Conversion of Lactococcus lactis cell envelope proteinase specificity by partial allele exchange

AIMS: To determine whether conversion of lactocepin substrate binding regions by gene replacement can alter lactocepin specificity in Lactococcus lactis starter bacteria without affecting other important strain properties. METHODS AND RESULTS: We utilized two-step gene replacement to convert substrate-binding determinants in the L. lactis prtP genes encoding group h (bitter) lactocepin in two industrial strains into the corresponding group b (nonbitter) variant. Analysis of lactocepin activity toward alpha(s1)-casein (f 1-23) by reversed-phase high-pressure liquid chromatography demonstrated enzyme specificity among isogenic derivatives had been altered in a manner that was consistent with predicted amino acid substitutions in substrate binding regions. Milk acidification properties of some mutants were not statistically different (P > 0.05) from wild-type parent strains, and strain propensity for autolysis was also not significantly (P > 0.05) changed. CONCLUSIONS: Conversion of lactocepin substrate binding regions by allele exchange can effectively alter lactocepin specificity in industrial strains of L. lactis without significantly affecting other important strain properties. SIGNIFICANCE AND IMPACT OF THE STUDY: Methodology outlined in this study can be used to alter lactocepin specificity in commercial starter cultures with a propensity for bitter flavour defect, and prtP derivatives developed by this approach should be suitable for commercial application.     

Role of calcium in activity and stability of the Lactococcus lactis cell envelope proteinase

The mature lactococcal cell envelope proteinase (CEP) consists of an N-terminal subtilisin-like proteinase domain and a large C-terminal extension of unknown function whose far end anchors the molecule in the cell envelope. Different types of CEP can be distinguished on the basis of specificity and amino acid sequence. Removal of weakly bound Ca2+ from the native cell-bound CEP of Lactococcus lactis SK11 (type III specificity) is coupled with a significant reversible decrease in specific activity and a dramatic reversible reduction in thermal stability, as a result of which no activity at 25 degrees C (pH 6.5) can be measured. The consequences of Ca2+ removal are less dramatic for the CEP of strain Wg2 (mixed type I-type III specificity). Autoproteolytic release of CEP from cells concerns this so-called "Ca-free" form only and occurs most efficiently in the case of the Wg2 CEP. The results of a study of the relationship between the Ca2+ concentration and the stability and activity of the cell-bound SK11 CEP at 25 degrees C suggested that binding of at least two Ca2+ ions occurred. Similar studies performed with hybrid CEPs constructed from SK11 and Wg2 wild-type CEPs revealed that the C-terminal extension plays a determinative role with respect to the ultimate distinct Ca2+ dependence of the cell-bound CEP. The results are discussed in terms of predicted Ca2+ binding sites in the subtilisin-like proteinase domain and Ca-triggered structural rearrangements that influence both the conformational stability of the enzyme and the effectiveness of the catalytic site. We argue that distinctive primary folding of the proteinase domain is guided and maintained by the large C-terminal extension.     

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.     

Nucleotide sequence and characterization of the cell envelope proteinase plasmid in Lactococcus lactis subsp. cremoris HP

AIMS: The major cell envelope proteinase (lactocepin; EC 3.4.21.96) produced by Lactococcus lactis cheese starter bacteria is required for starter growth and acid production in milk. The aim of this study was to characterize a lactocepin plasmid from a L. lactis subsp. cremoris cheese starter strain. METHODS AND RESULTS: A restriction map of the lactocepin plasmid pHP003 from strain HP was constructed, fragments were cloned in Escherichia coli vectors, and the complete DNA sequence (13,433 bp) was determined. Among 120 industrial L. lactis starter strains screened, five contained the same specificity-type lactocepin as pHP003. The lactocepin gene in these strains was invariably linked with a partially-deleted abiB gene. CONCLUSION: The lactocepin specificity type of strain HP, conferred by a known configuration of key residues, is relatively uncommon. The gene is invariably linked with a partially deleted abiB gene on each lactocepin plasmid. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first complete sequence reported for a lactocepin plasmid, and provides the basis for better understanding, or manipulation, of lactocepin production.     

Contribution of Lactococcus lactis Cell Envelope Proteinase Specificity to Peptide Accumulation and Bitterness in Reduced-Fat Cheddar Cheese

Bitterness is a flavor defect in Cheddar cheese that limits consumer acceptance, and specificity of the Lactococcus lactis extracellular proteinase (lactocepin) is widely believed to be a key factor in the development of bitter cheese. To better define the contribution of this enzyme to bitterness, we investigated peptide accumulation and bitterness in 50% reduced-fat Cheddar cheese manufactured with single isogenic strains of Lactococcus lactis as the only starter. Four isogens were developed for the study; one was lactocepin negative, and the others produced a lactocepin with group a, e, or h specificity. Analysis of cheese aqueous extracts by reversed-phase high-pressure liquid chromatography confirmed that accumulation of α_S1-casein (f 1-23)-derived peptides f 1-9, f 1-13, f 1-16, and f 1-17 in cheese was directly influenced by lactocepin specificity. Trained sensory panelists demonstrated that Cheddar cheese made with isogenic starters that produced group a, e, or h lactocepin was significantly more bitter than cheese made with a proteinase-negative isogen and that propensity for bitterness was highest in cells that produced group h lactocepin. These results confirm the role of starter proteinase in bitterness and suggest that the propensity of some industrial strains for production of the bitter flavor defect in cheese could be altered by proteinase gene exchange or gene replacement.     

Regulation of proteinase synthesis in Lactococcus lactis

The synthesis of extracellular serine proteinase of Lactococcus lactis was studied during the growth in a batch and a continuous culture on chemically defined media. In a batch culture the proteinase synthesis started during the exponential phase of growth and the highest proteinase concentrations were found at the end of the exponential and beginning of the stationary phase of growth. During the growth in a lactose-limited chemostat with amino acids as the sole source of nitrogen, the specific rate of proteinase synthesis was maximal at a μof 0.23 h^?1. At higher growth rates the proteinase productin declined. The proteinase synthesis was dependent on the amino acid sources in the medium. In batch cultures of L. lactis grown on a chemically defined medium with amino acids, the proteinase production was increased four-fold compared to media containing casein or a tryptic digest of casein as the sole source of nitrogen. The inhibition of the rate of proteinase synthesis by casein and peptides was also observed during the growth in a chemostat. The addition of the dipeptide leucylproline (final concentration of 100 μM) to a lactose-limited continuous culture during the steady state (D = 0.23 h^?1) resulted in a transient inhibition of the rate of proteinase synthesis. This suggested that exogenously supplied peptides control the regulation of proteinase synthesis of L. lactis.     

Kinetics and substrate specificity of membrane-reconstituted peptide transporter DtpT of Lactococcus lactis

The peptide transport protein DtpT of Lactococcus lactis was purified and reconstituted into detergent-destabilized liposomes. The kinetics and substrate specificity of the transporter in the proteoliposomal system were determined, using Pro-[(14)C]Ala as a reporter peptide in the presence of various peptides or peptide mimetics. The DtpT protein appears to be specific for di- and tripeptides, with the highest affinities for peptides with at least one hydrophobic residue. The effect of the hydrophobicity, size, or charge of the amino acid was different for the amino- and carboxyl-terminal positions of dipeptides. Free amino acids, omega-amino fatty acid compounds, or peptides with more than three amino acid residues do not interact with DtpT. For high-affinity interaction with DtpT, the peptides need to have free amino and carboxyl termini, amino acids in the L configuration, and trans-peptide bonds. Comparison of the specificity of DtpT with that of the eukaryotic homologues PepT(1) and PepT(2) shows that the bacterial transporter is more restrictive in its substrate recognition.     

The occurrence of two intracellular oligoendopeptidases in Lactococcus lactis and their significance for peptide conversion in cheese

Two intracellular oligopeptide-preferring endopeptidases have been detected in Lactococcus lactis. A neutral thermolysin-like oligoendopeptidase (NOP) has been purified to homogeneity and an alkaline oligoendopeptidase has been partially purified. The specificity of the oligoendopeptidases towards important intermediary cheese peptides, produced by chymosin action on the caseins, clearly differs from that of the cell-envelope proteinase (CEP). NOP is active under conditions prevailing in cheese and contributes to initial proteolysis in a young cheese. It probably plays a crucial role in the degradation of an important bitter peptide in cheese, the -casein 193–209 fragment. The relatively low activity of the alkaline endopeptidase is further suppressed in cheese by the highly competitive actions of NOP and CEP.     

Chromosomal stabilization of the proteinase genes in Lactococcus lactis.

The plasmid-encoded proteinase genes prtP and prtM of Lactococcus lactis subsp. cremoris Wg2 were integrated by a Campbell-like mechanism into the L. lactis subsp. lactis MG1363 chromosome by using the insertion vector pKLG610. Two transformants were obtained that differed in the number of amplified pKLG610 copies in head-to-tail arrangements on their chromosomes; MG610 contained approximately two copies, and MG611 contained about eight copies. The amplifications were stably maintained during growth in milk in the absence of antibiotics. The proteolytic activity of strain MG611 was approximately 11-fold higher than that of strain MG610 and about 1.5 times higher than that of strain MG1363(pGKV552), which carried the proteinase genes on an autonomously replicating plasmid with a copy number of approximately 5. All three strains showed rapid growth in milk with concomitant rapid production of acid. The results suggest that a limited number of copies of the proteinase genes prtP and prtM per genome is sufficient for good growth in milk.     

Chromosomal stabilization of the proteinase genes in Lactococcus lactis.

The plasmid-encoded proteinase genes prtP and prtM of Lactococcus lactis subsp. cremoris Wg2 were integrated by a Campbell-like mechanism into the L. lactis subsp. lactis MG1363 chromosome by using the insertion vector pKLG610. Two transformants were obtained that differed in the number of amplified pKLG610 copies in head-to-tail arrangements on their chromosomes; MG610 contained approximately two copies, and MG611 contained about eight copies. The amplifications were stably maintained during growth in milk in the absence of antibiotics. The proteolytic activity of strain MG611 was approximately 11-fold higher than that of strain MG610 and about 1.5 times higher than that of strain MG1363(pGKV552), which carried the proteinase genes on an autonomously replicating plasmid with a copy number of approximately 5. All three strains showed rapid growth in milk with concomitant rapid production of acid. The results suggest that a limited number of copies of the proteinase genes prtP and prtM per genome is sufficient for good growth in milk.     

Hydrophilic and hydrophobic peptides produced in cheese by wild Lactococcus lactis strains

AIMS: To study the production of hydrophilic and hydrophobic peptides in cheese by 32 wild Lactococcus lactis strains of different RAPD patterns and to compare them with the peptides produced by lactococcal cells incubated with whole casein. METHOD AND RESULTS: Chromatograms of peptides from cheeses made using each strain as single starter culture were divided into five regions, and strains were classified in three groups by hierarchical cluster analysis of region areas. Thirty out of the 32 wild L. lactis strains produced higher levels of hydrophobic peptides in cheese than on whole casein. CONCLUSIONS: Cheese was a more favourable substrate than whole casein for hydrophobic peptide formation by L. lactis strains. SIGNIFICANCE AND IMPACT OF THE STUDY: New strains of lactococci should be screened for bitterness under cheese conditions, as the formation of hydrophobic peptides may be underestimated in assays with casein as substrate.     

Structural changes and interactions involved in the Ca(2+)-triggered stabilization of the cell-bound cell envelope proteinase in Lactococcus lactis subsp. cremoris SK11

The cell-bound cell envelope proteinase (CEP) of the mesophilic cheese-starter organism Lactococcus lactis subsp. cremoris SK11 is protected from rapid thermal inactivation at 25 degrees C by calcium bound to weak binding sites. The interactions with calcium are believed to trigger reversible structural rearrangements which are coupled with changes in specific activity (F. A. Exterkate and A. C. Alting, Appl. Env. Microbiol. 65:1390-1396, 1999). In order to determine the significance of the rearrangements for CEP stability and the nature of the interactions involved, the effects of the net charge present on the enzyme and of different neutral salts were studied with the stable Ca-loaded CEP, the unstable so-called "Ca-free" CEP and with the Ca-free CEP which was stabilized nonspecifically and essentially in its native conformation by the nonionic additive sucrose. The results suggest that strengthening of hydrophobic interactions is conducive to stabilization of the Ca-free CEP. On the other hand, a hydrophobic effect contributes significantly to the stability of the Ca-loaded CEP; a phased salting-in effect by a chaotropic salt suggests a complex inactivation process of this enzyme due to weakening of hydrophobic interactions and involving an intermediate enzyme species. Moreover, a Ca-triggered increase of a relatively significant hydrophobic effect in the sucrose-stabilized Ca-free CEP occurs. It is suggested that in the Ca-free CEP the absence of both local calcium-mediated backbone rigidification and neutralization of negative electrostatic potentials in the weak Ca-binding sites, and in addition the lack of significant hydrophobic stabilization, increase the relative effectiveness of electrostatic repulsive forces on the protein to an extent that causes the observed instability. The conditions in cheese seem to confer stability upon the cell-bound enzyme; its possible involvement in proteolysis throughout the ripening period is discussed.     

Discrepancies between the phenotypic and genotypic characterization of Lactococcus lactis cheese isolates

AIMS: The use of randomly amplified polymorphic DNA (RAPD)-PCR fingerprinting and plasmid profiles to determine at the strain level, the similarity of Lactococcus lactis isolates obtained during sampling of traditional cheeses and to verify its correspondence to the selected phenotypic characteristics. METHODS AND RESULTS: A total of 45 L. lactis isolates were genotypically analysed by RAPD-PCR fingerprinting and plasmid patterns. Phenotypic traits used to compare strains were proteolytic, acidifying, aminotransferase (aromatic and branched chain aminotransferase) and alpha-ketoisovalerate decarboxylase (Kivd) activities. The results show that 23 isolates could be grouped in clusters that exhibited 100% identity in both their RAPD and plasmid patterns, indicating the probable isolation of dominant strains during the cheese sampling process. However, there were phenotypic differences between isolates within the same cluster that included the loss of relevant technological properties such as proteinase activity and acidifying capacity or high variation in their amino acid converting enzyme activities. Likewise, the analysis of a specific attribute, Kivd activity, indicated that 7 of 15 isolates showed no detectable activity despite the presence of the encoding (kivd) gene. CONCLUSION: Phenotypic differences found between genotypically similar strains of L. lactis strains could be linked to differences in enzymatic expression. SIGNIFICANCE AND IMPACT OF THE STUDY: Phenotypic analysis of L. lactis isolates should be considered when selecting strains with new cheese flavour forming capabilities.     

Kinetic mechanism and specificity of the arginine-ornithine antiporter of Lactococcus lactis

The kinetic mechanism and specificity of the arginine-ornithine antiporter was investigated in membrane vesicles derived from Lactococcus lactis. Membrane vesicles loaded with ornithine, and diluted into an arginine-free medium, rapidly released a limited amount of ornithine during the first seconds of incubation. The amount of ornithine released was independent of the amount initially present on the inside and roughly matched the number of ornithine-binding sites in the membrane. Net flow of ornithine was only observed in membrane vesicles derived from induced cells and blocked by p-chloromercuribenzene sulfonic acid. These results suggest that net flow of ornithine is caused by a single turnover of the antiporter. With saturating concentrations of arginine in the external medium, efflux of ornithine was stoichiometrically coupled to uptake of arginine. Arginine-ornithine exchange and net flow of ornithine are electrically silent and not regulated by the electrical potential. The kinetics of the homologous exchange reactions indicate that the Vmax values for arginine and ornithine uptake are comparable, whereas the apparent Kt values differ. No major sidedness of the apparent Kt values are observed for both surfaces of the cytoplasmic membrane. Various basic amino acid analogues, including optical isomers, are transported as well, albeit with different efficiencies (Vmax/Kt). Evidence for a competitive character of arginine and ornithine interactions for binding sites on the antiporter are provided by transport and binding measurements. The Vmax and apparent Kt for arginine uptake increases with increasing internal ornithine, with little effect on the ratio of Vmax to apparent Kt. These results are discussed in terms of a simple carrier model in which the substrate-binding site is presented alternately to the two surfaces of the membrane as in a Ping Pong mechanism for enzyme kinetics.     

A maturation protein is essential for production of active forms of Lactococcus lactis SK11 serine proteinase located in or secreted from the cell envelope.

The complete nucleotide sequence of a gene located immediately upstream of the Lactococcus lactis subsp. cremoris SK11 prtP gene encoding the cell envelope-attached proteinase was determined. This gene, designated prtM, was found to be transcribed from the same promotor region as was the proteinase gene but in the opposite direction. The prtM gene directed the expression in Escherichia coli of a protein with a size similar to the expected value of 33 kilodaltons, as deduced from the nucleotide sequence data. The derived amino acid sequence of the PrtM protein indicated the presence of a consensus lipoprotein signal sequence at the N terminus, which suggested that PrtM is a lipoprotein. Plasmids containing the prtM gene, the prtP gene, or both were constructed. Expression studies of L. lactis clones containing these plasmids showed that the prtM gene encodes a trans-acting activity involved in the maturation of cell envelope-located and -secreted forms of the SK11 proteinase.     

An aminotransferase from Lactococcus lactis initiates conversion of amino acids to cheese flavor compounds.

The enzymatic degradation of amino acids in cheese is believed to generate aroma compounds and therefore to be involved in the complex process of cheese flavor development. In lactococci, transamination is the first step in the degradation of aromatic and branched-chain amino acids which are precursors of aroma compounds. Here, the major aromatic amino acid aminotransferase of a Lactococcus lactis subsp. cremoris strain was purified and characterized. The enzyme transaminates the aromatic amino acids, leucine, and methionine. It uses the ketoacids corresponding to these amino acids and alpha-ketoglutarate as amino group acceptors. In contrast to most bacterial aromatic aminotransferases, it does not act on aspartate and does not use oxaloacetate as second substrate. It is essential for the transformation of aromatic amino acids to flavor compounds. It is a pyridoxal 5'-phosphate-dependent enzyme and is composed of two identical subunits of 43.5 kDa. The activity of the enzyme is optimal between pH 6.5 and 8 and between 35 and 45 degrees C, but it is still active under cheese-ripening conditions.     

Comparison of cell wall proteinases from Lactococcus lactis subsp. cremoris AC1 and Lactococcus lactis subsp. lactis NCDO 763

Summary Cell wall-associated proteinases were isolated from Lactococcus lactis subsp. cremoris AC1 and subsp. lactis NCDO 763 in order to compare their specificities towards different caseins. Two purification strategies were applied. Cells grown in casein-free M17 medium were a suitable starting material for purification, since electrophoretic purity could be achieved after one chromatographic step. Both enzymes has an apparent molecular mass of about 145000 daltons as judged by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Electrophoresis and reversed phase HPLC patterns of hydrolysates of _s1-, _s2-, -, and K-caseins indicated that both proteinases had a similar specificity. The enzyme of L. lactis subsp. lactis split _s1- and _s2-caseins more extensively than that of L. lactis subsp. cremoris.     

Comparison of cell wall proteinases from Lactococcus lactis subsp. cremoris AC1 and Lactococcus lactis subsp. lactis NCDO 763

Summary The cell wall proteinases of Lactococcus lactis subsp. lactis NCDO 763 and L. lactis subsp. cremoris AC1 hydrolyse -casein with a similar specificity even though some quantitative differences can be observed for a few degradation products analysed by reverse phase HPLC and sodium dodecyl sulphate-polyacrylamide gel electrophoresis. The main peptides soluble in 1.1% trifluoroacetic acid and liberated by the two proteinases were identified and have been found to be the same for the two enzymes. They are located in two areas of the -casein sequence (53–93 and the C-terminal part: 129–209) and they include bitter tasting or physiologically active fragments. No narrow specificity was observed for these proteinases. However, glutamine and serine residues are more frequently encountered in position P1 and P1 of the sensitive peptide bond and the close environment (position P2 to P4 and P2 to P4) of the cleaved bond is mainly hydrophobic.     

Cloning and partial sequencing of the proteinase gene complex from Lactococcus lactis subsp. lactis UC317.

The proteinase genes from Lactococcus lactis subsp. lactis UC317 were identified on a plasmid, pCI310, which is a deletion derivative of a cointegrate between pCI301, the 75 kb Lac Prt plasmid from UC317 and the 38.5 kb cryptic plasmid from that strain. The prt genes were cloned using a replacement cloning strategy whereby fragments from pCI310 were exchanged with the equivalent fragments in pNZ521, which contains the cloned proteinase genes from L. lactis subsp. lactis SK112. This generated two plasmids which encoded a cell-envelope-associated and a secreted proteinase, respectively. Specific regions of the UC317 structural prtP gene known to encode seven of the amino acids essential for substrate cleavage specificity were sequenced and compared with the known sequences of prt genes from L. lactis strains SK112, Wg2 and NCDO763. In spite of various differences that were detected in the nucleotide sequence of this region, it appears that these seven amino acids in strains UC317 and NCDO763 are identical, and represent a combination of three of the amino acids from SK112 and four from Wg2. These results indicate that the UC317 proteinase is a natural hybrid of the SK112 and Wg2 proteinases.     

Genotypic and technological characterization of Lactococcus lactis isolates involved in processing of artisanal Manchego cheese

Aims:  Genotypic and technological characterization of wild lactococci isolated from artisanal Manchego cheese during the ripening process for selection of suitable starter cultures.
Methods and Results:  A total of 114 isolates of lactococci were typed using randomly amplified polymorphic DNA-polymerase chain reaction (RAPD-PCR). Sixteen distinct RAPD-PCR patterns, at a similarity level of 73%, were obtained. On the basis of species-specific PCR reaction, the isolates were assigned to the species Lactococcus lactis subsp. lactis and Lactococcus lactis subsp. cremoris with L. lactis subsp. lactis being predominant at both dairies. Twenty-six isolates were technologically characterized to select those with the best properties. Most of them showed good technological properties although some could produce tyramine.
Conclusions:  The presence of coincident genotypes at both dairies has been demonstrated, which would suggest that they are well adapted to the Manchego cheese environment. Interesting differences were found in the technological characterization and the potential role of autochthonous lactococci strains as starter culture has been displayed.
Significance and Impact of the Study:  The great economic importance of Manchego cheese encouraged a deeper knowledge of its microbiota, to select strains with the best properties to use as starter cultures in industrial Manchego cheeses, preserving the autochthonous characteristics.