Partial Isolation and Degradation of Caseins by Cell Wall Proteinase(s) of Streptococcus cremoris HP

The cell wall proteinase fraction of Streptococcus cremoris HP has been isolated. This preparation did not exhibit any activity due to either specific peptidases known to be located near the outside surface of and in the membrane or intracellular proteolytic enzymes. By using thin-layer chromatography for the detection of relatively small hydrolysis products which remain soluble at pH 4.6, it was shown that β-casein is preferentially attacked by the cell wall proteinase. This was also the case when whole casein or micelles were used as the substrate. κ-casein hydrolysis is a relatively slow process, and α_s-casein degradation appeared to proceed at an extremely low rate. These results could be confirmed by using ¹⁴CH₃-labeled caseins. A relatively fast and linear initial progress of ¹⁴CH₃-labeled β-casein degradation is not inhibited by α_s-casein and only slightly by κ-casein at concentrations of these components which reflect their stoichiometry in the micelles. Possible implications of β-casein degradation for growth of the organism in milk are discussed.     

Cell-Wall-Bound Proteinase of Lactobacillus delbrueckii subsp. lactis ACA-DC 178: Characterization and Specificity for β-Casein

Lactobacillus delbrueckii subsp. lactis ACA-DC 178, which was isolated from Greek Kasseri cheese, produces a cell-wall-bound proteinase. The proteinase was removed from the cell envelope by washing the cells with a Ca²⁺-free buffer. The crude proteinase extract shows its highest activity at pH 6.0 and 40°C. It is inhibited by phenylmethylsulfonyl fluoride, showing that the enzyme is a serine-type proteinase. Considering the substrate specificity, the enzyme is similar to the lactococcal P_I-type proteinases, since it hydrolyzes β-casein mainly and α- and κ-caseins to a much lesser extent. The cell-wall-bound proteinase from L. delbrueckii subsp. lactis ACA-DC 178 liberates four main peptides from β-casein, which have been identified.     

Identification of the 64 kilodalton chloroplast stromal phosphoprotein as phosphoglucomutase

Phosphorylation of the 64 kilodalton stromal phosphoprotein by incubation of pea (Pisum sativum) chloroplast extracts with [γ-³²P]ATP decreased in the presence of Glc-6-P and Glc-1,6-P₂, but was stimulated by glucose. Two-dimensional gel electrophoresis following incubation of intact chloroplasts and stromal extracts with [γ-³²P]ATP, or incubation of stromal extracts and partially purified phosphoglucomutase (EC 2.7.5.1) with [³²P]Glc-1-P showed that the identical 64 kilodalton polypeptide was labeled. A 62 kilodalton polypeptide was phosphorylated by incubation of tobacco (Nicotiana sylvestris) stromal extracts with either [γ-³²P]ATP or [³²P]Glc-1-P. In contrast, an analogous polypeptide was not phosphorylated in extracts from a tobacco mutant deficient in plastid phosphoglucomutase activity. The results indicate that the 64 (or 62) kilodalton chloroplast stromal phosphoprotein is phosphoglucomutase.     

Proteinase production by a species of Cephalosporium

An unidentified Cephalosporium species produced an extracellular proteinase when grown in a variety of fermentation media under submerged culture conditions. Maximal enzyme yields were obtained in a medium containing 2% corn meal, 1% soybean meal, and 0.5% CaCO₃ in tap water. Optimal proteinase production in this medium occurred within a 72- to 96-hr growth period. High enzyme yields were also attained with media in which cottonseed meal, Fermatein, Pharmamedia, or soybean-α-protein was substituted for the soybean meal. The substitution of these ingredients for the corn meal resulted in significantly decreased proteinase yields. The addition of minerals or vitamins to the corn meal-soybean meal fermentation medium failed to enhance proteinase production. The enzyme was most active in an alkaline environment; maximal caseinolysis occurred at pH 7.5, whereas pH 8.5 was optimal for either hemoglobin or β-lactoglobulin hydrolysis. Enzymatic activity was also noted with either bovine albumin fraction V or soybean-α-protein substrates, whereas ovalbumin was not susceptible to enzymatic attack. The enzyme was stable within the pH range of 3.0 to 9.5 at 25 C for 2 hr, and at 5 C for 24 hr. The proteinase was stable upon heating for 10 min at 35 to 45 C, but it was totally inactivated at 70 C. The proteinase was unaffected by soybean inhibitor, partially inactivated by lima bean inhibitor, and completely inactivated by ovomucoid inhibitor.     

The Contribution of Caseins to the Amino Acid Supply for Lactococcus lactis Depends on the Type of Cell Envelope Proteinase

The ability of caseins to fulfill the amino acid requirements of Lactococcus lactis for growth was studied as a function of the type of cell envelope proteinase (P_I versus P_III type). Two genetically engineered strains of L. lactis that differed only in the type of proteinase were grown in chemically defined media containing α_s1-, β-, and κ-caseins (alone or in combination) as the sources of amino acids. Casein utilization resulted in limitation of the growth rate, and the extent of this limitation depended on the type of casein and proteinase. Adding different mixtures of essential amino acids to the growth medium made it possible to identify the nature of the limitation. This procedure also made it possible to identify the amino acid deficiency which was growth rate limiting for L. lactis in milk (S. Helinck, J. Richard, and V. Juillard, Appl. Environ. Microbiol. 63:2124–2130, 1997) as a function of the type of proteinase. Our results were compared with results from previous in vitro experiments in which casein degradation by purified proteinases was examined. The results were in agreement only in the case of the P_I-type proteinase. Therefore, our results bring into question the validity of the in vitro approach to identification of casein-derived peptides released by a P_III-type proteinase.     

Isolation and Characterization of Glutamyl Endopeptidase 2 from Bacillus intermedius 3-19

The culture filtrate of Bacillus intermedius 3-19 was used for isolation by chromatography on CM-cellulose and Mono S columns of a proteinase that is secreted during the late stages of growth. The enzyme is irreversibly inhibited by the inhibitor of serine proteinases diisopropyl fluorophosphate, has two pH optima (7.2 and 9.5) for casein hydrolysis and one at pH 8.5 for Z-Glu-pNA hydrolysis. The molecular weight of the enzyme is 26.5 kD. The K(m) for Z-Glu-pNA hydrolysis is 0.5 mM. The temperature and pH dependences of the stability of the proteinase were studied. The enzyme was identified as glutamyl endopeptidase 2. The N-terminal sequence (10 residues) and amino acid composition of the enzyme were determined. The enzyme hydrolyzes Glu4-Gln5, Glu17-Asp18, and Cys11-Ser12 bonds in the oxidized A-chain of insulin and Glu13-Ala14, Glu21-Arg22, Cys7-Gly8, and Cys19-Gly20 bonds in the oxidized B-chain of insulin.     

Substrate Specificity of Barley Cysteine Endoproteases EP-A and EP-B

The cysteine endoproteases (EP)-A and EP-B were purified from green barley (Hordeum vulgare L.) malt, and their identity was confirmed by N-terminal amino acid sequencing. EP-B cleavage sites in recombinant type-C hordein were determined by N-terminal amino acid sequencing of the cleavage products, and were used to design internally quenched, fluorogenic peptide substrates. Tetrapeptide substrates of the general formula 2-aminobenzoyl-P₂-P₁-P₁′-P₂′-tyrosine(NO₂)-aspartic acid, in which cleavage occurs between P₁ and P₁′, showed that the cysteine EPs preferred phenylalanine, leucine, or valine at P₂. Arginine was preferred to glutamine at P₁, whereas proline at P₂, P₁, or P₁′ greatly reduced substrate kinetic specificity. Enzyme cleavage of C hordein was mainly determined by the primary sequence at the cleavage site, because elongation of substrates, based on the C hordein sequence, did not make them more suitable substrates. Site-directed mutagenesis of C hordein, in which serine or proline replaced leucine, destroyed primary cleavage sites. EP-A and EP-B were both more active than papain, mostly because of their much lower K_m values.     

Purification and Characterization of an X-Prolyl-Dipeptidyl Peptidase from Lactobacillus sakei

An X-prolyl-dipeptidyl peptidase has been purified from Lactobacillus sakei by ammonium sulfate fractionation and five chromatographic steps, which included hydrophobic interaction, anion-exchange chromatography, and gel filtration chromatography. This procedure resulted in a recovery yield of 7% and an increase in specificity of 737-fold. The enzyme appeared to be a dimer with a subunit molecular mass of approximately 88 kDa. Optimal activity was shown at pH 7.5 and 55°C. The enzyme was inhibited by serine proteinase inhibitors and several divalent cations (Cu²⁺, Hg²⁺, and Zn²⁺). The enzyme almost exclusively hydrolyzed X-Pro from the N terminus of each peptide as well as fluorescent and colorimetric substrates; it also hydrolyzed X-Ala at the N terminus, albeit at lower rates. K_m s for Gly-Pro- and Lys-Ala-7-amido-4-methylcoumarin were 29 and 88 μM, respectively; those for Gly-Pro- and Ala-Pro-p-nitroanilide were 192 and 50 μM, respectively. Among peptides, β-casomorphin 1-3 was hydrolyzed at the highest rates, while the relative hydrolysis of the other tested peptides was only 1 to 12%. The potential role of the purified enzyme in the proteolytic pathway by catalyzing the hydrolysis of peptide bonds involving proline is discussed.     

Hydrolysis of alpha(s, 1)-Casein B by Streptococcus lactis Membrane Proteinase

The membrane-associated proteinase of Streptococcus lactis strain 3 hydrolyzed α_{s, 1}-casein B into 11 peptide fragments. Eight of the 11 peptides were purified and partially characterized. Each peptide contained several, but not all six, essential amino acids required for growth. The culture was able to utilize one peptide as the sole source for the essential amino acid leucine. Leucine, serine, valine, and glycine were found to be NH₂-terminal residues. Two of the peptides were phosphopeptides. The data support the functional role of the membrane-associated proteinase as being involved in the initial breakdown of proteins to peptides.     

Comparative Study of Action of Cell Wall Proteinases from Various Strains of Streptococcus cremoris on Bovine αs1-, β-, and κ-Casein

Partially purified cell wall proteinases of eight strains of Streptococcus cremoris were compared in their action on bovine α_s1-, β-, and κ-casein, as visualized by starch gel electrophoresis, sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and thin-layer chromatography. Characteristic degradation profiles could be distinguished, from which the occurrence of two proteinases, represented by strain HP and strain AM₁, was concluded. The action of the HP-type proteinase P₁ (also detectable in strains Wg₂, C₁₃, and TR) was established by electrophoretic methods to be directed preferentially towards β-casein. The AM₁-type proteinase P_III (also detectable in strain SK₁₁) was also able to degrade β-casein, but at the same time split α_s1- and κ-casein more extensively than did P_I. Strain FD₂₇ exhibited mainly P_I activity but also detectable P_III degradation characteristics. The cell wall proteinase preparation of strain E₈ showed low P_I as well as low P_III activity. All proteinase preparations produced from κ-casein positively charged degradation products with electrophoretic mobilities similar to those of degradation products released by the action of the milk-clotting enzyme chymosin. The differences between P_I and P_III in mode of action, as detected by gel electrophoresis and thin-layer chromatography, were reflected by the courses of the initial degradation of methyl-¹⁴C-labeled β-casein and by the effect of α_s1- plus κ-casein on these degradations. The results are discussed in the light of previous comparative studies of cell wall proteinases in strains of S. cremoris and with respect to the growth of this organism in milk.     

Characterization of a Cell Envelope-Associated Proteinase Activity from Streptococcus thermophilus H-Strains

The production and biochemical properties of cell envelope-associated proteinases from two strains of Streptococcus thermophilus (strains CNRZ 385 and CNRZ 703) were compared. No significant difference in proteinase activity was found for strain CNRZ 385 when cells were grown in skim milk medium and M17 broth. Strain CNRZ 703 exhibited a threefold-higher proteinase activity when cells were grown in low-heat skim milk medium than when grown in M17 broth. Forty-one percent of the total activity of CNRZ 385 was localized on the cell wall. The optimum pH for enzymatic activity at 37°C was around 7.0. Serine proteinase inhibitors, such as phenylmethylsulfonyl fluoride and diisopropylfluorophosphate, inhibited the enzyme activity in both strains. The divalents cations Ca²⁺, Mg²⁺, and Mn²⁺ were activators, while Zn²⁺ and Cu²⁺ were inhibitors. β-Casein was hydrolyzed more rapidly than α_s1-casein. The results of DNA hybridization and immunoblot studies suggested that the S. thermophilus cell wall proteinase and the lactococcal proteinase are not closely related.     

Pyrophosphate Fructose-6-P 1-Phosphotransferase from Tomato Fruit : Evidence for Change during Ripening

Three forms of pyrophosphate fructose-6-phosphate 1-phosphotransferase (PFP) were purified from both green and red tomato (Lycopersicon esculentum) fruit: (a) a classical form (designated Q₂) containing α- (66 kilodalton) and β- (60 kilodalton) subunits; (b) a form (Q₁) containing a β-doublet subunit; and (c) a form (Q₀) that appeared to contain a β-singlet subunit. Several lines of evidence suggested that the different forms occur under physiological conditions. Q₂ was purified to apparent electrophoretic homogeneity; Q₁ and Q₀ were highly purified, but not to homogeneity. The distribution of the PFP forms from red (versus green) tomato was: Q₂, 29% (90%); Q₁, 47% (6%); and Q₀, 24% (4%). The major difference distinguishing the red from the green tomato enzymes was the fructose-2,6-bisphosphate (Fru-2,6-P₂)-induced change in K_m for fructose-6-phosphate (Fru-6-P), the `green forms' showing markedly enhanced affinity on activation (K<sub>m</sub> decrease of 7-9-fold) and the `red forms' showing either little change (Q₀, Q₁) or a relatively small (2.5-fold) affinity increase (Q₂). The results extend our earlier findings with carrot root to another tissue and indicate that forms of PFP showing low or no affinity increase for Fru 6-P on activation by Fru-2,6-P₂ (here Q₁ and Q₀) are associated with sugar storage, whereas the classical form (Q₂), which shows a pronounced affinity increase, is more important for starch storage.     

Degradation of Native Starch Granules by Barley alpha-Glucosidases

The initial hydrolysis of native (unboiled) starch granules in germinating cereal kernels is considered to be due to α-amylases. We report that barley (Hordeum vulgare L.) seed α-glucosidases (EC 3.2.1.20) can hydrolyze native starch granules isolated from barley kernels and can do so at rates comparable to those of the predominant α-amylase isozymes. Two α-glucosidase charge isoforms were used individually and in combination with purified barley α-amylases to study in vitro starch digestion. Dramatic synergism, as much as 10.7-fold, of native starch granule hydrolysis, as determined by reducing sugar production, occurred when high pl α-glucosidase was combined with either high or low pl α-amylase. Synergism was also found when low pl α-glucosidase was combined with α-amylases. Scanning electron micrographs revealed that starch granule degradation by α-amylases alone occurred specifically at the equatorial grooves of lenticular granules. Granules hydrolyzed by combinations of α-glucosidases and α-amylases exhibited larger and more numerous holes on granule surfaces than did those granules attacked by α-amylase alone. As the presence of α-glucosidases resulted in more areas being susceptible to hydrolysis, we propose that this synergism is due, in part, to the ability of the α-glucosidases to hydrolyze glucosidic bonds other than α-1,4- and α-1,6- that are present at the granule surface, thereby eliminating bonds which were barriers to hydrolysis by α-amylases. Since both α-glucosidase and α-amylase are synthesized in aleurone cells during germination and secreted to the endosperm, the synergism documented here may function in vivo as well as in vitro.     

Purification and Characterization of Leu-Proteinase, the Leucine Specific Serine Proteinase from Spinach (Spinacia oleracea L.) Leaves

The leucine specific serine proteinase present in the soluble fraction of leaves from Spinacia oleracea L. (called Leu-proteinase) has been purified by acetone precipitation and a combination of gel-filtration, ion exchange, and adsorption chromatography. This enzyme shows a molecular weight of 60,000 ± 3,000 daltons, an isoelectric point of 4.8 ± 0.1, and a relative electrophoretic mobility of 0.58 ± 0.03. The Leu-proteinase catalyzed hydrolysis of p-nitroanilides of N-α-substituted(-l-)amino acids as well as of chromogenic macromolecular substrates has been investigated between pH 5 and 10 at 23 ± 0.5°C and I = 0.1 molar. The enzyme activity is characterized by a bell-shaped profile with an optimum pH value around 7.5, reflecting the acid-base equilibrium of groups with pK_a values of 6.8 ± 0.1 and 8.2 ± 0.1 (possibly the histidyl residue present at the active site of the enzyme and the N-terminus group). Among the substrates considered, N-α-benzoyl-l-leucine p-nitroanilide shows the most favorable catalytic parameters and allows to determine an enzyme concentration as low as 1 × 10⁻⁹ molar. In agreement with the enzyme specificity, only N-α-tosyl-l-leucine chloromethyl ketone, di-isopropyl fluorophosphate and phenylmethylsulfonyl fluoride, among compounds considered specific for serine enzymes, strongly inhibit the Leu-proteinase. Accordingly, the enzyme activity is insensitive to cations, chelating agents, sulfydryl group reagents, and activators.     

Collagenolytic Serine-Carboxyl Proteinase from Alicyclobacillus sendaiensis Strain NTAP-1: Purification, Characterization, Gene Cloning, and Heterologous Expression

Enzymatic degradation of collagen produces peptides, the collagen peptides, which show a variety of bioactivities of industrial interest. Alicyclobacillus sendaiensis strain NTAP-1, a slightly thermophilic, acidophilic bacterium, extracellularly produces a novel thermostable collagenolytic activity, which exhibits its optimum at the acidic region (pH 3.9) and is potentially applicable to the efficient production of such peptides. Here, we describe the purification to homogeneity, characterization, gene cloning, and heterologous expression of this enzyme, which we call ScpA. Purified ScpA is a monomeric, pepstatin-insensitive carboxyl proteinase with a molecular mass of 37 kDa which exhibited the highest reactivity toward collagen (type I, from a bovine Achilles tendon) among the macromolecular substrates examined. On the basis of the sequences of the peptides obtained by digestion of collagen with ScpA, the following synthetic peptides were designed as substrates for ScpA and kinetically analyzed: Phe-Gly-Pro-Ala^*Gly-Pro-Ile-Gly (k_cat, 5.41 s⁻¹; K_m, 32 μM) and Met-Gly-Pro-Arg^*Gly-Phe-Pro-Gly-Ser (k_cat, 351 s⁻¹; K_m, 214 μM), where the asterisks denote the scissile bonds. The cloned scpA gene encoded a protein of 553 amino acids with a calculated molecular mass of 57,167 Da. Heterologous expression of the scpA gene in the Escherichia coli cells yielded a mature 37-kDa species after a two-step proteolytic cleavage of the precursor protein. Sequencing of the scpA gene revealed that ScpA was a collagenolytic member of the serine-carboxyl proteinase family (the S53 family according to the MEROPS database), which is a recently identified proteinase family on the basis of crystallography results. Unexpectedly, ScpA was highly similar to a member of this family, kumamolysin, whose specificity toward macromolecular substrates has not been defined.     

Entamoeba histolytica Cysteine Proteinase 5 Binds Integrin on Colonic Cells and Stimulates NFκB-mediated Pro-inflammatory Responses

Integrins are important mammalian receptors involved in normal cellular functions and the pathogenesis of inflammation and disease. Entamoeba histolytica is a protozoan parasite that colonizes the gut, and in 10% of infected individuals, causes amebic colitis and liver abscess resulting in 10⁵ deaths/year. E. histolytica-induced host inflammatory responses are critical in the pathogenesis of the disease, yet the host and parasite factors involved in disease are poorly defined. Here we show that pro-mature cysteine proteinase 5 (PCP5), a major virulent factor that is abundantly secreted and/or present on the surface of ameba, binds via its RGD motif to α_Vβ₃ integrin on Caco-2 colonic cells and stimulates NFκB-mediated pro-inflammatory responses. PCP5 RGD binding to α_Vβ₃ integrin triggered integrin-linked kinase(ILK)-mediated phosphorylation of Akt-473 that bound and induced the ubiquitination of NF-κB essential modulator (NEMO). As NEMO is required for activation of the IKKα-IKKβ complex and NFκB signaling, these events markedly up-regulated pro-inflammatory mediator expressions in vitro in Caco-2 cells and in vivo in colonic loop studies in wild-type and Muc2^−/− mice lacking an intact protective mucus barrier. These results have revealed that EhPCP5 RGD motif is a ligand for α_Vβ₃ integrin-mediated adhesion on colonic cells and represents a novel mechanism that E. histolytica trophozoites use to trigger an inflammatory response in the pathogenesis of intestinal amebiasis.     

Mechanism of Proteinase Release from Lactococcus lactis subsp. cremoris Wg2

The procedure generally used for the isolation of extracellular, cell-associated proteinases of Lactococcus lactis species is based on the release of the proteinases by repeated incubation and washing of the cells in a Ca²⁺-free buffer. For L. lactis subsp. cremoris Wg2, as many as five incubations for 30 min at 29°C are needed in order to liberate 95% of the proteinase. Proteinase release was not affected by chloramphenicol, which indicates that release is not the result of protein synthesis during the incubations. Ca²⁺ inhibited, while ethylene glycol-bis(β-aminoethyl ether)-N,N,N′,N′-tetraacetic acid (EGTA) stimulated, proteinase release from the cells. The pH optimum for proteinase release ranged between 6.5 and 7.5, which was higher than the optimum pH of the proteinase measured for casein hydrolysis (i.e., 6.4). Treatment of cells with the serine proteinase inhibitor phenylmethylsulfonyl fluoride prior to the incubations in Ca²⁺-free buffer reduced the release of the proteinase by 70 to 80%. The residual proteinase remained cell associated but could be removed by the addition of active L. lactis subsp. cremoris Wg2 proteinase. This suggests that proteinase release from cells of L. lactis subsp. cremoris Wg2 is the result of autoproteolytic activity. From a comparison of the N-terminal amino acid sequence of the released proteinase with the complete amino acid sequence determined from the nucleotide sequence of the proteinase gene, a protein of 180 kilodaltons would be expected. However, a proteinase with a molecular weight of 165,000 was found, which indicated that further hydrolysis had occurred at the C terminus.     

Angiotensin I-Converting-Enzyme-Inhibitory and Antibacterial Peptides from Lactobacillus helveticus PR4 Proteinase-Hydrolyzed Caseins of Milk from Six Species

Sodium caseinates prepared from bovine, sheep, goat, pig, buffalo or human milk were hydrolyzed by a partially purified proteinase of Lactobacillus helveticus PR4. Peptides in each hydrolysate were fractionated by reversed-phase fast-protein liquid chromatography. The fractions which showed the highest angiotensin I-converting-enzyme (ACE)-inhibitory or antibacterial activity were sequenced by mass spectrum and Edman degradation analyses. Various ACE-inhibitory peptides were found in the hydrolysates: the bovine α_S1-casein (α_S1-CN) 24-47 fragment (f24-47), f169-193, and β-CN f58-76; ovine α_S1-CN f1-6 and α_S2-CN f182-185 and f186-188; caprine β-CN f58-65 and α_S2-CN f182-187; buffalo β-CN f58-66; and a mixture of three tripeptides originating from human β-CN. A mixture of peptides with a C-terminal sequence, Pro-Gly-Pro, was found in the most active fraction of the pig sodium caseinate hydrolysate. The highest ACE-inhibitory activity of some peptides corresponded to the concentration of the ACE inhibitor (S)-N-(1-[ethoxycarbonyl]-3-phenylpropyl)-ala-pro maleate (enalapril) of 49.253 μg/ml (100 μmol/liter). Several of the above sequences had features in common with other ACE-inhibitory peptides reported in the literature. The 50% inhibitory concentration (IC₅₀) of some of the crude peptide fractions was very low (16 to 100 μg/ml). Some identified peptides were chemically synthesized, and the ACE-inhibitory activity and IC₅₀s were confirmed. An antibacterial peptide corresponding to β-CN f184-210 was identified in human sodium caseinate hydrolysate. It showed a very large spectrum of inhibition against gram-positive and -negative bacteria, including species of potential clinical interest, such as Enterococcus faecium, Bacillus megaterium, Escherichia coli, Listeria innocua, Salmonella spp., Yersinia enterocolitica, and Staphylococcus aureus. The MIC for E. coli F19 was ca. 50 μg/ml. Once generated, the bioactive peptides were resistant to further degradation by proteinase of L. helveticus PR4 or by trypsin and chymotrypsin.     

Specificity of a cell-envelope-located proteinase (PIII-type) from Lactococcus lactis subsp. cremoris AM1 in its action on bovine β-casein

Summary The action of the cell-envelope proteinase (P_III-type) from Lactococcus lactis ssp. cremoris AM₁ on bovine -casein was studied. The results were compared with those obtained earlier with (P_I-type) proteinases from the cell envelope of other L. lactis strains. From a 4-h digest (pH 6.2; 15°C) of -casein made with the P_III-type proteinase, 24 peptides were isolated and purified by selective precipitation followed by semi-preparative reversed-phase HPLC. Altogether, these peptides accounted for the preferential splitting of 16 peptide bonds in -casein by the P_III-type proteinase. In nine cases the primary cleavage site (P₁-P₁) was a Glx-X or X-Glx peptide bond. In ten cases at least one large hydrophobic residue (Met, Leu, Tyr, Phe) formed part of the cleavable bond. The P₂-P₃ and/or P₂-P₃ regions of the substrate consisted of hydrophobic and/or negatively charged side chains or of side chains potentially involved in hydrogen bonds. Nine of the peptide bonds split were reported previously to be also susceptible to cleavage by P_I-type proteinases, although the kinetics may be different. The P_III-type proteinase shows a broader specificity in its initial cleavage of -casein than does the P_I-type. Offprint requests to: S. Visser     

Specificity of Lactococcus lactis subsp. cremoris SK11 Proteinase, Lactocepin III, in Low-Water-Activity, High-Salt-Concentration Humectant Systems and Its Stability Compared with That of Lactocepin I

Marked changes in the specificity of hydrolysis of α_s1-, β-, and κ-caseins by lactocepin III from Lactococcus lactis subsp. cremoris SK11 were found in humectant systems giving the equivalent water activity (a_w) and salt concentration of cheddar cheese. Correlations were noted between certain peptides produced by the activity of lactocepin III in the humectant systems and peptides found in cheddar cheese. The stability of lactocepin III was compared with that of lactocepin I from L. lactis subsp. cremoris HP in the humectant systems at different pHs. Significant differences between the stability of each of the lactocepin types were evident. The relationship between stability and humectant type, a_w, pH, and NaCl concentration was complex. Nevertheless, in those systems where a_w, pH, and NaCl concentration were equivalent to those in cheddar cheese, lactocepin I was generally more stable than lactocepin III. It was concluded that differences in the specificity and/or stability of various lactocepin types are likely to persist in cheese itself and therefore potentially contribute to differences in the peptide composition of ripened cheese.