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).     

Arginine metabolism in sugar deprived Lactococcus lactis enhances survival and cellular activity, while supporting flavour production

Flavour development in cheese is affected by the integrity of Lactococcus lactis cells. Disintegrated cells enhance for instance the enzymatic degradation of casein to free amino acids, while integer cells are needed to produce specific flavour compounds from amino acids. The impact of the cellular activity of these integer cells on flavour production remains to be elucidated. In this study we investigated whether lactose-deprived L. lactis cells that use arginine as an alternative energy source can extend cellular activity and produce more specific flavours. In cheese experiments we demonstrated that arginine metabolising cells survived about 3 times longer than non-arginine metabolising cells, which suggests prolonged cellular activity. Cellular activity and flavour production of L. lactis was further studied in vitro to enable controlled arginine supplementation. Comparable with the results found in cheese, the survival rates of in vitro incubated cells improved when arginine was metabolised. Furthermore, elongated cellular activity was reflected in 3-4-fold increased activity of flavour generating enzymes. The observed prolonged cellular activity resulted in about 2-fold higher concentrations of typical Gouda cheese flavours. These findings provide new leads for composing starter cultures that will produce specific flavour compounds.     

Fermented soymilk with a monoculture of Lactococcus lactis

Lactococcus lactis strain (LL3) isolated from mothers' milk was used to produce fermented soymilk. The strain survived at levels of over 7 log cfu/ml for 3 weeks in the fermented soymilk. A consumer survey was carried out to compare the acceptability of the fermented product with a similar product made with L. lactis ATCC11545 originally isolated from cow's milk. Blind samples produced by fermentation with the two strains were rated equally attractive, whereas information on the origin of the strains significantly enhanced the pleasantness of the fermented soymilk.     

产生菌株的筛选及其鉴定

以从传统乳制品中分离得到的7株乳酸菌为出发菌株,应用琼脂扩散法,以黄色微球菌为指示菌,筛选到了一株具有较大抑菌作用的乳酸菌.对S7产生的抑菌物质的物理化学性质研究表明,该抑菌物质的性质与Nisin一致;同时16SrDNA序列分析结果显示,S7是一株乳酸乳球菌,综合以上结果,可以认为这是一株Nisin产生菌.     

乳酸乳球菌与酵母菌混合培养时菌间的相互影响

研究了干酪常用发酵剂——乳酸乳球菌与干酪中两株常见酵母菌——耶罗解脂酵母及汉逊德巴利酵母混合培养时的相互影响.在营养肉汤中对三株菌单独及混合培养,比浊法测定其生长浓度,同时在脱脂乳培养基中做相同培养,然后检测活菌数、球菌产酸及菌株自溶情况.结果表明:乳酸乳球菌、耶罗解脂酵母及汉逊德巴利酵母三株菌混合培养时其菌数及自溶度,均有显著增加,表明混合培养加快了菌株生长代谢的速率.这对研究干酪促熟及风味调整具有重要意义.     

Metabolism of Lactococcus lactis subsp. cremoris MG 1363 in acid stress conditions

The metabolism of glucose by Lactococcus lactis subsp. cremoris MG 1363 remains homolactic whatever the pH of the culture medium. The growth rate decreased with the acidification of the medium until a limit pH value of 4.0 for which no growth was observed. In contrast, the specific rate of glucose consumption decreased only for very low pH values, i.e., below 4.5. The efficiency of biomass synthesis relative to the energy supply decreased when the medium pH diminished, as illustrated by Y(ATP) values. This observation was related to the increase in both components of the proton-motive force when the pH decreased. The growth stopped when the internal pH reached a limit value of 5.4 due to organic acid accumulation.     

乳酸乳球菌细胞壁蛋白酶的分离纯化

本研究确定了分离纯化乳酸乳球菌细胞壁蛋白酶(CEP)的最佳技术路线.用裂解液(50mmol/L Tris-HCI,2mmol/L EDTA-Na2,100mmol/L NaCl,0.5%Tritonx-100,1mg/ml溶菌酶,pH8.5)悬浮菌体(20ml/g),37℃下保温3h,离心后取上清液即为粗酶液.粗酶液通过45%硫酸铵沉淀,DEAE-Sephadcx A-25和Sephacryl-S-300 HR两步层析,可以得到纯化的细胞壁蛋白酶.蛋白酶提纯倍数达到74.048%,最后回收率为14.865%,PAGE电泳检测为一条带,SDS-PAGE检测蛋白酶为单体结构,分子量大约为53kD.用纯化后CEP酶解乳清蛋白,酶解液ACE抑制率为45%.     

The effect of lactose, NaCl and an aero/anaerobic environment on the tyrosine decarboxylase activity of Lactococcus lactis subsp. cremoris and Lactococcus lactis subsp. lactis

The aim of this work was to study, under model conditions, combined effects of the concentration of lactose (0-1% w/v), NaCl (0-2% w/v) and aero/anaerobiosis on the growth and tyramine production in 3 strains of Lactococcus lactis subsp. lactis and 2 strains of L. lactis subsp. cremoris. The levels of the factors tested were chosen with respect to the conditions which can occur during the real process of natural cheese production, including the culture temperature (10 ± 1 °C). In all strains tested, tyrosine decarboxylation was most influenced by NaCl concentration; the highest production of tyramine was obtained within the culture with the highest (2% w/v) salt concentration applied. Two of the strains L. lactis subsp. lactis produced tyramine only in broth with the highest NaCl concentration tested. In the remaining 3 strains of L. lactis, tyramine was detected under all conditions applied. The tested concentration of lactose and aero/anaerobiosis had a less significant effect on tyramine decarboxylation. However, it was also found that at the same concentrations of NaCl and lactose, a higher amount of tyramine was detected under anaerobic conditions. In all strains tested, tyramine decarboxylation started during the active growth phase of the cells.     

Formation of methional by Lactococcus lactis IFPL730 under cheese model conditions

The present work describes the capacity of Lactococcus lactis to produce methional and other sulphur compounds derived from methionine (Met) in a cheese model system. Cheese slurries were prepared from pasteurized ewes' skimmed milk, chemically acidified with glucono-'-lactone and homogenized aseptically adding Met, !-ketoglutarate, pyridoxal 5'-phosphate, thiamine pyrophosphate and NaCl. Slurries were incubated at 12 °C for 14 days with cellular suspensions of L. lactis IFPL359, L. lactis IFPL730 and L. lactis NCDO763 in different combinations. Slurries added with resting cells and the intracellular fraction from L. lactis IFPL730 showed the highest production of methional at the outset of incubation, which decreased during incubation along with a concomitant increase in 3-methylthiopropanol. The sensorial analysis of slurries indicated a characteristic methional aroma (cooked potato-like) in samples containing 4-methylthio-2-ketobutyrate and the intracellular fraction from L. lactis IFPL730. As incubation proceeded, the intensity of methional aroma decreased but samples were judged by the panel tasters as developing a cheese-like flavour.     

Subspecies-Specific Nested PCR Assay for Detection of Lactococcus lactis spp. lactis and spp. cremoris

A nested PCR-based assay composed of Lactococcus lactis species-specific primers for the nest 1 amplification and subspecies-specific primers for the nest 2 amplification was validated with the identified strains of L. lactis isolated from dairy and nondairy sources and positive and negative control strains. Forward and reverse primer set was designed for nest 1 amplification targeting the conserved housekeeping gene yueF encoding nonproteolytic protein from peptidase family M16 of L. lactis. Amplicons of 447 bp of yueF were subjected for nest 2 amplification producing amplicons of 372 bp. The designed outer primer set for nest 1 amplification was observed to be specific to L. lactis because the DNA from other bacteria could not be amplified and the inner primer set for nest 2 amplification was found to be specific for the detection of ssp. lactis and cremoris of L. lactis.     

Validation of a model for growth of Lactococcus lactis and Listeria innocua in a structured gel system: effect of monopotassium phosphate

The effect of monopotassium phosphate (KH(2)PO(4)) on the chemical environment and on growth of Listeria innocua and Lactococcus lactis in coculture were investigated in a liquid and in a gelled microbiological medium at 12 degrees C and an initial pH of 6.2. As expected, addition of KH(2)PO(4) to both the liquid and gelled media resulted in an increase in buffering capacity. This effect on buffering capacity changed the profiles of lactic acid dissociation and pH evolution. At all gelatin concentrations studied, addition of KH(2)PO(4) increased the growth rate and the stationary cell concentration of L. lactis. In addition, the growth rate of L. innocua slightly increased but, in contrast, the stationary cell concentration remained unchanged. A new class of predictive models developed previously in our research team to quantify the effect of food model gel structure on microbial growth [Antwi, M., Bernaerts, K., Van Impe, J. F., Geeraerd, A. H., 2007. Modelling the combined effect of food model system and lactic acid on L. innocua and L. lactis growth in mono- and coculture. International Journal of Food Microbiology 120, 71-84] was applied. Our analysis indicate that KH(2)PO(4) influenced the parameters of the chemical and microbiological subprocesses of the model. Nonetheless, the growth model satisfactorily predicted the stationary cell concentration when (i) the undissociated lactic acid concentrations at which L. innocua and L. lactis growth cease were chosen as previously reported, and (ii) all other parameters of the chemical and microbiological subprocesses were computed for each medium. This confirms that the undissociated lactic acid concentrations at which growth ceases is a unique property of a bacterium and does not, within our case study, depend on growth medium. The study indicates that microbial growth depends on the interplay between the individual food components which affect the physicochemical properties of the food, such as the buffering capacity. Towards future research, it can be concluded that mathematical models which embody the effect of buffering capacity are needed for accurate predictions of microbial growth in food systems.     

Fatty acid membrane composition and activation of glycine-betaine transport in Lactococcus lactis subjected to osmotic stress

Lactococcus lactis subsp. cremoris NCDO763 accumulates glycine-betaine (betaine) when submitted to an osmotic stress with NaCl. Betaine transport activity increases with the extent of the osmotic upshock but also with growth temperature, and supplementation of the medium by Tween-80. Fatty acid analysis of the lipid fraction of L. lactis NCDO763 reveals significant modifications of the fatty acid composition of the membrane when cells are submitted to osmotic stress, high temperature or Tween-80 medium supplementation. The main modification in L. lactis membrane fatty acid composition in response to high osmolality is the increase of Cyclopropane Fatty Acid (CFA) deltaC19:0, whereas Unsaturated/Saturated ratio remains unchanged.     

Spray Drying of Lactococcus lactis ssp. lactis C2 and Cellular Injury

Starter cultures were spray-dried at five outlet-air temperatures using four concentrations of cells in the feed solution. Powders made using the lowest outlet-air temperature and the highest cell concentration had the highest viability. Storage at 4°C for 3 mo caused a 34–86% loss of viability. Cellular injury resulted from dehydration, and exposure to high temperatures in the atomizer and during droplet drying. Lactic acid production was similar for frozen, freeze-dried and spray-dried cultures made from a single cell paste. The lag time before lactic acid production was apparently an inherent characteristic of each specific cell paste.     

Microcalorimetric study of the growth of bacterial colonies of Lactococcus lactis IL1403 in agar gels

Growth of Lactococcus lactis IL1403 in solid agar gels and liquid cultures at different glucose concentrations of 2, 10 and 20 g/L and different inoculation rates from 10⁰ to 10⁶ cfu/mL with the 10-fold increment was studied using thermal activity monitor TAM III. In parallel to calorimetric measurements the changes of glucose and lactic acid concentrations and pH of culture media were measured in order to obtain additional information for the interpretation of calorimetric power-time curves. Maximal specific growth rates of heat evolution proportional to growth rates of biomass μ_max (W/h), heat produced during different growth stages Q_TOT (J/mL), Q_ExP (J/mL) and duration of lag-phases λ (h) were obtained by processing calorimetric curves. The sizes of colonies were measured also at the end of growth using microscope. The data obtained together with calculated heat yield coefficient Y_Q (J/cfu) allowed to analyze and describe quantitatively the growth of individual colonies and develop a model of multistage growth of a typical colony of L. lactis in 1% agar gel. Microcalorimetry used in combination with other relevant methods is a very powerful and precise tool in studying solid-state fermentations.     

Genetically modified Lactococcus lactis: novel tools for drug delivery

The dairy bacterium Lactococcus lactis can be genetically engineered to secrete bioactive cytokines. This enabled the development of an entirely novel drug delivery system: topical and active delivery of therapeutic proteins by genetically modified micro-organisms. In mice, intestinal inflammation can be successfully treated with interleukin-10- (IL-10) or trefoil factor-secreting L. lactis . In human application, biological containment is guaranteed by exchange of the gene encoding thymidylate synthase for IL-10. The recombinant strain is now absolutely dependent on exogenous thymidine. Thymidine starvation will irreversibly lead to 'thymidine-less death' induction. This accomplishment has opened applications in human medicine.     

Inhibition of Clostridium tyrobutyricum in Vidiago cheese by Lactococcus lactis ssp. lactis IPLA 729, a nisin Z producer

Lactococcus lactis ssp. lactis IPLA 729 is a nisin Z producer isolated from raw milk cheese able to grow and produce nisin Z in milk. The ability of this strain to inhibit the growth of Clostridium tyrobutyricum CECT 4011, a late blowing agent, in Vidiago cheese, a semi-hard farmhouse variety, manufactured in Asturias, Northern Spain, was investigated. For control purposes, cheeses were manufactured with the mesophilic mixed starter IPLA-001. In experimental cheeses, the nisin-producing strain L. lactis IPLA 729 was combined with this starter. Nisin Z activity reached a concentration of 1600 AU/ml in 1-day cheeses and this level was maintained until 15 days of ripening. Furthermore, to compare the inhibitory activity of the nisin-producing strain to nitrate, cheeses were also manufactured with a commercial starter culture and potassium nitrate as anti-blowing agent was added in accordance with Vidiago's cheesemakers. The control, experimental and commercial cheeses were contaminated with C. tyrobutyricum CECT 4011. The composition of the three different cheeses showed only slight differences with respect to total solids, protein and fat, although control and experimental cheeses showed a richer flavour-compound profile than commercial cheeses. The level of the spoilage strain C. tyrobutyricum CECT 4011 decreased from 1.2x10(6) to 1.3x10(3) cfu/g during ripening in presence of the nisin Z producer, while it increased to 1.99x10(9) cfu/g in control cheeses and to 3.5x10(7) cfu/g in commercial cheeses.     

Diversity Analysis,Batch Fermentation and Characterization of Nisin in Identified Strains of Lactococcus lactis spp. lactis

Thirty-one strains of Lactococcus lactis spp. lactis were identified out of 89 isolates of lactic acid bacteria (LAB) from dairy and nondairy sources. Of the 31 strains, 24 (46.1%) were obtained from dairy and seven (18.9%) from non-dairy sources. The cluster analysis of rep-PCR showed that (GTG)₅-PCR followed by ERIC-PCR exhibited more discriminating potential than BOX-PCR. The obtained banding patterns characterized the polymorphism among strains. The strain level polymorphism was also obtained by the combined cluster analysis of (GTG)_5, ERIC and BOX-PCR which exhibited a level of heterogeneity among strains but not with the sources of isolation. Among 31 strains, 17 strains were able to produce zones of inhibition against Lactobacillus acidophilus NCDC 015 and therefore considered as nisin producers. Nisin production by strains was further confirmed by PCR amplification of nisA/Z of 174 bp size. The nisin activity and cell growth observed to be higher in pH controlled batch fermentation than in uncontrolled fermentation. The nisin activity, cell concentration, and acidity were high in immobilized cell system than free cell batch fermentation. The hot acid and chloroform extraction method was found to be the efficient way for the partial purification of nisin from fermented broth.     

Screening for and characterization of Lactococcus lactis bacteriophages with high thermal resistance

Fifty-six Lactococcus lactis phage isolates collected from different German dairies and obtained from a starter culture manufacturer were tested for their heat resistance. About 40% of these isolates resisted treatment at 80 °C for 5 min when they were heated in milk. The most resistant phage isolate, P1532, was collected from sour cream. Plaque-formation was still detectable even after heating at 97 °C for 5 min. The second heat-resistant one, P680, showed some plaque-forming ability after heating at 95 °C for 5 min. Kinetic parameters for the thermal inactivation of these two resistant phages were determined for temperatures ranging from 70 to 97 °C. The inactivation of phage P1532 in skim milk and in buffer medium were found to follow first-order kinetics and did not exhibit tailing, whereas in the inactivation curves of phage P680 tailing was observed. The D-value of P1532 at pasteurization temperature of 72 °C was calculated as 112 min.     

Interaction between Lactococcus lactis and Lactococcus raffinolactis during growth in milk: development of a new starter culture

Many milk fermentations use mixed cultures of lactic acid bacteria. To select a new mixed starter culture, 100 acid-producing bacterial strains were isolated from raw cow milk. Of these, 13 strains identified as belonging to the genera Lactococcus, Lactobacillus, Leuconostoc, or Weissella (based on phenotypic and genotypic tests) were assessed for a symbiotic effect between pairs of isolated strains during growth in milk. Among the strains tested, a mixed culture of Lactococcus lactis ssp. lactis strain 54 and Lactococcus raffinolactis strain 37 stimulated greater acid production during fermentation than occurred with pure fermentation. This stimulatory effect was not observed in milk supplemented with yeast extract or glucose or in constituted medium. Addition of a cell-free filtrate from milk fermented by strain 54 increased acid production by strain 37; however, the converse effect was not observed. The increased acid production by this mixed culture was, therefore, due to stimulation of strain 37 by metabolic products of strain 54, suggesting that the interaction between strains 54 and 37 is commensal. Analysis with a taste-sensing system indicated that fermented milk containing the mixed culture was more acidic, had more anionic bitterness, had greater aftertastes of anionic bitterness and astringency, and was less salty and umami than milk containing the individual cultures. This study identifies a new commensal relationship between 2 lactococcal strains that are commonly used for making dairy products.