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.     

Bacteriophage resistance in Lactococcus lactis ssp. lactis using antisense ribonucleic acid.

Antisense RNA against a conserved bacteriophage gene when expressed in a Lactococcus lactis ssp. lactis strain renders it resistant to bacteriophage infection. Two open reading frames have been identified in a L. lactis ssp. lactis bacteriophage that are conserved in a majority of isolates. They code for an 18-kDa (designated GP18C) protein and a 24-kDa (GP24C) protein, respectively, which are arranged along with previously identified open reading frames in a tandem motif similar to other bacteriophages. The presence of gp18C and gp24C in a number of bacteriophage isolates was confirmed by polymerase chain reaction using primers specific for these regions. Plasmids bearing various fragments of gp18C, gp24C, or both were constructed such that the respective open reading frames were positioned in the antisense direction relative to the Lactococcus lactis ssp. cremoris Wg2 promoter, p59. These antisense RNA-producing vectors inhibited the efficiency of plaquing of L. lactis ssp. lactis bacteriophage phi 7-9 up to 50%; the resulting plaques were extremely small and irregular in shape. The replication of the bacteriophage was severely inhibited, and the total number decreased over the first 3 h during infection in strains expressing antisense RNA compared with the host strain alone, in which the bacteriophage number increased 10(4)-fold.     

Lactococcus lactis, a bacterial model for stress responses and survival

The dairy organism, Lactococcus lactis, is continuously exposed to stress conditions generated during industrial processes. To identify the mechanisms that confer resistance to the lethal effects of oxygen and thermal stress, we isolated resistant strains by insertional mutagenesis. Mutated genes were identified and mutations were shown to confer resistance to multiple stresses (including non-selected stresses such as carbon starvation). Our results revealed that metabolic flux plays an important role in L. lactis stress response, and suggested that phosphate and guanine pools may be intracellular stress sensors. As previously shown, we also observed an increase of stress resistance during the stationary phase. We have evidence that stationary phase actually initiates very early during growth. Taken together, these data show that the stationary phase is a very complex system with multiple participants interacting altogether. These results reinforce the idea of the interdependence of stress response and the intimate relation between metabolic flux and stress responses in L. lactis.     

Changes in acid tolerance of Lactococcus lactis during growth at constant pH

Cells of Lactococcus lactis MG1363 growing in batch culture in TYG (tryptone, yeast extract, glucose) medium at constant pH 7.0 became gradually more acid sensitive shortly after inoculation until a point of maximum sensitivity was reached in early log-phase. The acid tolerance then gradually increased in the mid- and late-log phase until maximum tolerance was reached at the onset of stationary phase. This pattern has been termed the growth-phase acid tolerance. The variation in acid tolerance seen in pH 7.0 grown cells of L. lactis MG1363 did not result from changes in internal pH or membrane H+ ATPase activity levels. Neither the amount of glucose present during mid-log phase nor the amount of lactate produced by the cells correlated with the pattern of the log-phase acid tolerance. Cells grown in partially spent TYG medium showed a reduced growth rate and increased acid tolerance compared to cells grown in fresh TYG medium. Supplementing the spent medium with tryptone or yeast extract or both restored the growth rate and cells became more sensitive to acid. Fractionation of tryptone yielded a fraction which stimulated the growth of MG1363 in partially spent medium and delayed the acquisition of acid tolerance. The active compound(s) has a putative molecular weight of about 1 kDa and was partially degraded by papain and trypsin.     

Proteolytic activities,peptide utilization and oligopeptide transport systems of wild Lactococcus lactis strains

The increasing demand for tasty dairy products has raised the interest for strains of lactic acid bacteria with novel properties. In this study we have explored the proteolytic system of 24 wild Lactococcus lactis strains isolated previously from Spanish raw milk cheeses, to select proteolytic strains with high peptidase activity and efficient peptide transport capability. Large variations in overall proteolysis, proteolytic activities, as well as in peptide utilization, were recorded among strains. Peptide utilization correlated well with the presence of oligopeptide transport systems (Opp and Dpp) in wild L. lactis strains. Eighteen of the 24 wild L. lactis strains possessed both Opp and Dpp systems, what supports the theory that the presence of both oligopeptide transport systems could confer an advantage to the strain. Differences in the nucleotide sequence of genes coding for the oligopeptide binding proteins were shown by means of restriction endonuclease analyses. Based on the characteristics determined in this work, L. lactis strains ESI197, M21 and P21 seem to be promising candidates for use as components of starter cultures.     

Is thermotolerance correlated to heat-shock protein synthesis in Lactococcus lactis subsp. lactis?

Exposure of Lactococcus lactis subsp. lactis cells to a heat shock at 40 degrees C for 30 min induces thermotolerance, the increased ability of bacterial cells to survive exposure to lethal temperature (52 degrees C for 25 min). This transient state of thermal resistance is accompanied, as in Escherichia coli, by the synthesis of a new set of specific proteins termed heat-shock proteins (Hsps). Pre-treatment of the bacterial cells by antibiotics (streptomycin, spiramycin, kanamycin and erythromycin) known to act on translation, induces the major Hsps synthesis but no thermal protection; conversely, puromycin and amino acid analogues treatments, known to produce abnormal and incomplete peptides, triggers the thermotolerance state without inducing significant Hsps synthesis. These results demonstrate that heat-shock response and induced thermotolerance are not tightly correlated phenomena in L. lactis subsp. lactis.     

Continuous production of lactic acid from molasses by perfusion culture of Lactococcus lactis using a stirred ceramic membrane reactor

A perfusion culture system was used for continuous production of lactic acid by retaining cells at a high density of Lactococcus lactis in a stirred ceramic membrane reactor (SCMR). After the cell concentration increased to 248 g/l, half of the culture broth volume was replaced with the fermentation medium. Subsequently, a substrate solution containing glucose (run 1) or molasses (run 2) was continuously supplied to the cells retained in the SCMR. Simultaneously, the culture supernatant was extracted using a ceramic filter with a pore size of 0.2 mum. The dilution rate was initially set at 0.4 h(-1) and gradually decreased to 0.2 h(-1) due to reduction in the permeability of the filter. The concentration of glucose in the substrate solution was adjusted to 60 g/l for the transition and the first period until 240 h, 90 g/l for the second period from 240 h to 440 h, and 70 g/l for the third period from 440 h to 643 h. The average concentration of lactic acid in the filtrate reached 46 g/l in the first period, 43 g/l in the second period, and 33 g/l for the third period. The productivity obtained for the first period reached 15.8 g.l(-1).h(-1), twice as much as that achieved in repeated batch fermentations. Based on the results obtained in run 1, the substrate solution containing 120 g/l of molasses was continuously supplied for 240 h in run 2. The concentration and productivity of lactic acid reached 40 g/l and 10.6 g.l(-1).h(-1), respectively, by continuously replenishing the culture medium at a dilution rate of 0.26 h(-1). These results demonstrated that the filtration capacity of the SCMR was sufficient for a continuous and rapid replenishment of molasses solution from the dense cell culture and, therefore, the perfusion culture system is considered to provide a low-cost process for continuous production of lactic acid from cheap resources.     

乳酸乳球菌高效电转化的方法

以质粒pMG36e和pNZ8148为材料,对乳酸乳球ATCC19435的电转化条件进行了优化研究.实验结果表明,乳酸乳球菌的最佳电转化条件为对数生长中后期的细胞,电场强度12 kV/cm,质粒浓度0.1～1 mg/L,复苏时间2 h,此时质粒pMG36e和pNZ8148时供试菌株的电转化效率分别为1.95x105μg-1和2.18x105μg-1,比优化前电转化效率均提高10倍以上.本研究为外源基因电转化乳酸乳球菌提供了可靠的试验参数依据.     

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.     

Expression of bovine trypsin in Lactococcus lactis

Bovine trypsin is widely used in the production of bioactive peptides from milk proteins. The objective of this study was to express bovine trypsin in Lactococcus lactis to produce peptides by fermentation. The bovine trypsin with bias codon of L. lactis was synthesized, cloned into a secretory expressive vector pSEC-E7, and then introduced to L. lactis strain NZ9000 by electroporation. The expression of trypsin induced by nisin was identified by Western blot. Western blot analysis revealed a band in the protoplast fraction corresponding to SP_Usp45 (signal peptide of usp45)-trypsin. Biological activity of expressed trypsin was confirmed by the single substrate overlay assay. These results suggest that the expression of biologically active bovine trypsin has been detected in the protoplast fraction of L. lactis strain NZ9000 (pSEC:trypsin).     

Fatty acid composition of trout oil

Fatty acid analysis of oils from farmed trout of the species Oncorhynchus mykiss was carried out by gas-liquid chromatography with a flame ionisation detector (FID). Results show an influence of trout age and sex in fatty acid composition of the oils analysed. Trout oil has more docosahexaenoic acid (DHA) than eicosapentaenoic acid (EPA) and, while the EPA content does not change during growth, DHA diminishes during trout development, especially in females. In the group of medium sized trout (140–200 g), the ratios of SFA:MUFA:PUFA are similar to those recommended by the American Heart Association.     

Fatty acid composition and freeze-thaw resistance in lactobacilli

The fatty acid composition and freeze-thaw resistance of eight strains of thermophilic lactobacilli were studied. Seven of these contained the same polar and neutral lipids, the five major components making up 90% of the cellular fatty acid pool being 14:0, 16:0, 16:1, 18:1 and C19 cyclopropane (cyc19:0). Strain comparison by means of cluster analysis based on the fatty acid ratios using the overlap coefficient revealed two well defined clusters. One was formed by three strains of species Lactobacillus delbrueckii subsp. lactis and Lb. delbrueckii subsp. delbrueckii, the other included five strains of the species Lb. delbrueckii subsp. bulgaricus, Lb. acidophilus and Lb. helveticus. Resistance of strains with a high content of unsaturated fatty acids (66-70%) decreased with increasing cyc19:0 concentrations. In contrast, in strains with a low concentration of unsaturated fatty acids (42-49%), increasing cyc19:0 levels were associated with increased freeze-thaw resistance.     

Humectant permeability influences growth and compatible solute uptake by Staphylococcus aureus subjected to osmotic stress

The effects of different humectants (sodium chloride, sucrose, and glycerol) on the growth of and compatible solute (glycine betaine, proline, and carnitine) uptake by the osmotolerant foodborne pathogen Staphylococcus aureus were investigated. While growth in the presence of the impermeant humectants sodium chloride and sucrose induced the accumulation of proline and glycine betaine by cells, growth in the presence of the permeant humectant glycerol did not. When compatible solutes were omitted from low-water-activity media, growth was very poor in the presence of impermeant humectants. In contrast, the addition of compatible solutes had essentially no effect on growth when cells were grown in low-water-activity media containing glycerol as the humectant. Carnitine was found to accumulate to high intracellular levels in osmotically stressed cells when proline and glycine betaine were absent, making it a potentially important compatible solute for this organism.     

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%.     

Lactococcal 936-species phage attachment to surface of Lactococcus lactis

The interactions of the 936-species phages sk1, jj50, and 64 with the cell surface of Lactococcus lactis LM0230 were analyzed. Cell envelopes (walls + plasma membrane), cell wall, or plasma membrane from L. lactis ssp. lactis LM0230 each inactivated the phages in vitro. However, other 936-species phages kh and P008, which do not infect strain LM0230, were not inactivated by any of the subcellular fractions. Treating cell walls or plasma membrane with the cell wall hydrolase mutanolysin eliminated inactivation of phage sk1. This suggested that intact cell wall fragments were required for inactivation. A role for plasma membrane in phage sk1 inactivation was further investigated. Boiling, washing in 2 M KCl, 8 M urea, or 0.1 M Na(2)CO(3)/pH 11, or treating the plasma membrane with proteases did not reduce adsorption or inactivation of phage. Adding lipoteichoic acid or antibodies to lipoteichoic acid did not reduce inactivation of phage in a mixture with membrane, suggesting that lipoteichoic acid was not involved. Inactivation by envelopes or cell wall correlated with ejection of DNA from the phage sk1 capsid. Although calcium is required for plaque formation, it was not required for adsorption, inactivation, or ejection of phage DNA by envelopes or cell wall. The results suggest that at least for phages sk1, jj50, and 64, adsorption and phage DNA injection into the host does not require a host membrane protein or lipoteichoic acid, and that cell wall components are sufficient for these initial steps of phage infection.     

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.