Specificity of hydrolysis of bovine kappa-casein by cell envelope-associated proteinases from Lactococcus lactis strains.

The cell envelope-associated proteinases from Lactococcus lactis subsp. cremoris H2 (a PI-type proteinase-producing strain) and SK11 (a PIII-type proteinase-producing strain) both actively hydrolyze the kappa-casein component of bovine milk but with significant differences in the specificity of peptide bond hydrolysis. The peptide bonds Ala-23-Lys-24, Leu-32-Ser-33, Ala-71-Gln-72, Leu-79-Ser-80, Met-95-Ala-96, and Met-106-Ala-107 were cleaved by both proteinase types, although the relative rates of hydrolysis at some of these sites were quite different for the two proteinases. Small histidine-rich peptides were formed as early products of the action of the cell envelope-associated proteinases on kappa-casein, implicating this casein as a possible significant source of histidine, which is essential for starter growth. The major difference between the two proteinase types in their action on kappa-casein was in their ability to cleave bonds near the C-terminal end of the molecule. The bond Asn-160-Thr-161 and, to a lesser extent, the bond Glu-151-Val-152 were very rapidly cleaved by the PIII-type proteinase, whereas hydrolysis of these bonds by the PI-type proteinase was barely detectable (even after 24 h of digestion). Differential hydrolysis of kappa-casein at these sites by the two different proteinase types resulted in the formation of distinctive, high-M(r) products detectable by sodium dodecyl sulfate-polyacrylamide gel electrophoresis.(ABSTRACT TRUNCATED AT 250 WORDS)     

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 cell envelope-associated proteinases of thermophilic lactobacilli

The proteolytic activities of two natural isolates of thermophilic lactobacilli, Lactobacillus acidophilus BGRA43 and Lact. delbrueckii BGPF1, and Lact. acidophilus CH2 (Chr. Hansen's strain) and Lact. acidophilus V74 (Visby's strain), were compared. Results revealed that optimal pH for all four proteinases is 6.5, whereas temperature optimum varied among proteinases. Determination of caseinolytic activity done under optimal conditions for each strain revealed that the CH2 and V74 proteinases completely hydrolysed both alphaS1-casein and beta-casein, showing very low activity towards kappa-casein. The BGPF1 proteinase completely hydrolysed only beta-casein. The BGRA43 proteinase completely hydrolysed all three casein fractions. The proteolytic activities of whole cells were inhibited by serine proteinase inhibitors, suggesting that all four strains produce serine proteinases. DNA-DNA hybridization and PCR analysis showed that BGPF1 contains the prtB-like proteinase gene. Characterized thermophilic strains BGPF1 and BGRA43 were successfully used as starter cultures for production of yoghurt and acidophilus milk, respectively.     

Substrate specificity of the cell envelope-located proteinase of Lactococcus lactis subsp. lactis NCDO 763.

1. The specificity of the cell envelope-located proteinase of Lactococcus lactis subsp. lactis NCDO 763 towards caseins has been submitted to a statistical study. Positive and negative relations have been evidenced between several amino acids and positions P6 to P'2 of the cleaved bonds. 2. Fragment 1-23 of alpha s1 and oxidized B chain of insulin are well cleaved by the proteinase while CMP (fragment 106-169 of kappa-casein) is a poor substrate. 3. Comparison with other cell envelope-located proteinase has been done. The enzyme of the strain 763 hydrolyses alpha s1-casein and fragment 1-23 of alpha s1-casein as the enzyme of the strain Sk11 and beta-casein as the enzyme of the strain Wg2. 4. The specificity of these proteinases and the comparison of their amino acid sequences let us postulate a more complex substrate binding area for these lactococcal proteinases than for the subtilisin.     

Altered specificity of lactococcal proteinase p(i) (lactocepin I) in humectant systems reflecting the water activity and salt content of cheddar cheese

By using various humectant systems, the specificity of hydrolysis of alpha(s1)-, beta-, and kappa-caseins by the cell envelope-associated proteinase (lactocepin; EC 3.4.21.96) with type P(1) specificity (i.e., lactocepin I) from Lactococcus lactis subsp. lactis BN1 was investigated at water activities (a(w)) and salt concentrations reflecting those in cheddar type cheese. In the presence of polyethylene glycol 20000 (PEG 20000)-NaCl (a(w) = 0.95), hydrolysis of beta-casein resulted in production of the peptides comprising residues 1 to 6 and 47 to 52, which are characteristic of type P(III) enzyme activity (lactocepin III) in buffer. The fragment comprising residues 1 through 166, inclusive (fragment 1-166), which is typical of lactocepin I activity in buffer systems, was not produced. Similarly, peptide 152-160 from kappa-casein, which is usually produced in aqueous buffers exclusively by lactocepin III, was a major product of lactocepin I. Most of the specificity differences obtained in the presence of PEG 20000-NaCl were also obtained in the presence of PEG 20000 alone (a(w) = 0.99). In addition, alpha(s1)-casein, which normally is resistant to lactocepin I activity, was rapidly hydrolyzed in the presence of PEG 20000 alone. Hydrolysis of casein in the presence of PEG 300-NaCl or glycerol-NaCl (both having an a(w) of 0.95) was generally as expected for lactocepin I activity except that beta-casein peptide 47-52 and kappa-casein fragment 1-160 were produced; both of these are normally formed by lactocepin III in buffer. The differences in lactocepin specificity obtained in the humectant systems can be attributed to a combination of a(w) and humectant hydrophobicity, both of which are parameters that are potentially relevant to the cheese-ripening environment.     

Discrimination of distinct proteinases at the four structural levels of rat liver mitochondria.

Rat liver mitochondrial fractions corresponding to four morphological structures (matrix, inner membrane, intermembrane space and outer membrane) contain proteinases that cleave casein components at different rates. Proteinases of the intermembrane space preferentially cleave kappa-casein, whereas the proteinases of the outer membrane, inner membrane and matrix fractions degrade alpha S1-casein more rapidly. Electrophoretic separation of the degradation products of alpha S1-casein and kappa-casein in polyacrylamide gels shows that different polypeptides are produced when the substrate is degraded by the matrix, by both membranes and by the intermembrane-space fraction. Some of the degradation products resulting from incubation of the caseins with the mitochondrial fractions are probably the result of digestion by contaminating lysosomal proteinase(s). The matrix has a high peptidase activity, since glucagon, a small peptide, is very rapidly degraded by this fraction. These observations strongly suggest that distinct proteinases, with different specificities, are associated respectively with the intermembrane space and with both membrane fractions.     

Isolation and properties of human kappa-casein

Human kappa-casein was isolated from human whole casein by gel filtration with Sephadex G-200 and hydroxylapatite chromatography in the presence of sodium dodecyl sulfate (SDS). The kappa-casein was calcium-insensitive and did stabilize human beta-casein and bovine alpha s1-casein against precipitation by calcium ions. Formation of micelles from human beta- and kappa-caseins, and calcium ions was confirmed by electron microscopic observation. On SDS-polyacrylamide gel electrophoresis (SDS-PAGE), a single band was obtained. The formation of para-kappa-caseins by chymosin was confirmed by SDS-PAGE. Two para-kappa-caseins with apparent molecular weights of 13,000 and 11,000 appeared. The molecular weight of intact human kappa-casein was estimated to be approximately 33,000. The human kappa-casein contained about 40% carbohydrate (15% galactose, 3% fucose, 15% hexosamines, and 5% sialic acid) and 0.10% (1 mol/mol) phosphorus. Its amino acid composition was similar to that of bovine kappa-casein except for serine, glutamic acid, and lysine contents.     

Cloning and expression of the Lactococcus lactis subsp. cremoris SK11 gene encoding an extracellular serine proteinase

The Lactococcus lactis subsp. cremoris SK11 plasmid-located prtP gene, encoding a cell-envelope-located proteinase (PrtP) that degrades alpha s1-, beta- and kappa-casein, was identified in a lambda EMBL3 gene library in Escherichia coli using immunological methods. The complete prtP gene could not be cloned in E. coli and L. lactis on high-copy-number plasmid vectors. However, using a low-copy-number vector, the complete prtP gene could be cloned in strains MG1363 and SK1128, proteinase-deficient derivatives of L. lactis subsp. lactis 712 and L. lactis subsp. cremoris SK11, respectively. The proteinase deficiency of these hosts was complemented to wild-type (wt) levels by the cloned SK11 prtP gene. The caseinolytic specificity of the proteinase specified by the cloned prtP gene was identical to that encoded by the wt proteinase plasmid, pSK111. The expression of recombinant plasmids containing 3' and 5' deletions of prtP was analyzed with specific attention directed towards the location of the gene products. In this way the expression signals of prtP were localized and overproduction was obtained in L. lactis subsp. lactis. Furthermore, a region at the C terminus of PrtP was identified which is involved in cell-envelope attachment in lactococci. A deletion derivative of prtP was constructed which specifies a C-terminally truncated proteinase that is well expressed and fully secreted into the medium, and still shows the same capacity to degrade alpha s1-, beta- and kappa-casein.     

Purification and characterization of extracellular proteinases excreted by a strain of Bacillus subtilis BS2, isolated from fermented African locust bean 'iru'

Proteinases were excreted by strains of Bacillus subtilis during fermentation of African locust bean cotyledons. Those excreted by one strain were purified and characterized by ammonium sulphate precipitation, ion-exchange chromatography (IEC), gel filtration, inhibition tests and polyacrylamide gel electrophoresis (PAGE). Three proteinases and an esterase without proteolytic activity were identified. A serine proteinase which showed a high degree of hydrophobicity and a neutral proteinase were present. The third proteinase showed both proteolytic and esterolytic activities, and had multiple electrophoretic mobilities on polyacrylamide gel.     

Resolution and characterisation of multiple isoforms of bovine kappa-casein by 2-DE following a reversible cysteine-tagging enrichment strategy

Visualisation of multiple isoforms of kappa-casein on 2-D gels is restricted by the abundant alpha- and beta-caseins that not only limit gel loading but also migrate to similar regions as the more acidic kappa-casein isoforms. To overcome this problem, we took advantage of the absence of cysteine residues in alpha(S1)- and beta-casein by devising an affinity enrichment procedure based on reversible biotinylation of cysteine residues. Affinity capture of cysteine-containing proteins on avidin allowed the removal of the vast majority of alpha(S1)- and beta-casein, and on subsequent 2-D gel analysis 16 gel spots were identified as kappa-casein by PMF. Further analysis of the C-terminal tryptic peptide along with structural predictions based on mobility on the 2-D gel allowed us to assign identities to each spot in terms of genetic variant (A or B), phosphorylation status (1, 2 or 3) and glycosylation status (from 0 to 6). Eight isoforms of the A and B variants with the same PTMs were observed. When the casein fraction of milk from a single cow, homozygous for the B variant of kappa-casein, was used as the starting material, 17 isoforms from 13 gel spots were characterised. Analysis of isoforms of low abundance proved challenging due to the low amount of material that could be extracted from the gels as well as the lability of the PTMs during MS analysis. However, we were able to identify a previously unrecognised site, T(166), that could be phosphorylated or glycosylated. Despite many decades of analysis of milk proteins, the reasons for this high level of heterogeneity are still not clear.     

Identification of P-57, a serine proteinase, from human erythrocyte membranes, which cleaves both chains of human third component (C3) of complement

A proteinase, which cleaves human third component of complement, was solubilized from erythrocyte membranes then purified by gel filtration chromatography, fluid phase electrophoresis, and hydroxylapatite chromatography. Labeling of the purified material by 125I or 3H-DFP and measurement of proteolytic activity subsequently isolated by SDS-polyacrylamide gel electrophoresis allowed to identify a 57 kDa single band, in non reducing conditions. Inhibition of this activity by PMSF supports covalent modification of an active serine residue. This membrane serine proteinase cleaved alpha and beta chains of human third component of complement, suggesting that p-57 is distinct from plasma serine proteinases.     

Mechanism of action of inter-alpha-trypsin inhibitor

Inter-alpha-trypsin inhibitor (I alpha I) is a unique proteinase inhibitor that can be proteolyzed by the same enzymes that are inhibited, to generate smaller inhibitors. This study examines the reactions of I alpha I with trypsin, chymotrypsin, plasmin, and leukocyte elastase. Complexes of I alpha I and proteinase were demonstrated by gel filtration chromatography. Complete digestion of I alpha I by each proteinase was not accompanied by a comparable loss of inhibition of that enzyme or a different enzyme. Following proteolysis, inhibitory activity was identified in I alpha I fragments of molecular weight 50,000-100,000 and less than 40,000. Addition of a second proteinase inhibitor prevented proteolysis. Both I alpha I and its complex with proteinase were susceptible to degradation. Kinetic parameters for both the inhibition and proteolysis reactions of I alpha I with four proteinases were measured under physiological conditions. On the basis of these results, a model for the mechanism of action of I alpha I is proposed: Proteinase can react with either of two independent sites on I alpha I to form an inhibitory complex or a complex that leads to proteolysis. Both reactions occur simultaneously, but the inhibitory capacity of I alpha I is not significantly affected by proteolysis since the product of proteolysis is also an inhibitor. For a given proteinase, the inhibition equilibrium constant and the Michaelis constant for proteolysis describe the relative stability of the inhibition and proteolysis complexes; the second-order rate constants for inhibition and proteolysis indicate the likelihood of either reaction. The incidence of inhibition or proteolysis reactions involving I alpha I in vivo cannot be assessed without knowledge of the exact concentrations of inhibitor and proteinases; however, analysis of inhibition rate constants suggests that I alpha I might be involved in plasmin inhibition.     

Interaction of alpha 2-macroglobulin with trypsin, chymotrypsin, plasmin, and papain

The interaction alpha 2-macroglobulin with four proteinases has been investigated by binding assays and by gel electrophoresis. At pH 7.65 the binding ratios of the proteinase-alpha 2-macroglobulin complexes were found to be 2:1 (trypsin and papain), 1.4:1 (chymotrypsin), and 1:1 (plasmin). The progressive decrease in the stoichiometry of the three seryl proteinase complexes was paralleled by a concomitant decrease in the proteinase-dependent specific cleavage of the alpha 2-macroglobulin peptide chains. Rate studies have shown that the relative rates of reaction of the proteinases with alpha 2-macroglobulin also varied greatly: papain greater than trypsin greater than chymotrypsin greater than plasmin. The data suggest that the ability of a proteinase to saturate the second proteinase binding site is a reflection of its ability to bind to alpha 2-macroglobulin and cleave the second pair of scissile alpha 2-macroglobulin peptide bonds before the alpha 2-macroglobulin has undergone the conformational change initiated by the formation of the 1:1 proteinase alpha 2-macroglobulin complex.     

Characterization of certain proteinase isoenzymes produced by benign and virulent strains of Bacteroides nodosus

Three proteinase isoenzymes from one benign strain of Bacteroides nodosus and five proteinase isoenzymes from each of two virulent strains of B. nodosus were purified by horizontal slab polyacrylamide gel electrophoresis. The purified isoenzymes hydrolysed casein, collagen I, collagen III, elastin, alpha-elastin, fibrinogen, gelatin, haemoglobin and alpha-keratin. The pH optima of all the isoenzymes lay between 7.25 and 9.5, the range of 8.75-9.25 being common to all. The isoenzymes were inhibited by phenylmethylsulphonyl fluoride, diphenylcarbamyl chloride, L-(1-tosylamide-2-phenyl)ethyl chloromethyl ketone, EGTA and EDTA, indicating that they were chymotrypsin-like serine proteinases that require a metal ion for stability or activity. EDTA inhibition was not reversed by addition of Ca2+ or Mg2+. Some isoenzymes were activated by Mg2+, Ca2+, Cr3+ and Se4+ and all were inhibited by Fe2+, Co2+, Cu2+, Zn2+, Cd2+ and Hg2+. Isoenzymes from benign strains had a lower temperature stability, losing all activity at 55 degrees C, whereas those from virulent strains lost all activity at 60 degrees C.     

Engineering of the Lactococcus lactis serine proteinase by construction of hybrid enzymes

Plasmids containing wild-type and hybrid proteinase genes were constructed from DNA fragments of the prtP genes of Lactococcus lactis strains Wg2 and SK11. These plasmids were introduced into the plasmid-free strain L. lactis MG1363. The serine proteinases produced by these L. lactis strains were isolated, and their cleavage specificity and rate towards alpha s1- and beta-casein was investigated. The catalytic properties of both the SK11 and Wg2 proteinases, which differ in 44 out of 1902 amino acid residues, could be changed dramatically by the reciprocal exchange of specific fragments between the two enzymes. As a result, various L. lactis strains were constructed having new proteolytic properties that differ from those of the parental strains. Furthermore, two segments in the proteinase could be identified that contribute significantly to the cleavage specificity towards casein; within these two segments, several amino acid residues were identified that are important for substrate cleavage rate and specificity. The results also indicate that the lactococcal proteinase has an additional domain involved in substrate binding compared with the related subtilisins. This suggests that the 200 kd L. lactis proteinase may be the representative of a new subclass of subtilisin-like enzymes.     

Comparative study on cell envelope-associated proteinases in natural isolates of mesophilic lactobacilli

Lactobacilli isolated from different natural sources were screened for the presence of cell envelope-associated proteinases (Prt⁺ strains). Among them 17 of 75 tested isolates were Prt⁺. All Prt⁺ strains were producers of a serine-type proteinase, since their proteolytic activity was inhibited by phenylmethylsulfonyl fluoride. Most of the natural isolates of mesophilic lactobacilli degraded only β-casein such as Lactobacillus paracasei subsp. paracasei strains BGLI17 and BGLI18 and Lact. rhamnosus BGEN1. Only Lact. divergens BG742 cleaved all three, α-, β- and κ-caseins, even in the presence of Ca²⁺ ions. Total DNA isolated from Lact. paracasei subsp. paracasei strains BGLI17 and BGLI18 hybridized to the lactococcal proteinase gene probes originated from Lactococcus lactis subsp. cremoris Wg2. Hybridization could not be linked to the plasmid DNA, and pulse-field gel electrophoresis analysis suggested that the proteinase genes of these two strains are most probably chromosomally located.     

Characterization of proteinases from Antarctic krill (Euphausia superba)

Fractions of three trypsin-like proteinases, TL I, TL II, and TL III, a chymotrypsin-like proteinase, CL, two carboxypeptidase A enzymes, CPA I and CPA II and two carboxypeptidase B enzymes, CPB I and CPB II, from Antarctic krill (Euphausia superba) have been characterized with respect to purity by the means of capillary electrophoresis, CE, and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS). The masses of the trypsin-like and chymotrypsin-like proteinases were determined to be 25,020, 25,070, 25,060, and 26,260Da for TL I, TL II, TL III, and CL, respectively. The masses of the CPA enzymes are likely 23,170 and 23,260Da, whereas the CPB enzyme masses likely are 33,730 and 33,900Da. The degradation efficiency and cleavage pattern of the trypsin-like proteinases were studied with native myoglobin as a model substrate using CE, MALDI-TOF-MS, and nanoelectrospray mass spectrometry (nESI-MS). The degradation efficiency of the trypsin-like proteinases was found to be approximately 12 and 60 times higher compared to bovine trypsin at 37 degrees C and 1-3 degrees C, respectively. All three fractions of trypsin-like proteinases showed a carboxypeptidase activity in combination with their trypsin activity.     

Inactivation of human plasma alpha 1-antichymotrypsin by microbial proteinases

Incubation of human plasma alpha 1-antichymotrypsin with proteinases from various microbial sources resulted in the enzymatic inactivation of the inhibitor as determined by loss of inhibitory activity against alpha-chymotrypsin. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the reaction products indicated that intact alpha 1-antichymotrypsin (Mr 67000) had been converted to an inactive form (63000) by limited proteolysis. No stable proteinase/inhibitor complexes were detected, and no random proteolysis of the inactivated inhibitor occurred even after prolonged incubation with the proteinases. Metallo- and serine proteinases from several microbial sources all readily inactivated alpha 1-antichymotrypsin. Since alpha 1-antichymotrypsin is also an early stage acute phase reactant, its inactivation may be important in disrupting bodily defense mechanisms.