTEVTPG.     

Protein hydrolysis by immobilized and stabilized trypsin

The preparation of novel immobilized and stabilized derivatives of trypsin is reported here. The new derivatives preserved 80% of the initial catalytic activity toward synthetic substrates [benzoyl-arginine p-nitroanilide (BAPNA)] and were 50,000-fold more thermally stable than the diluted soluble enzyme in the absence of autolysis. Trypsin was immobilized on highly activated glyoxyl-Sepharose following a two-step immobilization strategy: (a) first, a multipoint covalent immobilization at pH 8.5 that only involves low pK(a) amino groups (e.g., those derived from the activation of trypsin from trypsinogen) is performed and (b) next, an additional alkaline incubation at pH 10 is performed to favor an intense, additional multipoint immobilization between the high concentration of proximate aldehyde groups on the support surface and the high pK(a) amino groups at the enzyme surface region that participated in the first immobilization step. Interestingly, the new, highly stable trypsin derivatives were also much more active in the proteolysis of high molecular weight proteins when compared with a nonstabilized derivative prepared on CNBr-activated Sepharose. In fact, all the proteins contained a cheese whey extract had been completely proteolyzed after 6 h at pH 9 and 50°C, as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Under these experimental conditions, the immobilized biocatalysts preserve more than 90% of their initial activity after 20 days. Analysis of the three-dimensional (3D) structure of the best immobilized trypsin derivative showed a surface region containing two amino terminal groups and five lysine (Lys) residues that may be responsible for this novel and interesting immobilization and stabilization. Moreover, this region is relatively far from the active site of the enzyme, which could explain the good results obtained for the hydrolysis of high-molecular weight proteins.     

CRYSTALLINE CHYMO-TRYPSIN AND CHYMO-TRYPSINOGEN : I. ISOLATION,CRYSTALLIZATION, AND GENERAL PROPERTIES OF A NEW PROTEOLYTIC ENZYME AND ITS PRECURSOR

A new crystalline protein, chymo-trypsinogen, has been isolated from acid extracts of fresh cattle pancreas. This protein is not an enzyme but is transformed by minute amounts of trypsin into an active proteolytic enzyme called chymo-trypsin. The chymo-trypsin has also been obtained in crystalline form. The chymo-trypsinogen cannot be activated by enterokinase, pepsin, inactive trypsin, or calcium chloride. There is an extremely slow spontaneous activation upon standing in solution. The activation of chymo-trypsinogen by trypsin follows the course of a monomolecular reaction the velocity constant of which is proportional to the trypsin concentration and independent of the chymotrypsinogen concentration. The rate of activation is a maximum at pH 7.0–8.0. Activation is accompanied by an increase of six primary amino groups per mole but no split products could be found, indicating that the activation consists in an intramolecular rearrangement. There is a slight change in optical activity but no change in molecular weight. The physical and chemical properties of both proteins are constant through a series of fractional crystallizations. The activity of chymo-trypsin decreases in proportion to the destruction of the native protein by pepsin digestion or denaturation by heat or acid. Chymo-trypsin has powerful milk-clotting power but does not clot blood plasma and differs qualitatively in this respect from the crystalline trypsin previously reported. It hydrolyzes sturin, casein, gelatin, and hemoglobin more slowly than does crystalline trypsin but the hydrolysis of casein is carried much further. The hydrolysis takes place at different linkages from those attacked by trypsin. The optimum pH for the digestion of casein is about 8.0–9.0. It does not hydrolyze any of a series of dipeptides or polypeptides tested. Several chemical and physical properties of both proteins have been determined.     

Some peculiarities of trypsin and heparin interaction]

The interaction of trypsin with an acid polysaccharide, heparin, at pH 4.2 and 8.0 is studied. Heparin is found to destabilize the enzyme under condition of both autolytic denaturation (pH 8.0) and thermoinactivation (pH 4.2). Data on trypsin inactivation kinetics suggest that the stage of forming molecular complexes with different contents of trypsin and heparin precedes the stage of the enzyme denaturation. Maximal trypsin inactivation rate takes place under equimolar enzyme:heparin ration.     

Identification of the reactive (inhibitory) sites of chymotryptic inhibitor I from potatoes

Chymotryptic Inhibitor I from potato tubers was subjected to limited hydrolysis with catalytic amounts of chymotrypsin and trypsin at pH 3. The fragmen     

INACTIVATION OF CRYSTALLINE TRYPSIN

1. The rate of inactivation of crystalline trypsin solutions and the nature of the products formed during the inactivation at various pH at temperatures below 37°C. have been studied. 2. The inactivation may be reversible or irreversible. Reversible inactivation is accompanied by the formation of reversibly denatured protein. This denatured protein exists in equilibrium with the native active protein and the equilibrium is shifted towards the denatured form by raising the temperature or by increasing the alkalinity. The decrease in the fraction of active enzyme present (due to the formation of this reversibly denatured protein) as the pH is increased from 8.0 to 12.0 accounts for the decrease in the rate of digestion of proteins by trypsin in this range of pH. 3. The loss of activity at high temperatures or in alkaline solutions, just described, is very rapid and is completely reversible for a short time only. If the solutions are allowed to stand the loss in activity becomes gradually irreversible and is accompanied by the appearance of various reaction products the nature of which depends upon the temperature and pH of the solution. 4. On the acid side of pH 2.0 the trypsin protein is changed to an inactive form which is irreversibly denatured by heat. The course of the reaction in this range is monomolecular and its velocity increases as the acidity increases. 5. From pH 2.0 to 9.0 trypsin protein is slowly hydrolyzed. The course of the inactivation in this range of pH is bimolecular and its velocity increases as the alkalinity increases to pH 10.0 and then decreases. As a result of these two reactions there is a point of maximum stability at about pH 2.3. 6. On the alkaline side of pH 13.0 the reaction is similar to that in strong acid solution and consists in the formation of inactive protein. The course of the reaction is monomolecular and the velocity increases with increasing alkalinity. From pH 9.0 to 12.0 some hydrolysis takes place and some inactive protein is formed and the course of the reaction is represented by the sum of a bi- and monomolecular reaction. The rate of hydrolysis decreases as the solution becomes more alkaline than pH 10.0 while the rate of formation of inactive protein increases so that there is a second point at about pH 13.0 at which the rate of inactivation is a minimum. In general the decrease in activity under all these conditions is proportional to the decrease in the concentration of the trypsin protein. Equations have been derived which agree quantitatively with the various inactivation experiments.     

胰蛋白酶水解β-乳球蛋白获得ACE抑制肽的条件优化

采用三因素二次通用旋转设计和体外检测法,对胰蛋白酶水解β-乳球蛋白获得ACE抑制肽的条件进行优化。结果表明,底物浓度(X1)、温度(X2)、酶与底物的质量比(X3)对ACE抑制率的影响回归方程为:Y=50.62-2.33X1-1.97X2+5.81 X3-3.36X2X3-6.56X22-1.96X32,胰蛋白酶水解β-乳球蛋白获得ACE抑制肽的最优水解条件为:底物质量浓度为60 g/L,水解温度30℃,酶与底物的质量比为5.5%,水解时间6 h,水解产物对ACE抑制活性最大抑制率为53.86%。     

Trypsin from the pyloric caeca of bluefish (Pomatomus saltatrix)

Trypsin was purified from the pyloric caeca of bluefish (Pomatomus saltatrix) by ammonium sulfate precipitation, acetone precipitation and soybean trypsin inhibitor-Sepharose 4B affinity chromatography. Bluefish trypsin migrated as a single band using both sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) and native-PAGE and had a molecular mass of 28 kDa. The optima pH and temperature for the hydrolysis of benzoyl-dl-arginine-p-nitroanilide (BAPNA) were 9.5 and 55 °C, respectively. The enzyme was stable over a broad pH range (7 to 12), but was unstable at acidic pH, and at temperatures greater than 40 °C. The enzyme was inhibited by specific trypsin inhibitors: soybean trypsin inhibitor (SBTI), N-p-tosyl-l-lysine chloromethyl ketone (TLCK) and the serine protease inhibitor phenylmethyl sulfonylfluoride (PMSF). CaCl₂ partially protected trypsin against activity loss at 40 °C, but NaCl (0 to 30%) decreased the activity in a concentration dependent manner. The N-terminal amino acid sequence of trypsin was determined as IVGGYECKPKSAPVQVSLNL and was highly homologous to other known vertebrate trypsins.     

A trypsin and chymotrypsin inhibitor from chick peas (Cicer arietinum).

1. A trypsin and chymotrypsin inhibitor was isolated by extraction of chick-pea meal at pH8.3, followed by (NH4)2SO4 precipitation and successive column chromatography on CM-cellulose and calcium phosphate (hydroxyapatite). 2. The inhibitor was pure by polyacrylamide-gel and cellulose acetate electrophoresis and by isoelectric focusing in polyacrylamide gels. 3. The inhibitor had a molecular weight of approx. 10000 as determined by ultracentrifugation and by polyacrylamide-gel electrophoresis in the presence of sodium dodecyl sulphate. A molecular weight of 8300 was resolved from its amino acid composition. 4. The inhibitor formed complexes with trypsin and chymotrypsin at molar ratios of 1:1. 5. Limited proteolysis of the inhibitor with trypsin at pH3.75 resulted in hydrolysis of a single-Lys-X-bond and in consequent loss of 85% of the trypsin inhibitory activity and 60% of the chymotrypsin inhibitory activity. Limited proteolysis of the inhibitor with chymotrypsin at pH3.75 resulted in hydrolysis of a single-Tyr-X-bond and in consequent loss of 70% of the trypsin inhibitory activity and in complete loss of the chymotrypsin inhibitory activity. 6. Cleavage of the inhibitor with CNBr followed by pepsin and consequent separation of the products on a Bio Gel P-10 column, yielded two active fragments, A and B. Fragment A inhibited trypsin but not chymotrypsin, and fragment B inhibited chymotrypsin but not trypsin. The specific trypsin inhibitory activity, on a molar ratio, of fragment A was twice that of the native inhibitor, suggesting the unmasking of another trypsin inhibitory site as a result of the cleavage. On the other hand, the specific chymotrypsin inhibitory activity of fragment B was about one-half of that of the native inhibitor, indicating the occurrence of a possible conformational change.     

Purification and some properties of cholesterol oxidase from Schizophyllum commune with covalently bound flavin.

Cholesterol oxidase [EC 1.1.3.6] from Schizophyllum commune was purified by an affinity chromatography using 3-O-succinylcholesterol-ethylenediamine (3-cholesteryl-3-[2-aminoethylamido]propionate) Sepharose gels. The resulting preparation was homogeneous as judged by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis. The molecular weight of the enzyme was estimated to be 53,000 by SDS-gel electrophoresis and 46,000 by sedimentation equilibrium. The enzyme contained 483 amino acid residues as calculated on the basis of the molecular weight of 53,000. The enzyme consumed 60 mumol of O2/min per mg of protein with 1.3 mM cholesterol at 37 degrees C. The enzyme showed the highest activity with cholesterol; 3 beta-hydroxysteroids, such as dehydroepiandrosterone, pregnenolone, and lanosterol, were also oxidized at slower rates. Ergosterol was not oxidized by the enzyme. The Km for cholesterol was 0.33 mM and the optimal pH was 5.0. The enzyme is a flavoprotein which shows a visible absorption spectrum having peaks at 353 nm and 455 nm in 0.1 M acetate buffer, pH 4.0. The spectrum was characterized by the hypsochromic shift of the second absorption peak of the bound flavin. The bound flavin was reduced on anaerobic addition of a model substrate, dehydroepiandrosterone. Neither acid not heat treatment released the flavin coenzyme from the enzyme protein. The flavin of the enzyme could be easily released from the enzyme protein in acid-soluble form as flavin peptides when the enzyme protein was digested with trypsin plus chymotrypsin. The mobilities of the aminoacyl flavin after hydrolysis of the flavin peptides on thin layer chromatography and high voltage electrophoresis differed from those of free FAD, FMN, and riboflavin. A pKa value of 5.1 was obtained from pH-dependent fluorescence quenching process of the aminoacyl flavin. AMP was detected by hydrolysis of the flavin peptides with nucleotide pyrophosphatase. The results indicate strongly that cholesterol oxidase from Schizophyllum commune contains FAD as the prothetic group, which is covalently linked to the enzyme protein. The properties of the bound FAD were comparable to those of N (1)-histidyl FAD.     

Extracellular serine protease synthesis by mosquito-pathogenic strains of Bacillus sphaericus

Nine strains of Bacillus sphaericus toxic to mosquito larvae produced haloes of hydrolysis when cultured on casein-nutrient agar. In batch culture, protease synthesis by B. sphaericus BSE 18 occurred during exponential growth and was repressed by high concentrations of peptone. Extracellular protease from this bacterium showed optimal activity at about pH 10.2, was inhibited by phenylmethylsulphonyl chloride and chymostatin but not soybean trypsin inhibitor or EDTA. Hydrolysis of N -CBZ-glycine-nitrophenyl ester was consistent with the major enzyme being a serine protease.     

A functional comparison of ovine and porcine trypsins

Trypsin was isolated from ovine and porcine pancreas using affinity chromatography on immobilized p-aminobenzamidine. Molecular masses of the two proteins were 23900 and 23435 Da, determined by matrix-assisted laser desorption/ionisation time of flight (MALDI-TOF) mass spectrometry. The purified trypsins were compared using the kinetic properties K(m) and k(cat) which were determined at pH 8.0 and between 25 and 55 degrees C. Comparison of the Michaelis constants for ovine and porcine trypsins toward N-alpha-benzoyl-arginine-p-nitroanilide (BapNA) indicated that ovine trypsin had higher affinity for this substrate than the porcine enzyme. The rates of the reactions catalysed by the two enzymes correlated strongly over the range of temperatures and substrate concentrations tested, as did the k(cat) values. The specific activity of ovine trypsin for BapNA was, on average, approximately 10% higher than that of the porcine enzyme over the range of conditions tested. Porcine trypsin was less susceptible to denaturation at low pH or high temperature than was ovine trypsin. Porcine and ovine trypsin produced seven identically sized fragments from auto-catalytic hydrolysis. Proposed regions of identity between ovine and porcine trypsins were I(54)-K(77), L(98)-R(107), S(134)-K(178) and N(209)-K(116). Hydrolysis of beta-lactoglobulin, egg white lysozyme or casein by ovine or porcine trypsin yielded virtually identical patterns of fragments although the rate at which fragments were produced, in the case of beta-lactoglobulin, differed between the two enzymes. On balance the two enzymes appear to be functionally identical in their action.