Monoclonal Antibodies to the Cell-Wall-Associated Proteinase of Lactococcus lactis subsp. cremoris Wg2

Twelve monoclonal antibodies directed to the cell-wall-associated proteinase of Lactococcus lactis subsp. cremoris Wg2 were isolated after immunization of BALB/c mice with a partially purified preparation of the proteinase. The monoclonal antibodies reacted with the 126-kilodalton proteinase band in a Western immunoblot. All but one of the monoclonal antibodies reacted with protein bands with a molecular weight below 126,000, possibly degradation products of the proteinase. The monoclonal antibodies could be divided into six groups according to their different reactions with the proteinase degradation products in the Western blot. Different groups of monoclonal antibodies reacted with different components of the L. lactis subsp. cremoris Wg2 proteinase. Crossed immunoelectrophoresis showed that monoclonal antibody groups I, II, and III react with proteinase component A and that groups IV, V, and VI react with proteinase component B. The isolated monoclonal antibodies cross-reacted with the proteinases of other L. lactis subspecies. Monoclonal antibodies of group IV cross-reacted with proteinase component C of other L. lactis subsp. cremoris strains. The molecular weight of the proteinase attached to the cells of L. lactis subsp. cremoris Wg2 was 200,000, which is different from the previously reported values. This could be analyzed by immunodetection of the proteinase on a Western blot. This value corresponds to the molecular weight calculated from the amino acid sequence of the cloned L. lactis subsp. cremoris Wg2 proteinase gene.     

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.     

Characterization of the Cell Wall-Bound Proteinase of Lactobacillus casei HN14

Lactobacillus casei HN14, which was isolated from homemade cheese, produces an extracellular, cell wall-bound proteinase. The HN14 proteinase can be removed from the cell envelope by washing the cells in a Ca²⁺-free buffer. The activity of the crude proteinase extract is inhibited by phenylmethylsulfonyl fluoride, showing that the enzyme is a serine-type proteinase. Considering the substrate specificity, the HN14 proteinase is similar to the lactococcal PI-type enzyme, since it hydrolyzes β-casein only. Lactobacillus casei HN14 appeared to be plasmid free, which suggests that the proteinase gene is chromosomally located. Chromosomal DNA of this strain hybridizes with DNA probes Q1 (which contains a fragment of the prtM gene) and Q6 and Q92 (which contain fragments of the prtP gene); all three probes originated from the proteinase gene region of Lactococcus lactis subsp. cremoris Wg2. A restriction enzyme map of the proteinase region of Lactobacillus casei HN14 was constructed on the basis of hybridization experiments. Comparison of the restriction enzyme maps of the Lactobacillus casei HN14 proteinase gene region and those of lactococcal proteinase gene regions studied so far indicates that they are highly similar.     

Autoproteolysis of the Extracellular Serine Proteinase of Lactococcus lactis subsp. cremoris Wg2

The molecular masses of purified extracellular serine proteinase of a number of Lactococcus lactis strains vary significantly, and these molecular mass values do not correspond to the values estimated on the basis of genetic data. The discrepancies can only partially be explained by N-terminal processing during maturation of the precursor enzyme and by C-terminal cleaving during the release from the cell envelope. With a monoclonal antibody that binds in the active site region of the L. lactis proteinase, the processing of the released proteinase was followed. At 30°C the proteinase was degraded with a concomitant loss of β-casein hydrolytic activity. In the presence of CaCl₂, proteinase degradation was inhibited, and new degradation products were detected. The specific serine proteinase inhibitors phenylmethylsulfonyl fluoride and diisopropylfluorophosphate also inhibited proteinase degradation. Two major high-molecular-mass proteinase fragments (165 and 90 kDa) were found to have the same N-terminal amino acid sequence as the mature proteinase, i.e., [Asp-1-Ala-2-Lys-3-Ala-4-Asn-5-Ser-6, indicating that both fragments were formed by cleavage at the C terminus. The N terminus of a proteinase fragment with low molecular mass (58 kDa) started with Gln-215. In this fragment part of the active site region was eliminated, suggesting that it is proteolytically inactive. Unlike larger fragments, this 58-kDa fragment remained intact after prolonged incubations. These results indicate that autoproteolysis of the L. lactis subsp. cremoris Wg2 proteinase ultimately leads to inactivation of the proteinase by deletion of the active site region.     

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°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°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.     

Determination of the Domain of the Lactobacillus delbrueckii subsp. bulgaricus Cell Surface Proteinase PrtB Involved in Attachment to the Cell Wall after Heterologous Expression of the prtB Gene in Lactococcus lactis

Belonging to the subtilase family, the cell surface proteinase (CSP) PrtB of Lactobacillus delbrueckii subsp. bulgaricus differs from other CSPs synthesized by lactic acid bacteria. Expression of the prtB gene under its own promoter was shown to complement the proteinase-deficient strain MG1363 (PrtP⁻ PrtM⁻) of Lactococcus lactis subsp. cremoris. Surprisingly, the maturation process of PrtB, unlike that of lactococcal CSP PrtPs, does not require a specific PrtM-like chaperone. The carboxy end of PrtB was previously shown to be different from the consensus anchoring region of other CSPs and exhibits an imperfect duplication of 59 amino acids with a high lysine content. By using a deletion strategy, the removal of the last 99 amino acids, including the degenerated anchoring signal (LPKKT), was found to be sufficient to release a part of the truncated PrtB into the culture medium and led to an increase in PrtB activity. This truncated PrtB is still active and enables L. lactis MG1363 to grow in milk supplemented with glucose. By contrast, deletion of the last 806 amino acids of PrtB led to the secretion of an inactive proteinase. Thus, the utmost carboxy end of PrtB is involved in attachment to the bacterial cell wall. Proteinase PrtB constitutes a powerful tool for cell surface display of heterologous proteins like antigens.     

Cloning and Characterization of the Lactococcal Plasmid-Encoded Type II Restriction/Modification System, LlaDII

The LlaDII restriction/modification (R/M) system was found on the naturally occurring 8.9-kb plasmid pHW393 in Lactococcus lactis subsp. cremoris W39. A 2.4-kb PstI-EcoRI fragment inserted into the Escherichia coli-L. lactis shuttle vector pCI3340 conferred to L. lactis LM2301 and L. lactis SMQ86 resistance against representatives of the three most common lactococcal phage species: 936, P335, and c2. The LlaDII endonuclease was partially purified and found to recognize and cleave the sequence 5′-GC↓NGC-3′, where the arrow indicates the cleavage site. It is thus an isoschizomer of the commercially available restriction endonuclease Fnu4HI. Sequencing of the 2.4-kb PstI-EcoRI fragment revealed two open reading frames arranged tandemly and separated by a 105-bp intergenic region. The endonuclease gene of 543 bp preceded the methylase gene of 954 bp. The deduced amino acid sequence of the LlaDII R/M system showed high homology to that of its only sequenced isoschizomer, Bsp6I from Bacillus sp. strain RFL6, with 41% identity between the endonucleases and 60% identity between the methylases. The genetic organizations of the LlaDII and Bsp6I R/M systems are identical. Both methylases have two recognition sites (5′-GCGGC-3′ and 5′-GCCGC-3′) forming a putative stem-loop structure spanning part of the presumed −35 sequence and part of the intervening region between the −35 and −10 sequences. Alignment of the LlaDII and Bsp6I methylases with other m⁵C methylases showed that the protein primary structures possessed the same organization.     

Involvement of a Plasmid in Production of Ropiness (Mucoidness) in Milk Cultures by Streptococcus cremoris MS

Curing and genetic transfer experiments showed that lactose-fermenting ability (Lac⁺) and the ability to produce mucoidness in milk cultures (Muc⁺) in Streptococcus cremoris MS were coded on plasmids. The Lac⁺ phenotype was associated with a 75.8-megadalton plasmid, pSRQ2201. The Muc⁺ phenotype was associated with a 18.5-megadalton plasmid, pSRQ2202. The Lac plasmid, pSRQ2201, was first conjugatively transferred from S. cremoris MS to Lac⁻S. lactis ML-3/2.2. Later, the Muc plasmid, pSRQ2202, was conjugatively transferred from Lac⁻ Muc⁺S. cremoris MS04 to Lac⁺ nonmucoid S. lactis transconjugant ML-3/2.201. Subsequently, pSRQ2201 and pSRQ2202 were cotransferred from Lac⁺ Muc⁺S. lactis transconjugant ML-3/2.202 to Lac⁻, nonmucoid, malty S. lactis 4/4.2 and S. lactis subsp. diacetylactis SLA3.25. Transconjugants showing pSRQ2201 were Lac⁺; those containing pSRQ2202 were Muc⁺. With the transfer of pSRQ2202, the transconjugants S. lactis ML-3/2.202 and S. lactis subsp. diacetylactis SLA3.2501 not only acquired the Muc⁺ phenotype but also resistance to bacteriophages, which were lytic to the respective parent strains S. lactis ML-3/2.201 and S. lactis subsp. diacetylactis SLA3.25.     

Ultrasound Treatment for Harvesting an Aminopeptidase from Lactic Acid Bacteria and Quantitation of the Enzyme by Enzyme-Linked Immunosorbent Assays

Ultrasound treatment of Lactococcus lactis subsp. cremoris AM2 was optimized to release a maximum amount of intracellular aminopeptidase without modifying the antigenicity of the enzyme. The cells were sonicated three times for 30 s at 23 W. Antibodies produced against the aminopeptidase purified from L. lactis subsp. cremoris AM2 enabled us to use immunoblotting to detect the enzyme in the lysates of all of the lactococci tested but not in the lysates of Leuconostoc strains, lactobacilli, and Streptococcus salivarus subsp. thermophilus. A sandwich enzyme-linked immunosorbent assay (ELISA) was developed to quantify the purified aminopeptidase; the detection limit was 4 ng/ml. The aminopeptidase in the supernatant obtained after the ultrasound treatment of strain AM2 cells was detected with the ELISA starting with a total protein concentration of 200 ng/ml. The proportion of equivalent purified aminopeptidase in the supernatant of L. lactis subsp. cremoris AM2 was about 2% of the total protein. Similarly, the aminopeptidase was quantified in different lactococci; the percentages varied between 0.16 and 2%, depending on the strain. The aminopeptidase content in a mixture of several lactic bacteria was also determined with the sandwich ELISA.     

Resistance against Industrial Bacteriophages Conferred on Lactococci by Plasmid pAJ1106 and Related Plasmids

Plasmid pAJ1106 and its deletion derivative, plasmid pAJ2074, conferred lactose-fermenting ability (Lac) and bacteriophage resistance (Hsp) at 30°C to Lac⁻ proteinase (Prt)-negative Lactococcus lactis subsp. lactis and L. lactis subsp. lactis var. diacetylactis recipient strains. An additional plasmid, pAJ331, isolated from the original source strain of pAJ1106, retained Hsp and conjugative ability without Lac. pAJ331 was conjugally transferred to two L. lactis subsp. lactis and one L. lactis subsp. cremoris starter strains. The transconjugants from such crosses acquired resistance to the phages which propagated on the parent recipient strains. Of 10 transconjugant strains carrying pAJ1106 or one of the related plasmids, 8 remained insensitive to phages through five activity test cycles in which cultures were exposed to a large number of industrial phages at incubation temperatures used in lactic casein manufacture. Three of ten strains remained phage insensitive through five cycles of a cheesemaking activity test in which cultures were exposed to approximately 80 different phages through cheesemaking temperatures. Three phages which propagated on transconjugant strains during cheesemaking activity tests were studied in detail. Two were similar (prolate) in morphology and by DNA homology to phages which were shown to be sensitive to the plasmid-encoded phage resistance mechanism. The third phage was a long-tailed, small isometric phage of a type rarely found in New Zealand cheese wheys. The phage resistance mechanism was partially inactivated in most strains at 37°C.     

Construction of Streptococcus lactis subsp. lactis Strains with a Single Plasmid Associated with Mucoid Phenotype

Lactose-fermenting mucoid (Lac⁺ Muc⁺) variants of plasmid-free Streptococcus lactis subsp. lactis MG1614 were obtained by protoplast transformation with total plasmid DNA from Muc⁺S. lactis subsp. cremoris ARH87. By using plasmid DNA from these variants for further transformations followed by novobiocininduced plasmid curing, Lac⁻ Muc⁺ MG1614 strains containing only a single 30-megadalton plasmid could be constructed. This plasmid, designated pVS5, appeared to be associated with the Muc⁺ phenotype.     

An Ecological Study of Lactococci Isolated from Raw Milk in the Camembert Cheese Registered Designation of Origin Area

The genetic diversity of lactococci isolated from raw milk in the Camembert cheese Registered Designation of Origin area was studied. Two seasonal samples (winter and summer) of raw milk were obtained from six farms in two areas (Bessin and Bocage Falaisien) of Normandy. All of the strains analyzed had a Lactococcus lactis subsp. lactis phenotype, whereas the randomly amplified polymorphic DNA (RAPD) technique genotypically identified the strains as members of L. lactis subsp. lactis or L. lactis subsp. cremoris. The genotypes were confirmed by performing standard PCR with primers corresponding to a region of the histidine biosynthesis operon. The geographic distribution of each subspecies of L. lactis was determined; 80% of the Bocage Falaisien strains were members of L. lactis subsp. lactis, and 30.5% of the Bessin strains were members of L. lactis subsp. lactis. A dendrogram was produced from a computer analysis of the RAPD profiles in order to evaluate the diversity of the lactococci below the subspecies level. The coefficient of similarity for 117 of the 139 strains identified as members of L. lactis subsp. cremoris was as high as 66%. The L. lactis subsp. lactis strains were more heterogeneous and formed 10 separate clusters (the level of similarity among the clusters was 18%). Reference strains of L. lactis subsp. lactis fell into 2 of these 10 clusters, demonstrating that lactococcal isolates are clearly different. As determined by the RAPD profiles, some L. lactis subsp. lactis strains were specific to the farms from which they originated and were recovered throughout the year (in both summer and winter). Therefore, the typicality of L. lactis subsp. lactis strains was linked to the farm of origin rather than the area. These findings emphasize the significance of designation of origin and the specificity of “Camembert de Normandie” cheese.     

Purification and Characterization of a Tripeptidase from Lactococcus lactis subsp. cremoris Wg2

A tripeptidase from a cell extract of Lactococcus lactis subsp. cremoris Wg2 has been purified to homogeneity by DEAE-Sephacel and phenyl-Sepharose chromatography followed by gel filtration over a Sephadex G-100 SF column and a high-performance liquid chromatography TSK G3000 SW column. The enzyme appears to be a dimer with a molecular weight of between 103,000 and 105,000 and is composed of two identical subunits each with a molecular weight of about 52,000. The tripeptidase is capable of hydrolyzing only tripeptides. The enzyme activity is optimal at pH 7.5 and at 55°C. EDTA inhibits the activity, and this can be reactivated with Zn²⁺, Mn²⁺, and partially with Co²⁺. The reducing agents dithiothreitol and β-mercaptoethanol and the divalent cation Cu²⁺ inhibit tripeptidase activity. Kinetic studies indicate that the peptidase hydrolyzes leucyl-leucyl-leucine with a K_m of 0.15 mM and a V_max of 151 μmol/min per mg of protein.     

Inactivation of the Glutamate Decarboxylase Gene in Lactococcus lactis subsp. cremoris

Lactococcus lactis subsp. lactis strains show glutamate decarboxylase activity, whereas L. lactis subsp. cremoris strains do not. The gadB gene encoding glutamate decarboxylase was detected in the L. lactis subsp. cremoris genome but was poorly expressed. Sequence analysis showed that the gene is inactivated by the frameshift mutation and encoded in a nonfunctional protein.     

Conjugal Transfer in Lactic Streptococci of Plasmid-Encoded Insensitivity to Prolate- and Small Isometric-Headed Bacteriophages

Eight of 40 strains of Streptococcus lactis and S. lactis subsp. diacetylactis were able to conjugally transfer a degree of phage insensitivity to Streptococcus lactis LM0230. Transconjugants from one donor strain, S. lactis subsp. diacetylactis 4942, contained a 106-kilobase (kb) cointegrate plasmid, pAJ1106. The plasmid was conjugative (Tra⁺) and conferred phage insensitivity (Hsp) and lactose-fermenting ability (Lac) in S. lactis and Streptococcus cremoris transconjugants. The phage resistance mechanism was effective against prolate- and small isometric-headed phages at 30°C. In S. lactis transconjugants, the phage resistance mechanism was considerably weakened at elevated temperatures. A series of deletion plasmids was isolated from transconjugants in S. cremoris 4854. Deletion plasmids were pAJ2074 (74 kb), Lac⁺, Hsp⁺, Tra⁺; pAJ3060 (60 kb), Lac⁺, Hsp⁺; and pAJ4013 (13 kb), Lac⁺. These plasmids should facilitate mapping Hsp and tra genes, with the aim of constructing phage-insensitive strains useful to the dairy industry.     

Cooperation between Lactococcus lactis and Nonstarter Lactobacilli in the Formation of Cheese Aroma from Amino Acids

In Gouda and Cheddar type cheeses the amino acid conversion to aroma compounds, which is a major process for aroma formation, is essentially due to lactic acid bacteria (LAB). In order to evaluate the respective role of starter and nonstarter LAB and their interactions in cheese flavor formation, we compared the catabolism of phenylalanine, leucine, and methionine by single strains and strain mixtures of Lactococcus lactis subsp. cremoris NCDO763 and three mesophilic lactobacilli. Amino acid catabolism was studied in vitro at pH 5.5, by using radiolabeled amino acids as tracers. In the presence of α-ketoglutarate, which is essential for amino acid transamination, the lactobacillus strains degraded less amino acids than L. lactis subsp. cremoris NCDO763, and produced mainly nonaromatic metabolites. L. lactis subsp. cremoris NCDO763 produced mainly the carboxylic acids, which are important compounds for cheese aroma. However, in the reaction mixture containing glutamate, only two lactobacillus strains degraded amino acids significantly. This was due to their glutamate dehydrogenase (GDH) activity, which produced α-ketoglutarate from glutamate. The combination of each of the GDH-positive lactobacilli with L. lactis subsp. cremoris NCDO763 had a beneficial effect on the aroma formation. Lactobacilli initiated the conversion of amino acids by transforming them mainly to keto and hydroxy acids, which subsequently were converted to carboxylic acids by the Lactococcus strain. Therefore, we think that such cooperation between starter L. lactis and GDH-positive lactobacilli can stimulate flavor development in cheese.     

Rapid PCR-Based Method Which Can Determine Both Phenotype and Genotype of Lactococcus lactis Subspecies

A highly efficient, rapid, and reliable PCR-based method for distinguishing Lactococcus lactis subspecies (L. lactis subsp. lactis and L. lactis subsp. cremoris) is described. Primers complementary to positions in the glutamate decarboxylase gene have been constructed. PCR analysis with extracted DNA or with cells of different L. lactis strains resulted in specific fragments. The length polymorphism of the PCR fragments allowed a clear distinction of the L. lactis subspecies. The amplified fragment length polymorphism with the primers and the restriction fragment length polymorphism of the amplified products agreed perfectly with the identification based on genotypic and phenotypic analyses, respectively. Isolates from cheese starters were investigated by this method, and amplified fragments of genetic variants were found to be approximately 40 bp shorter than the typical L. lactis subsp. cremoris fragments.     

Antisense RNA directed against the major capsid protein of Lactococcus lactis subsp. cremoris bacteriophage 4-1 confers partial resistance to the host

Summary Antisense RNA targeted against the major capsid protein (MCP) of Lactococcus lactis subsp. cremoris bacteriophage F4-1 reduced bacteriophage replication by up to 50%. The region containing the mcp gene was oriented to transcribe the antisense strand using a L. lactis subsp. cremoris Wg2 promoter. The size of the mcp insert transcribed affected the level of bacteriophage inhibition and the greatest level of inhibition was achieved using a 301-bp fragment from the 5 end of the mcp. Antisense mcp RNA constructs were stable and did not alter the endogenous plasmid profile in the host, L. lactis subsp. cremoris F4-1. There were, however, some adverse effects on the host during the stationary phase as exhibited by a decline in cell density. Offprint requests to: C. A. Batt     

Identification of Lactococcus lactis Genes Required for Bacteriophage Adsorption

The aim of this work was to identify genes in Lactococcus lactis subsp. lactis IL1403 and Lactococcus lactis subsp. cremoris Wg2 important for adsorption of the 936-species phages bIL170 and 645, respectively. Random insertional mutagenesis of the two L. lactis strains was carried out with the vector pGh9:ISS1, and integrants that were resistant to phage infection and showed reduced phage adsorption were selected. In L. lactis IL1403 integration was obtained in the ycaG and rgpE genes, whereas in L. lactis Wg2 integration was obtained in two genes homologous to ycbC and ycbB of L. lactis IL1403. rgpE and ycbB encode putative glycosyltransferases, whereas ycaG and ycbC encode putative membrane-spanning proteins with unknown functions. Interestingly, ycaG, rgpE, ycbC, and ycbB are all part of the same operon in L. lactis IL1403. This operon is probably involved in biosynthesis and transport of cell wall polysaccharides (WPS). Binding and infection studies showed that 645 binds to and infects L. lactis Wg2, L. lactis IL1403, and L. lactis IL1403 strains with pGh9:ISS1 integration in ycaG and rgpE, whereas bIL170 binds to and infects only L. lactis IL1403 and cannot infect Wg2. These results indicate that 645 binds to a WPS structure present in both L. lactis IL1403 and L. lactis Wg2, whereas bIL170 binds to another WPS structure not present in L. lactis Wg2. Binding of bIL170 and 645 to different WPS structures was supported by alignment of the receptor-binding proteins of bIL170 and 645 that showed no homology in the C-terminal part.