Proteolysis of Hispanico cheese manufactured using lacticin 481-producing Lactococcus lactis ssp. lactis INIA 639

Hispánico cheese was manufactured using lacticin 481-producing Lactococcus lactis ssp. lactis INIA 639, bacteriocin-nonproducing L. lactis ssp. lactis INIA 437, or a combination of both strains, as starter cultures. Lactobacillus helveticus LH 92, a culture of high amino-peptidase activity sensitive to lacticin 481, was added to all vats. Milk inoculation with the bacteriocin producer promoted early lysis of Lb. helveticus cells in cheese. Cell-free aminopeptidase activity in cheese made with the 3 lactic cultures was 1.8 times the level reached in cheese made only with L. lactis strain INIA 437 and Lb. helveticus, after 15 d of ripening. Proteolysis (as estimated by the o-phthaldialdehyde method) in cheese made with the 3 lactic cultures was twice as high, and the level of total free amino acids 2.4 times the level found in cheese made only with L. lactis strain INIA 437 and Lb. helveticus, after 25 d of ripening. Hydrophobic and hydrophilic peptides and their ratio were at the lowest levels in cheese made with the 3 lactic cultures, which received the lowest scores for bitterness and the highest scores for taste quality.     

Volatile compounds and aroma of Hispánico cheese manufactured using lacticin 481-producing Lactococcus lactis subsp. lactis INIA 639 as an adjunct culture

Lacticin 481-producing Lactococcus lactis subsp. lactis INIA 639 (BP), bacteriocin-nonproducing L. lactis subsp. lactis INIA 437 (BNP), or a combination of both strains were used as mesophilic cultures for Hispánico cheese manufacture. A Lactobacillus helveticus (LH) culture of high aminopeptidase activity, sensitive to lacticin 481, was used as thermophilic culture. Three batches (BP+LH, BNP+LH, and BNP+BP+LH cheeses) were made in duplicate experiments. Ethanol, 1-propanol, and three ethyl esters reached their highest levels in BP+LH cheese, whereas acetic acid, five ketones, and two alkanes were at their maximum levels in BNP+LH cheese. Higher levels of acetaldehyde and three branched chain aldehydes were found in BNP+BP+LH cheese than in the other two cheeses. Aroma quality and aroma intensity scores were higher for BP+LH and BNP+BP+LH cheeses than for BNP+LH cheese.     

Elevated enzyme release from lactococcal starter cultures on exposure to the lantibiotic lacticin 481, produced by Lactococcus lactis DPC5552

A Lactococcus lactis subsp. lactis strain (DPC5552), which causes the lysis of other lactococcal cultures, was isolated during a screening of raw milk samples for bacteriocin producers. Purification of the bacteriocin produced revealed that production of the lantibiotic, lacticin 481, was associated with the bacteriolytic capability of the strain. However, unlike bacteriocin-induced lysis observed with bacteriocins such as lacticin 3147 and lactococcins A, B, and M (where the target strain is killed), the DPC5552 supernatant gave rise to a situation whereby the target strain continued to grow (albeit at a lower rate) with simultaneous release of the intracellular enzymes lactate dehydrogenase (LDH) and post-proline dipeptidyl aminopeptidase (Pep X). In parallel experiments, 32 AU/ml of the inhibitory activity from L. lactis DPC5552 resulted in a 10- and 6-fold-higher LDH release after 5 h than that with 32 AU/ml of either lacticin 3147 or lactococcin A, B, and M. Laboratory-scale Cheddar cheese-making trials also demonstrated that lacticin 481-producing cultures induced the release of elevated levels of LDH from the starter L. lactis HP, without severely compromising its acid-producing capabilities. These results indicate that lacticin 481-producing strains may provide improved adjuncts for delivering lactococcal intracellular enzymes into the cheese matrix and, thus, improve cheese quality and flavor.     

Control of late blowing in cheese by adding lacticin 3147-producing Lactococcus lactis IFPL 3593 to the starter

Bacteriocins produced by lactic acid bacteria offer potential as tools for ensuring food safety and quality. Lacticin 3147 is a two-peptide lantibiotic previously shown to inhibit a broad range of food spoilage and pathogenic bacteria. Lacticin 3147-producing Lactococcus lactis IFPL 3593 was investigated for its ability to inhibit the growth of clostridia as a means to prevent late blowing in cheese. L. lactis IFPL 3593 was shown to inhibit germination of clostridia spores and prevent late blowing in semi-hard cheeses, with a 5 log g^?1 reduction in the numbers of spores when compared to control cheeses. Furthermore, this bacteriocin-producing strain demonstrated considerable potential as a biopreservative agent against heterofermentative lactobacilli and their associated blowing defects. The use of this strain to prevent late blowing in cheese thereby represents a promising alternative to the addition of lysozyme particularly given the increasing concerns regarding the potential allergenicity of this additive.     

Partial characterization of lacticin NK24, a newly identified bacteriocin of Lactococcus lactis NK24 isolated from Jeot-gal

Strain NK24 was isolated from Jeot-gal and identified as a bacteriocin producer, which has bactericidal activity against Leuconostoc mesenteroides KCCM 11324. Strain NK24 was identified tentatively as Lactococcus lactis by the API test. The activity of lacticin NK24, named tentatively as the bacteriocin produced by L. lactis NK24, was detected during the mid-log growth phase, reached a maximum during the early stationary phase, and decreased after the late stationary phase. Lacticin NK24 showed a relatively broad spectrum of activity against non-pathogenic and pathogenic micro-organisms as assessed using the spot-on-lawn method. Its antimicrobial activity on sensitive indicator cells was completely destroyed by protease IX or protease XIV. The inhibitory activities of lacticin NK24 were detected during treatments up to 100°C for 30 min. Lacticin NK24 was very stable over a pH range of 2·0–9·0 and to all organic solvents examined. It demonstrated a typical bactericidal mode of inhibition against L. mesenteroides KCCM 11324. The apparent molecular mass of lacticin NK24 was estimated to be in the region of 3–3·5 kDa, which was determined by the direct detection of bactericidal activity after SDS-PAGE.     

Lactococcin MMT24, a novel two-peptide bacteriocin produced by Lactococcus lactis isolated from rigouta cheese

Lactococcin MMT24 is a novel bacteriocin produced by Lactococcus lactis MMT24, a strain isolated from a Tunisian traditional cheese. The bacteriocin shows a narrow antimicrobial activity against closely related lactic acid bacteria. Lactococcin MMT24 is heat resistant, remains active after incubation at pH 3 to 10, lyophilization, long-term storage at -20 degrees C and is sensitive to treatment with proteolytic enzymes. The mode of action of lactococcin MMT24 was identified as bactericidal. Purification of the active compound showed that lactococcin MMT24 consists of two distinct peptides, named pepalpha and pepbeta, whose complementary action is necessary for full antibacterial activity. Optimal antibacterial activity was obtained when the complementary peptides pepalpha and pepbetawere present in equal amounts. Mass spectrometry analysis showed masses of 3765.33 Da and 3255.26 Da for pepalpha and pepbeta, respectively. These molecular masses do not correspond to those of so far described bacteriocins. Addition of 50 nmol l(-1) of lactococcin MMT24 to cells of L. lactis ssp. cremoris ATCC11603 induced increase in the concentration of K+ in supernatant indicating a massive leakage of this ion from the cells. This release was most likely caused by pores formation by the pepalphaand pepbeta peptides in the target bacterial membrane.     

Optimisation of bacteriocin production of Lactococcus lactis subsp. lactis MA23, a strain isolated from Boza

Lactococcus lactis subsp. lactis MA23 produces a bacteriocin (6400 AU/mL) that inhibits the growth of many Gram‐positive bacteria but is not active against Gram‐negative bacteria. This bacteriocin inhibits growth of lactococcal strains that are producing nisin, lacticin or lactococcin suggesting it to be different from these bacteriocins. The nutritional requirements and optimal growth conditions for MA23 bacteriocin production were studied with fed‐batch fermentations. The optimal pH, carbon source and nitrogen source for bacteriocin production were pH 6.5, sucrose (0.5%) and yeast extract (1%), respectively.     

Identification and partial characterization of lacticin BH5, a bacteriocin produced by Lactococcus lactis BH5 isolated from Kimchi

Strain BH5 was isolated from naturally fermented Kimchi and identified as a bacteriocin producer that has bactericidal activity against Micrococcus flavus ATCC 10240. Strain BH5 was identified tentatively as Lactococcus lactis by API test. Lactococcus lactis BH5 showed a broad spectrum of activity against most of the nonpathogenic and pathogenic microorganisms tested by the modified deferred method. The activity of lacticin BH5, named tentatively as the bacteriocin produced by L. lactis BH5, was detected at the mid-log growth phase, reached its maximum during the early stationary phase, and decreased after the late stationary phase. Lacticin BH5 also showed a relatively broad spectrum of activity against nonpathogenic and pathogenic microorganisms as tested by the spot-on-lawn method. Its antimicrobial activity on sensitive indicator cells was completely destroyed by protease XIV. The inhibitory activities of lacticin BH5 were detected during treatments up to 100 degrees C for 30 min. Lacticin BH5 was very stable over a pH range of 2.0 to 9.0 and was stable with all the organic solvents examined. It demonstrated a typical bactericidal mode of inhibition against M. flavus ATCC 10240. The apparent molecular mass of lacticin BH5 was estimated to be in the region of 3 to 3.5 kDa, by the direct detection of bactericidal activity after sodium dodecyl sulfate-polyacrylamide gel electrophoresis.     

Growth stimulation of a proteinase positive Lactococcus lactis strain by a proteinase negative Lactococcus lactis strain

Lactococcus lactis AMP15/pAMP31(D471R) is a proteinase negative, lactose negative strain with a modified oligopeptide transport system, and potential as a debittering agent due to its efficient utilization of hydrophobic peptides. Five wild L. lactis strains of dairy origin, which produced cheeses of high flavour quality, were cocultured with L. lactis AMP15/pAMP31(D471R) in an attempt to select adequate combinations of strains for use as defined cheese starters with potential debittering ability. Four of these strains, L. lactis B6, K16, M21 and P21, inhibited growth of L. lactis AMP15/pAMP31(D471R) at a level of 10(6) to 10(7) cfu mL(-1) after 24 h of incubation, even though production of bacteriocin-like compounds could only be proven for L. lactis M21. When L. lactis AMP15/pAMP31(D471R) was cocultured with the fifth strain, L. lactis N22, its growth was significantly (P<0.001) inhibited whereas growth of L. lactis N22 was significantly stimulated. The nature of the interaction was studied and it was established that L. lactis N22 is auxotrophic for folate, a compound produced and excreted by L. lactis AMP15/pAMP31(D471R).     

Phenotypic and genetic characterization of a selected set of Lactococcus lactis strains isolated from a starter-free farmhouse cheese

Eleven strains of lactococci isolated from a farmhouse starter-free cheese manufactured from raw cow's milk were analysed in detail for some technologically-related properties. Large phenotypic differences were encountered between the isolates, some of which could be of practical relevance. Several strains produced lactic acid at a rate and at a final concentration suitable for large-scale cheesemaking. The enzymatic capabilities assayed with the API ZYM system showed that all strains possess similar profiles with weak proteinase and moderate leucine-arylamidase and esterase-lipase activities. Interestingly, two related strains presented a strong β -galactosidase activity. Plasmid and chromosomal analyses indicated a high degree of diversity among wild strains and showed low homology with some well-known Lactococcus lactis strains. Under highly stringent conditions, only one plasmid from a single strain gave a clear positive hybridization signal with lactococcal-derived probes for the β -phospho- galactosidase and the proteinase genes. In general, wild strains produced more odorous compounds and in higher amounts than the reference strains.     

Inhibition of a methicillin-resistant Staphylococcus aureus strain in Afuega'l Pitu cheese by the nisin Z-producing strain Lactococcus lactis subsp. lactis IPLA 729

Methicillin-resistant Staphylococcus aureus strains are a potential threat for food safety because foodborne illness caused by methicillin-resistant Staphylococcus aureus has been reported even though these strains were only associated with nosocomial infections until recently. This article focuses on the inhibitory effect of the nisin Z-producing strain Lactococcus lactis subsp. lactis IPLA 729 on the growth of Staphylococcus aureus CECT 4013, a methicillin-resistant strain. S. aureus was inhibited by the presence of the nisin producer IPLA 729 in buffered Trypticase soy broth, milk, and Afuega'l Pitu cheese, an acid-coagulated cheese manufactured in Asturias, Northern Spain. A reduction of 3.66 log units was observed in Trypticase soy broth at the end of the incubation period. In milk, viable counts of S. aureus were undetectable or were reduced by 2.16 log units in 24 h depending on the initial inoculum (1.8 x 10(4) and 7.2 x 10(6) CFU/ml). The staphylococcal strain was also undetected in test cheeses in which the nisin Z producer was present whereas 2 log units were detected in control cheeses at the end of ripening.     

Occurrence of nisin Z production in Lactococcus lactis BFE 1500 isolated from wara, a traditional Nigerian cheese product

Screening for bacteriocin production of 500 strains of lactic acid bacteria (LAB) from various African fermented foods resulted in the detection of a bacteriocin producing Lactococcus lactis (BFE 1500) isolated from a dairy product called wara. The bacteriocin inhibited not only the closely related LAB, but also strains of Listeria monocytogenes, Listeria innocua, Clostridium butyricum, Clostridium perfringens, Bacillis cereus and Staphylococcus aureus. It was heat stable even at autoclaving temperature (121 degrees C for 15 min) and was active over a wide pH range (2-10), but highest activity was observed in the lower pH range. The bacteriocin was inactivated by alpha-chymotrypsin and proteinase K, but not by other proteases. Growth kinetic assay indicated stronger growth inhibition by the bacteriocin produced by Lc. lactis BFE 1500 on L. monocytogenes WS 2250 and B. cereus DSM 2301 than with the nisin A producing strain DSM 20729. Polymerase chain reaction indicated the presence of the nisin operon in strain BFE 1500 and sequencing of its structural gene showed that Lc. lactis BFE 1500 produced the natural nisin variant, nisin Z, as indicated by the substitution of asparagine residue instead of histidine at position 27. The genetic determinants for bacteriocin production in strain BFE 1500 are located on a conjugative transposon. The ability of the bacteriocin produced by Lc. lactis BFE 1500 to inhibit a wide range of food-borne pathogens is of special interest for food safety, especially in the African environment with perennial problems of poor food hygiene.     

Characterization of four new Lactococcus lactis bacteriophages isolated from dahi whey

Four lytic phages of Lactococcus lactis ssp. diacetylactis isolated from indigenous dahi whey were examined for their stability, growth characteristics and morphology. All these phages were partially inactivated by CHCl₃ , remained stable at 40°C and were partially inactivated at pH 3. There was a marked difference among these phages with respect to latent period, rise period and burst size. All phages belonged to Bradley's group B.     

Nisin and lacticin 481 coproduction by Lactococcus lactis strains isolated from raw ewes’ milk

Bacteriocin-producing lactococci were isolated from raw ewes’ milk samples obtained from 5 different Protected Designation of Origin Zamorano cheese manufacturers. Thirteen isolates with antimicrobial activity against Lactococcus lactis HP were selected. Eleven were identified by a PCR technique as L. lactis ssp. lactis and 2 were identified as L. lactis ssp. cremoris. They were grouped under 4 different pulsed-field gel electrophoresis patterns. The presence of structural genes of both nisin and lacticin 481 was detected in 10 L. lactis ssp. lactis isolates belonging to 2 different pulsed-field gel electrophoresis patterns. Coproduction of nisin and lacticin 481 was confirmed after semipurification by using selective indicators. The production of 2 bacteriocins by the same strain is an uncommon property, with relevance in food safety. Nisin and lacticin 481 L. lactis-producing strains might be used as adjunct cultures to the commercial starter in the manufacture of dairy products.     

Cell membrane damage induced by lacticin 3147 enhances aldehyde formation in Lactococcus lactis IFPL730

Amino acid catabolism is mainly initiated in Lactococcus lactis by a transamination reaction that leads to the formation of alpha-keto acids. In addition, a novel alpha-keto acid decarboxylase enzyme, rare in lactic acid bacteria, responsible for the conversion of alpha-keto acids into aldehydes has been reported in L. lactis IFPL730. The effect of lacticin 3147-induced cell damage on both amino acid transamination and alpha-keto acid decarboxylation by L. lactis IFPL730 leading to the formation of aldehydes from amino acids was investigated. Cell membrane permeabilization induced by lacticin 3147 facilitated the diffusion of amino acids into the cells and thus, enhanced amino acid transamination and formation of alpha-keto acids. However, alpha-keto acid decarboxylation was not affected by cell membrane permeabilization since decarboxylation of alpha-keto acids in both control and lacticin 3147-treated cells were similar, suggesting that these substrates could freely diffuse inside the cells. Nevertheless, the formation of 2-methylbutyraldehyde from isoleucine was enhanced in lacticin 3147-treated cells. The increase in alpha-keto acids formation rate by L. lactis IFPL730 due to lacticin 3147-induced cell damage, led to a concomitant increase in the subsequent decarboxylation reaction that complete the metabolic pathway to aldehyde production from amino acids. The present study points out to the use of the food grade lacticin 3147 along with L. lactis IFPL730 as a valuable tool in the development of cheese flavour.     

Immunostimulatory activity of Lactococcus lactis LM1185 isolated from Hydrangea macrophylla

Food Science and Biotechnology - The lactic acid bacteria, Lactococcus lactis subsp. lactis LM1185 was isolated from Hydrangea macrophylla. Strain LM1185 showed 50.5% of acid tolerance at pH 2.5...     

Enhancement of 2-methylbutanal formation in cheese by using a fluorescently tagged Lacticin 3147 producing Lactococcus lactis strain

The amino acid conversion to volatile compounds by lactic acid bacteria is important for aroma formation in cheese. In this work, we analyzed the effect of the lytic bacteriocin Lacticin 3147 on transamination of isoleucine and further formation of the volatile compound 2-methylbutanal in cheese. The Lacticin 3147 producing strain Lactococcus lactis IFPL3593 was fluorescently tagged (IFPL3593-GFP) by conjugative transfer of the plasmid pMV158GFP from Streptococcus pneumoniae, and used as starter in cheese manufacture. Starter adjuncts were the bacteriocin-sensitive strains L. lactis T1 and L. lactis IFPL730, showing branched chain amino acid aminotransferase and alpha-keto acid decarboxylase activity, respectively. Adjunct strains were selected to complete the isoleucine conversion pathway and, hence, increase formation of 2-methylbutanal conferring aroma to the cheese. The non-bacteriocin-producing strain L. lactis IFPL359-GFP was included as starter in the control batch. Fluorescent tagging of the starter strains allowed their tracing in cheese during ripening by fluorescence microscopy and confocal scanning laser microscopy. The bacteriocin produced by L. lactis IFPL3593-GFP enhanced lysis of the adjuncts with a concomitant increase in isoleucine transamination and about a two-fold increase of the derived volatile compound 2-methylbutanal. This led to an enhancement of the cheese aroma detected by a sensory panel. The improvement of cheese flavour and aroma may be of significant importance for the dairy industry.     

腐乳源乳酸乳球菌17M1高密度培养条件研究

为了获得乳酸乳球菌(Lactococcus lactis)17M1的高密度培养方法,以菌体密度和活菌数为评价指标,以豆腐乳清为基础培养基,采用响应面法对该菌株的培养基组成进行优化,并研究其培养条件。结果表明,菌株17M1的最佳培养基组成为：在豆腐乳清中加入2.00%大豆蛋白胨、胰酪蛋白胨1.70%、柠檬酸铵2.30%。在此优化培养基中初始pH值6.15,于37℃培养15 h,乳酸乳球菌17M1的活菌数达到了1.17×10¹⁰CFU/mL,高于M17肉汤培养基活菌数(1.04×10⁹CFU/mL)。该研究结果为乳酸乳球菌17M1的工业化应用提供了技术支持。     

Quality and nutritional characteristics of traditional curd cheese enriched with thermo-coagulated acid whey protein and indigenous Lactococcus lactis strain

Consumer interest in a healthy lifestyle and health-promoting natural products is a major driving force for the increasing global demand for bio-functional and sustainable dairy foods. Supplementation of curd cheese with thermo-coagulated acid whey protein (TAWP) led to 8–10% higher contents of moisture, 23–31% of lactose, 12–13% of unsaturated, 5–6% of monounsaturated, 63% of polyunsaturated, and 3–4% of long-chain fatty acids. Lipid quality indices – TI, AI, h/H, and Omega 6/3 among others, were also significantly better than those of control cheese. The addition of indigenous Lactococcus lactis strain enhanced the flavour of cheese samples, decreased the counts of yeast and mould up to 1 log cfu g⁻¹ after 10 days of storage. The replacement of curd with TAWP resulted in novel cheese with overall sensory perception above 77 points and added nutritional and functional value, however, body and texture parameters of modified cheese samples require an improvement.