Isolation and some properties of extracellular heat-stable lipases from Pseudomonas fluorescens strain AFT 36

Aeration increased the growth and lipase production in milk by Pseudomonas fluorescens strain AFT 36, isolated from refrigerated bulk milk. A heat-stable lipase was isolated from a shaken milk culture of this microorganism by DEAE-chromatography and gel filtration in Sepharose 6B. The lipase-rich fraction from DEAE cellulose contained 3 lipases that were separated by gel filtration; only the principal lipase, which represented approximately 71% of total lipolytic activity, was characterized. The purified enzyme showed maximum activity on tributyrin at pH 8.0 and 35 degrees C; it had a Km on tributyrin of 3.65 mM and was inhibited by concentrations of substrate greater than approximately 17 mM. The enzyme was very stable over the pH range 6-9; it was relatively heat-labile in phosphate buffer in the temperature range 60-80 degrees C, where it was stabilized significantly by Ca2+. It was, however, very stable at 100-150 degrees C: the D values at 150 degrees C were approximately 22 s and 28 s in phosphate buffer and synthetic milk serum respectively; the corresponding Z values in the temperature range 100-150 degrees C were approximately 40 and approximately 42 degrees C and the Ea for inactivation were 7.65 X 10(4) J mol-1 and 6.97 X 10(4) J mol-1 respectively.     

Cold-active lipolytic activity of psychrotrophic Acinetobacter sp. strain no. 6

A lipolytic bacterium, strain no. 6, was isolated from Siberian tundra soil. It was a gram-negative coccoid rod capable of growing at 4 degrees C but not at 37 degrees C and was identified as a psychrotrophic strain of the genus Acinetobacter. Strain no. 6 extracellularly produced a lipolytic enzyme that efficiently hydrolyzed triglycerides such as soybean oil during bacterial growth even at 4 degrees C; it degraded 60% of added soybean oil (initial concentration, 1% w/v) after cultivation in LB medium at 4 degrees C for 7 d. Thus, the bacterium is potentially applicable to in-situ bioremediation or bioaugumentation of fat-contaminated cold environments. We partially purified the lipolytic enzyme from the culture filtrate by acetone fractionation and characterized it. The enzyme preparation contained a single species of cold-active lipase with significant activity at 4 degrees C, which was 57% of the activity at the optimum temperature (20 degrees C). The enzyme showed a broad specificity toward the acyl group (C8-C16) of substrate ethyl esters.     

PRODUCTION AND PROPERTIES OF PENCILLIUM ROQUEFORTI LIPASE

SUMMARY: A Penicillium roqueforti strain produced maximal amounts of lipase when grown in 0.5% casitone-1% Proflo broth, pH 5.5, at 27°C. Addition of butteroil, com oil or olive oil to the growth medium inhibited the lipase production. Under pH stasis the partially purified lipase of P. roqueforti had an optimum pH of 8.0 and an optimum temperature of 37°C. Maximum lipolytic activity occurred with 5% butteroil emulsion as the substrate. Manganese chloride and magnesium chloride stimulated the enzyme activity. Calcium, sodium and potassium sale had no appreciable effect on lipolysis; silver, mercury and zinc salts were inhibitory. The lipase was thermolabile, being inactivated completely within 10 min at 50°C. The lipase hydrolyzed tributyrin, tricaprylin, tricaprin, tripropionin and triolein in decreasing order.     

Psychrotrophic, proteolytic and lipolytic properties of Enterobacteriaceae isolated from milk and dairy products

Most of the Enterobacteriaceae strains (73 out of 75) isolated in a previous study (Wessels et al., 1988) were psychrotrophic on agar plates, with the exception of Enterobacter cloacae strains. The Enterobacteriaceae strains were largely non-proteolytic on milk agar medium although limited numbers of E. cloacae, Serratia rubidaea and Klebsiella oxytoca strains were capable of proteolytic activity at 25 degrees C. The E. cloacae and K. oxytoca strains positive at 25 degrees C were also proteolytic at 7 degrees C. Most of the species tested were non-lipolytic on Victoria blue butterfat agar. The majority of Serratia marcescens and Klebsiella pneumoniae strains and a minority of E. cloacae and K. oxytoca strains, however, were lipolytic on this medium.     

Purification and characterization of a monoacylglycerol lipase from Pseudomonas sp. LP7315

A monoacylglycerol lipase (MGL) was purified from Pseudomonas sp. LP7315 by ammonium sulfate precipitation, anion-exchange chromatography, and preparative electrophoresis. The purified enzyme was homogeneous on SDS-PAGE with a molecular mass of 59 kDa. Its hydrolytic activity was confirmed to be specific for monoglycerides: the enzyme did not hydrolyze di- and triglycerides. MGL was found to be stable even after 1-h incubation at 65 degrees C. The optimum pH for monopalmitin hydrolysis was approximately 8. The hydrolytic activity depended not only on temperature and pH but also on the type of monoglyceride used. MGL also catalyzed monoglyceride synthesis at 65 degrees C in a solvent-free two-phase system, in which fatty acid droplets were dispersed in the glycerol phase with a low water content. The synthetic reaction proceeded at a constant rate for approximately 24 h and approximately reached an equilibrium after 48 h of reaction. The initial rate and equilibrium yield of the synthetic reaction depended on the type of fatty acid used as the substrate.     

Physiology of dairy-associated Bacillus spp. over a wide pH range

Bacillus species isolated from alkaline wash solutions used for cleaning in place in South African dairy factories have been suggested to contaminate product contact surfaces of dairy processing equipment and result in post-pasteurization spoilage of milk and milk products. Growth and attachment of such Bacillus isolates under alkaline and acidic conditions have not been previously described. Therefore, the in vitro growth temperature and pH ranges, attachment abilities and hydrophobicity, and enzyme production capabilities of four Bacillus isolates (tentatively identified as B. subtilis115, B. pumilus122, B. licheniformis137 and B. cereus144) previously isolated from the alkaline wash solutions in a South African dairy were examined. Growth pH ranges were determined in buffered Standard One-like Nutrient Broth and in unbuffered 1% Milk Medium at pH values ranging from 3 to 12. Growth and attachment to stainless steel surfaces and production of protease and lipase enzymes were determined in 1% Milk Medium at pH 4, 7 and 10. Colony hydrophobicity of each isolate by the Direction of Spreading Method (DOS) was also determined at pH 4, 7 and 10. In addition, Arrhenius plots were used to examine the growth temperature ranges of the isolates. All isolates grew at pH values ranging from 4.5 to 9.5 in buffered Standard One-like Nutrient Broth, and from pH 4 to 10 in 1% Milk Medium. All isolates also attached to stainless steel at pH 4, 7 and 10 in 1% Milk Medium. Generally the attachment of B. subtilis115, B. pumilus122 and B. lichenformis137 to stainless steel surfaces was enhanced at pH 4 and 10, compared to pH 7. By contrast, the best attachment of B. cereus144 cells to stainless steel surfaces was at pH 7. Planktonic and attached cells of all isolates produced proteolytic enzymes at pH 7 and 10, but not at pH 4. Similarly, planktonic and attached cells of B. subtilis115, B. pumilus122 and B. licheniformis137 produced lipolytic enzymes at pH 7 and 10, and weak lipolysis was observed at pH 4. The Bacillus cereus144 isolate showed no lipolytic activity at pH 10. All isolates exhibited low hydrophobic properties at all pH values even though attachment to stainless steel at the same pH values occurred. None of the isolates grew below 11 degrees C or above 56 degrees C, and optimum growth temperatures were in the high mesophilic range (36-44 degrees C).     

Bovine pancreatic lipase.I.Isolation, homogeneity, and characterization.

Bovine pancreatic lipase was isolated in pure form by lyophilization of fresh bovine pancreas, extraction of the enzyme with sucrose solution, fractional precipitation with ammonium sulfate and acetone, followed by chromatography on Sephadex G-100. The specific activity of the purest lipase fraction was 1750 micromoles fatty acid, liberated in 30 min per milligram of protein, indicating a purification of approximately 473-fold, with an overall yield of about 42%. Homogeneity of the enzyme was confirmed by rechromatography on Sephadex G-100 as well as with the gel electrophoretic and ultracentrifugal techniques. The purified enzyme gave a typical protein ultraviolet absorption spectrum with maximum absorption at 276 nm and minimum at 252 nm. The purified enzyme exhibited a single pH optimum of 8.8 and an isoelectric point near pH 5.5. Its optimum temperature was 37 C, and its optimum substrate concentration was 10%. These properties resembled those of milk lipase.     

Lipolytic Enzyme Activity of Macrophages in Bovine Mammary Gland Secretions

The ability of macrophages isolated from the involuted bovine mammary gland and pooled raw milk to secrete lipolytic enzymes was investigated. Macrophages obtained from the involuted gland and maintained in cell culture secreted lipolytic enzymes into culture medium for up to 120 h. Leukocytes in pooled raw milk were separated using Ficoll discontinuous density gradients. Macro-phages secreted lipolytic enzymes into the gradient while fractions containing polymorphonuclear leukocytes and lymphocytes did not possess lipolytic activity. Enzyme activity of macrophages from pooled raw milk averaged .1% of the total milk lipoprotein lipase activity present in the original milk samples. Fresh raw milk with a macrophage concentration increased to 2.5 × 10⁶ cells/ml contained 11.6% higher milk lipoprotein lipase activity after storage for 48 h at 4°C. These results indicate that macrophages isolated from bovine mammary secretions produce lipolytic enzymes that could influence milk lipoprotein lipase activity in raw milk over storage.     

Sources, properties and suitability of new thermostable enzymes in food processing

Investigations concerning recombinant a-amylases from Pyrococcus woesei and thermostable a-glucosidase from Thermus thermophilus indicate their suitability for starch processing. Furthermore, the study of recombinant ss-galactosidase from Pyrococcus woesei suitable for purpose of low lactose milk and whey production are also presented. The activity of this enzyme in a wide pH range of 4.3-6.6 and high thermostability suggests that it can be used for processing of dairy products at temperatures which restrict microbial growth during a long operating time of continuous-flow reactor with an immobilized enzyme system. Preparation of recombinant a-amylase and ss-galactosidase was facilitated by cloning and expression of genes from Pyrococcus woesei in Escherichia coli host. Satisfactory level of recombinant enzymes purification was achieved by thermal precipitation of native proteins originated from Escherichia coli. The obtained a-amylase has maximal activity at pH 5.6 and 93 degrees C. The half-life of this preparation (pH 5.6) at 90 degrees C and 110 degrees C was 11 h and 3.5 h, respectively, and retained 24% of residual activity following incubation for 2 h at 120 degrees C. An advantageous attribute of recombinant a -amylase is independence of its activity and stability on calcium salt. a-Glucosidase from Thermus thermophilus also not require metal ions for stability and retained about 80% of maximal activity at pH range 5.8-6.9. Thus, this enzyme can be used together with recombinant a-amylase.     

Purification and characterization of organic solvent-stable lipase from organic solvent-tolerant Pseudomonas aeruginosa LST-03

An organic solvent-stable lipase (LST-03 lipase) secreted into the culture broth of the organic solvent-tolerant Pseudomonas aeruginosa LST-03 was purified by ion-exchange and hydrophobic interaction chromatography in the presence of 2-propanol. The purified enzyme was homogeneous as determined by SDS-PAGE. The molecular mass of the lipase was estimated to be 27.1 kDa by SDS-PAGE and 36 kDa by gel filtration. The optimum pH and temperature were 6.0 and 37 degrees C. LST-03 lipase was stable at pH 5-8 and below 40 degrees C. Its hydrolytic activity was highest against tricaproin (C6), methyl octanoate (C8), and coconut oil respectively among the triacylglycerols, fatty acid methyl esters, and natural oils investigated. The enzyme cleaved not only the 1,3-positioned ester bonds, but also the 2-positioned ester bond of triolein. It exhibited high levels of activity in the presence of n-decane, n-octane, DMSO, and DMF as well as in the absence of an organic solvent. In addition, LST-03 lipase was stabler in the presence of n-decane, ethyleneglycol, DMSO, n-octane, n-heptane, isooctane, and cyclohexane than in the absence of an organic solvent.     

Purification and characterization of an extracellular lipase from Mucor hiemalis f. corticola isolated from soil

We have screened 39 microfungi isolates originated from soil in terms of lipolytic activity. Out of all screened, a novel strain of Mucor hiemalis f. corticola was determined to have the highest lipase activity. The extracellular lipase was produced in response to 2% glucose and 2.1% peptone. The lipase was purified 12.63-folds with a final yield of 27.7% through following purification steps; ammonium sulfate precipitation, dialysis, gel filtration column chromatography and ion exchange chromatography, respectively. MALDI-TOF MS analysis revealed 31% amino-acid identity to a known lipase from Rhizomucor miehei species. The molecular weight of the lipase was determined as 46kDa using SDS-PAGE and analytical gel filtration. Optimal pH and temperature of the lipase were determined as 7.0 and 40°C, respectively. The enzyme activity was observed to be stable at the pH range of 7.0-9.0. Thermostability assays demonstrated that the lipase was stable up to 50°C for 60min. The lipase was more stable in ethanol and methanol than other organic solvents tested. Furthermore, the activity of the lipase was slightly enhanced by SDS and PMSF. In the presence of p-NPP as substrate, K(m) and V(max) values of the lipase were calculated by Hanes-Woolf plot as 1.327mM and 91.11μmol/min, respectively.     

粘质沙雷氏菌膜结合葡萄糖酸脱氢酶的分离纯化及其酶学特性

经超声破碎细胞、TritonX-114相分离、盐析、DEAE-sepharose离子交换层析和Hydroxyapatite吸附层析等步骤,从2-酮基葡萄糖酸（2-keogluconic acid,2KGA）生产菌株粘质沙雷氏菌JUIM03中获得比活力91.43 U/mg、纯化倍数160.4 倍的膜结合葡萄糖酸脱氢酶（gluconate dehydrogenase,GADH）。研究结果表明,粘质沙雷氏菌膜结合GADH由3 个亚基组成,其分子质量分别为65.0、45.0 kDa和23.0 kDa左右,是一种含有细胞色素C的黄素蛋白,能够催化氧化葡萄糖酸为2KGA。粘质沙雷氏菌膜结合GADH的最适反应温度为40 ℃,最适反应pH 5.0,在30 ℃以下、pH 5.0～6.0的条件下较为稳定;该酶具有严格的底物特异性,只有在D-葡萄糖酸作为底物时才具有催化活性,其Km值为1.33 mmol/L;一些金属离子（如Fe3＋、Cu2＋和Zn2＋）、有机溶剂（乙醇、异丙醇、甲醇和丙酮）、变性剂（十二烷基硫酸钠和巯基乙醇）以及有机酸（草氨酸和草酸）对膜结合GADH的催化活性具有明显的抑制作用。研究为粘质沙雷氏菌2KGA生物合成的过程优化与控制提供了一定的理论依据。     

Milk lipoprotein lipase distribution in the major fractions of bovine milk

Raw, bovine bulk tank milk and milks from selected cows were separated by ultracentrifugation into four major fractions: casein, sloughed membrane material, serum, and milk fat globule membrane. Milk lipoprotein lipase activity was measured by the pH stat method and protein determinations were made by the Lowry procedure for each of the four fractions in order to calculate specific activity (units per milligram of protein). In six farm-cooled bulk milk samples stored less than or equal to 24 h, casein had a significantly higher milk lipoprotein lipase total activity, 35.66 units/ml of milk, than all of the fractions. Serum had the next highest activity with 11.69 units/ml of milk. Fluff and milk fat globule membrane had activities of .80 and .41 units/ml of milk, respectively. The specific activity of the fluff was 3.3 milk lipoprotein lipase units/mg of protein, which was significantly higher than the casein and serum fractions in pooled milk. Milks from five cows in midlactation were assayed individually for milk lipoprotein lipase activity and protein content immediately after milking and after 12, 24, 48 and 72 h of cold (4 degrees C) storage. Fresh warm milk was characterized by the absence of fluff. Casein had the highest mean activity (29.91 units/ml), followed by serum (10.25 units/ml) and milk fat globule membrane (.26 units/ml) in the warm milk from the individual cows. Upon cooling to 4 degrees C, significant increases in enzyme activity in the fluff and milk fat globule membrane fractions were observed at 12 h.(ABSTRACT TRUNCATED AT 250 WORDS)     

A Sensitive and Robust Method for Direct Determination of Lipolytic Activity in Natural Milk Environment

Microbial lipases may be produced during milk storage and processing. This can lead to organoleptic changes in the corresponding dairy products. Thus, monitoring of lipase activity in milk is desirable. Turbidity of milk prevents a direct photometric measurement of lipase activity using chromophore- or fluorophore-based assays. Laborious pretreatments or alternative analytical methods normally have to be used. With the method for the determination of lipolytic activity (MeDeLi) proposed here, it is possible to measure lipase activity directly in the natural milk utilizing tailored fluorometric substrates. Only a defatting step is carried out initially for the MeDeLi. Then, the conversion of added lipase substrate is carried out in the unmodified milk without addition of any solutions or any enzyme extraction procedure which may influence the enzyme activity. Thereafter, the milk sample is treated with two solutions to remove the turbidity of milk by dissolution. A valid and sensitive fluorometric measurement is then possible. The applicability of the MeDeLi was demonstrated in comparison with tests published previously: The limit of detection for lipolytic activity measured by MeDeLi was the lowest, with 41 pkat/mL. Raw milk, milk products, and spoiled milk samples were also investigated with the MeDeLi.     

Effects of pH, temperature, supplementation with whey protein concentrate, and adjunct cultures on the production of exopolysaccharides by Streptococcus thermophilus 1275

Effects of pH, temperature, supplementation with whey protein concentrate (WPC), and non-EPS culture on the exopolysaccharide (EPS) production by Streptococcus thermophilus 1275 were studied. The organism was grown in 10% reconstituted skim milk (RSM) in a Biostat B fermenter for 24 h at various pH (4.5, 5.5 and 6.5) and temperatures (30, 37, 40, and 42 degrees C), and supplementation with WPC 392, and non-EPS producing S. thermophilus 1303 and the amount of EPS produced were determined. Bacterial counts were enumerated and the concentrations of lactic acid, lactose, glucose, and galactose were also determined. A maximum of 406 mg/L of EPS was produced in RSM at 37 degrees C after 24 h of fermentation at pH 4.08 when the pH was not controlled. A pH of 5.5 and temperature of 40 degrees C were found to be optimal for EPS production by S. thermophilus 1275, yielding 458 mg/L. The EPS production increased when RSM was supplemented with WPC 392. At optimum pH and at 37 degrees C with WPC supplementation, the level of EPS increased to 1029 mg/L. Co-culturing S. thermophilus 1275 with non-EPS S. thermophilus 1303 increased EPS production at 37 degrees C and pH 5.5 to 832 mg/L. High temperature (42 degrees C) reduced the amount of EPS production, and EPS production ceased at pH 4.5 when maintained constantly at this pH. The level of lactose utilization and lactic acid production depended on growth conditions of the organism. No glucose was detected, while galactose was found to accumulate in the medium.     

Synthesis of extracellular lipase by a strain ofPseudomonas fluorescensisolated from raw camel milk

Ten strains of psychrotrophic bacteria were isolated from raw camel milk and were arranged according to their lipase production. Lipolytic activities ranged between 0.26 to 3.43 meq of palmetic acid 100 g^-;1of bovine milk fat h^-;1.Pseudomonas fluorescensRM₄was the most active strain. This bacterium could grow and secrete lipase over a wide range of temperatures. The optimum temperature for growth was 37°C, and the maximum lipase production was at 25°C. Growth was maximal after 96 h of incubation at 25°C, and lipase activity was maximal at 72 h post-inoculation at 25°C (during the late logarithmic phase). Shaking of the cultures (100 rpm) led to an increase in both growth and enzyme activities. Pseudomonas fluorescensRM₄was able to grow and secrete lipase over a pH range of 5.5-;8.50. Synthesis of the enzyme appeared to be inducible because no enzyme was detected in the absence of organic nitrogen. Supplementation of the basal medium with milk proteins enhanced lipase production. Tryptophan and lysine induced enzyme synthesis most effectively. Addition of 4 g l^-;1of glucose to broth stimulated both growth and production of lipase. Beyond this level of supplementation, lipase activity was considerably depressed.     

Purification and Partial Characterization of Caprine Milk Lipoprotein Lipase

Lipoprotein lipases of caprine and bovine milks were isolated, purified, and partially characterized from raw whole milk. Fractions with enzyme activity were two for caprine and one for bovine lipase. The milk lipoprotein lipase enzyme fractions were purified further by hydroxylapatite and intervent dilution chromatography. Caprine enzyme fractions were purified 142,000 and 87,000-fold from the isolates compared to the bovine enzyme, which was purified 5500-fold. For the two caprine enzyme fractions were three distinct electrophoretic bands of molecular weights 66,100; 58,900; and 55,000. Electrophoretic patterns of the two fractions were similar. Isoelectric focusing of the highly purified caprine fractions also revealed heterogeneity with minor differences in isoelectric points, pH 5.02 and 5.14. Bovine enzyme had two distinct electrophoretic bands with molecular weights of 74,100 and 66,100, but poly aery lamide gel electrophoresis in the absence of sodium dodecylsulfate or β-mercaptoethanol revealed only one major band indicating a quaternary structure. The pH optimum of the caprine milk lipoprotein lipase was 8.7 compared to bovine enzyme of 8.5. Increase of yield of enzyme from both species during purification was attributed to several factors, the most important being the removal of an inhibitor. If in milk, this inhibitor may play a role in susceptibility of milk to hydrolytic rancidity.     

Purification and characterization of the lipase from Pseudomonas fluorescens HU380

A lipase, which markedly splits polyunsaturated fatty acid ester (PUFA) bonds, from newly isolated Pseudomonas fluorescens HU380 was purified. The purification procedure included Phenyl-Toyopearl fractionation, DEAE-Sepharose chromatography, and Superdex-200HR chromatography. The enzyme was purified 24.3-fold with a yield of 14% and a specific activity of 9854 U/mg. Its molecular weight was estimated on SDS-PAGE to be 64,000. The optimum pH and temperature were 8.5 and 45 degrees C, respectively. The lipase was stable over the pH range of 6.0-7.0 at 30 degrees C for 24 h, and up to 40 degrees C at pH 7.0 for 60 min, when 0.1% Triton X-100 was present. The lipase preferably acted on short to middle-chain fatty acid simple methyl-esters and triglycerides, and cleaved mainly 1,3-ester bonds and to a lesser extent the 2-position ester bond of triolein. The lipase was inhibited by Co2+, Ni2+, Fe3+, Fe2+, and EDTA, and activated by Ca2+. Its N-terminal amino acid sequence was determined to be GVYDYKNFGTADSKALFSDAMAITLY, which exhibited considerable similarity with those of the lipases from other P. fluorescens strains, but no significant homology with other lipases. This lipase was able to decompose fats and oils that contained eicosapentaenoic acid (EPA) and docosahexaenoic acid (DHA) without significantly affecting the contents of these fatty acids. The results suggest that the lipase may be useful when applied to the processing of industrial fats and oils containing EPA and DHA, such as fish oil splitting.     

Coagulating and lipolytic activities of artisanal lamb rennet pastes

Lamb rennet pastes were prepared by the procedure most commonly used by Idiazabal cheese manufacturers. We studied the effects on their coagulating and lipolytic activities of the state of the stomach at the time of death (full of milk or empty), the amount of NaCl added, the origin of the lambs and paste storage time. Coagulating activities were generally between 155 and 363 units/g tissue. Pastes prepared from stomachs of lambs from slaughterhouse flocks had significantly higher coagulating activities than those of lambs from separate flocks. No significant decrease in coagulating activity was observed after 1 year storage at 4 degrees C. Chymosin represented 75-80% of the total coagulating activity with the remainder being pepsin. Rennet paste extracts with pH < 4.7 did not have increased coagulating activities when their pH was lowered to 2.0, while those with pH > 5.2 had activities 1.5-fold those before treatment. Lipase activity was higher in extracts of rennet pastes prepared using the stomachs of lambs that arrived at the slaughterhouse in the morning just prior to slaughter than in those prepared with the stomachs of lambs that had arrived on the previous evening. However, the reverse was the case for esterase activity. Activating the coagulating activity by pH cycling completely destroyed both lipolytic activities. Storage at 4 degrees C for > 1 year did not affect esterase activity but lipase activity decreased substantially after 4-5 months. Lipase, but not esterase, activity was responsible for the liberation of short-chain free fatty acids from ovine milk fat.     

Properties of proteases from milk somatic cells and blood leukocytes

Proteolytic activity of proteases associated with somatic cells isolated from high SCC milk and proteases associated with leukocytes isolated from bovine blood was assayed at pH 6.6 and 5.2 in a model system consisting of a beta-casein (.96%) substrate in Jenness/Koops buffer. Intact beta-casein and casein proteolysis products were measured by densitometric analysis of SDS-PAGE gels. Relative proteolytic activity was expressed as percentage degradation of beta-casein after 24 h at 37 degrees C per 1 x 10(6) cells/ml. Proteolytic activity associated with somatic cells isolated from bovine milk was 27.5 and 13.6% at pH 6.6 and 5.2, respectively. Proteolytic activity associated with leukocytes isolated from bovine blood was 16.0 and 8.4% at pH 6.6 and 5.2, respectively. Proteolytic activity at pH 6.6 was significantly higher for the somatic cells isolated from milk than for leukocytes isolated from blood. The reason for the difference in proteolytic activity of leukocytes isolated from blood of a healthy cow versus somatic cells isolated from milk produced by a cow with mastitis is not known. Further work is needed to determine whether the difference may be caused by a higher proportion of activated macrophages in somatic cells isolated from milk produced by cows with mastitis than in the leukocytes isolated from blood of healthy cows.