A combined model to predict the functionality of the bacteriocin-producing Lactobacillus sakei strain CTC 494

The use of bacteriocin-producing lactic acid bacteria for improved food fermentation processes seems promising. However, lack of fundamental knowledge about the functionality of bacteriocin-producing strains under food fermentation conditions hampers their industrial use. Predictive microbiology or a mathematical estimation of microbial behavior in food ecosystems may help to overcome this problem. In this study, a combined model was developed that was able to estimate, from a given initial situation of temperature, pH, and nutrient availability, the growth and self-inhibition dynamics of a bacteriocin-producing Lactobacillus sakei CTC 494 culture in (modified) MRS broth. Moreover, the drop in pH induced by lactic acid production and the bacteriocin activity toward Listeria as an indicator organism were modeled. Self-inhibition was due to the depletion of nutrients as well as to the production of lactic acid. Lactic acid production resulted in a pH drop, an accumulation of toxic undissociated lactic acid molecules, and a shift in the dissociation degree of the growth-inhibiting buffer components. The model was validated experimentally.     

The pentose moiety of adenosine and inosine is an important energy source for the fermented-meat starter culture Lactobacillus sakei CTC 494

The genome sequence of Lactobacillus sakei 23K has revealed that the species L. sakei harbors several genes involved in the catabolism of energy sources other than glucose in meat, such as glycerol, arginine, and nucleosides. In this study, a screening of 15 L. sakei strains revealed that arginine, inosine, and adenosine could be used as energy sources by all strains. However, no glycerol catabolism occurred in any of the L. sakei strains tested. A detailed kinetic analysis of inosine and adenosine catabolism in the presence of arginine by L. sakei CTC 494, a fermented-meat starter culture, was performed. It showed that nucleoside catabolism occurred as a mixed-acid fermentation in a pH range (pH 5.0 to 6.5) relevant for sausage fermentation. This resulted in the production of a mixture of acetic acid, formic acid, and ethanol from ribose, while the nucleobase (hypoxanthine and adenine in the case of fermentations with inosine and adenosine, respectively) was excreted into the medium stoichiometrically. This indicates that adenosine deaminase activity did not take place. The ratios of the different fermentation end products did not vary with environmental pH, except for the fermentation with inosine at pH 5.0, where lactic acid was produced too. In all cases, no other carbon-containing metabolites were found; carbon dioxide was derived only from arginine catabolism. Arginine was cometabolized in all cases and resulted in the production of both citrulline and ornithine. Based on these results, a pathway for inosine and adenosine catabolism in L. sakei CTC 494 was presented, whereby both nucleosides are directly converted into their nucleobase and ribose, the latter entering the heterolactate pathway. The present study revealed that the pentose moiety (ribose) of the nucleosides inosine and adenosine is an effective fermentable substrate for L. sakei. Thus, the ability to use these energy sources offers a competitive advantage for this species in a meat environment.     

Effects of sodium acetate on the production of stereoisomers of lactic acid by Lactobacillus sakei and other lactic acid bacteria

Lactobacillus sakei and other lactic acid bacteria were studied on the change of the type of stereoisomers (the ratio of L-form to D-form) of lactic acid produced in the presence of sodium acetate and under other cultural conditions. Of 49 strains tested, only L. sakei NRIC 1071(T) and L. coryniformis subsp. coryniformis NRIC 1638(T) changed the type in the presence of 50 mm sodium acetate compared with the absence of sodium acetate. The type produced by L. sakei NRIC 1071(T) was shifted 30% or more from the DL-type to the L-type in the presence of 50 mm sodium acetate. L. sakei NRIC 1071(T) produced not only twice or more the amount of L-lactic acid but decreased the amount of D-lactic acid compared with the absence of sodium acetate. The shift of the DL-type to the L-type by L. sakei is due to the high production of L-lactic acid and the low production of D-lactic acid. The type of stereoisomers produced by 11 L. sakei strains was also shifted from the DL-type to the L-type in the presence of 50 mm sodium acetate. The shift of stereoisomers by the majority of L. sakei strains seems interesting from the viewpoint of the delineation of this species.     

Anti-bacterial activity of Lactobacillus plantarum strain SK1 against Listeria monocytogenes is due to lactic acid production

AIMS: The aim of this research was to investigate the potential of Lactobacillus plantarum strain SK1 for use as a biological control agent against Listeria monocytogenes and determine its mechanism of anti-listerial activity. METHODS AND RESULTS: Co-growth of Lact. plantarum SK1 and L. monocytogenes UMCC98 in MRS broth showed that anti-listerial activity of Lact. plantarum SK1 occurred during late log/early stationary phase of growth. This coincided with a reduction in broth pH to 4.26. Evidence obtained from the analysis of cell-free culture filtrates of strain SK1 grown in MRS broth using thin-layer chromatography and growth of L. monocytogenes in pH-adjusted culture filtrates suggested that the anti-listerial activity was due to lactic acid production alone. Trials of Lact. plantarum SK1 on radishes stored at 5 degrees C showed that it had statistically significant (P < 0.05) anti-listerial activity. CONCLUSIONS: The anti-listerial activity of Lact. plantarum SK1 was due to lactic acid production alone. A small-scale trial on radishes stored at 5 degrees C showed it to have significant anti-listerial activity in planta. SIGNIFICANCE AND IMPACT OF THE STUDY: This organism has potential as a biological control agent for L. monocytogenes.     

In situ activity of a bacteriocin-producing Lactococcus lactis strain. Influence on the interactions between lactic acid bacteria during sourdough fermentation

AIMS: To biochemically characterize the bacteriocin produced by Lactococcus lactis ssp. lactis M30 and demonstrate its effect on lactic acid bacteria (LAB) during sourdough propagation. METHODS AND RESULTS: A two-peptide bacteriocin produced by L. lactis ssp. lactis M30 was purified by ion exchange, hydrophobic interaction and reversed phase chromatography. Mass spectrometry of the two peptides and sequence analysis of the ltnA2 gene showed that the bacteriocin was almost identical to lacticin 3147. During a 20-day period of sourdough propagation the stability of L. lactis M30 was demonstrated, with concomitant inhibition of the indicator strain Lactobacillus plantarum 20, as well as the non-interference with the growth of the starter strain Lact. sanfranciscensis CB1. CONCLUSIONS: In situ active bacteriocins influence the microbial consortium of sourdough LAB and can "support" the dominance of insensitive strains during sourdough fermentation. SIGNIFICANCE AND IMPACT OF THE STUDY: The in situ bacteriocinogenic activity of selected lactococci enables the persistence of insensitive Lact. sanfranciscensis strains, useful to confer good characteristics to the dough, at a higher cell concentration with respect to other LAB of the same ecosystem.     

一株功能性乳酸菌对胃肠道环境耐受能力的测定

目的对1株具有降胆固醇功能的乳酸菌进行胃肠道环境耐受能力的测定。方法分别测定菌株对胃内酸性和胃蛋白酶的耐受能力以及对小肠内胆盐和胰蛋白酶的耐受能力。结果该菌株对胃肠道有良好的耐受能力。结论本研究为后期菌株在动物及人体内发挥其功能性奠定了实验基础。     

The effect of sodium acetate on the activity of L- and D-lactate dehydrogenases in Lactobacillus sakei NRIC 1071(T) and other lactic acid bacteria

The effect of sodium acetate on the production of stereoisomers of lactic acid produced by Lactobacillus sakei NRIC 1071(T) and other lactic acid bacteria was studied. L. sakei NRIC 1071(T) started producing L-lactic acid at the early logarithmic phase and d-lactic acid at the late logarithmic phase. The activity of L-lactate dehydrogenase [EC 1.1.1.27, L-LDH] from the resting cells of L. sakei NRIC 1071(T) appeared at the early stage of the logarithmic phase during the growth, and the activity of D-lactate dehydrogenase [EC 1.1.1.28, D-LDH] at the late stage of the logarithmic phase. The resting cells and cell-free extracts of L. sakei NRIC 1071(T) did not produce DL-lactic acid from L- or D-lactic acid. Stained bands of L-LDH and D-LDH appeared in the cell-free extracts from the cells of L. sakei NRIC 1071(T). Consequently, L. sakei conclusively produced L- and D-lactic acid by the action of L-LDH and D-LDH. This finding leads to the conclusion that lactate racemase [EC 5.1.2.1] does not exist in this strain. When the specific activity of LDHs (the total activity of L-LDH plus D-LDH) from the cells cultivated in the presence of sodium acetate is compared with that cultivated in its absence, the ratio of the activity between the cells cultivated in the former condition and those in the latter fell from 1.7 on the cell-free extracts to 1.3 on the preparation of the QAE-Toyopearl 550c chromatography. This result indicates that the amount of LDHs in the cells of L. sake NRIC 1071(T) cultivated in the presence of 50 mM sodium acetate was much more than that in the cells cultivated in the absence of sodium acetate. The shift of the type of stereoisomers of lactic acid from the DL-type to the L-type is discussed in the case of L. sakei strains.     

LysA2, the Lactobacillus casei bacteriophage A2 lysin is an endopeptidase active on a wide spectrum of lactic acid bacteria

The lysin gene (lysA2) of the Lactobacillus casei bacteriophage A2 was cloned and expressed in Escherichia coli. LysA2 is an endopeptidase that hydrolyzes the bond between the terminal d-alanine of the peptidoglycan tetrapeptide and the aspartic acid residue that forms the bridge with the l-lysine of a neighboring peptidoglycan chain, characteristic of Gram-positive bacteria included into the A4 peptidoglycan subgroup. This includes most lactobacilli, Lactococcus lactis, Pediococcus acidilactici, and Pediococcus pentosaceus, the walls of all of which were substrates for the enzyme. Specific binding of LysA2 to the wall of these bacteria is mediated by its C-terminal moiety, does not need the N-terminal catalytic domain for recognition, and is stable: at least 88% of the molecules were still bound to L. casei after 3 days in phosphate buffer at 4°C. The enzyme acts as a monomer, is active at pH values between 4 and 6, and at temperatures ranging between 18°C and 50°C while being independent of divalent cation addition. The enzyme showed strong resistance to incubation at high and low pH values but became progressively inactivated at 50°C and above. LysA2 is bactericidal, the viability of L. casei cultures dropping to 1% in 10 min, under the standard conditions used for the enzymatic assay.     

Use of virginiamycin to control the growth of lactic acid bacteria during alcohol fermentation

The antibiotic virginiamycin was investigated for its effects on growth and lactic acid production by seven strains of lactobacilli during the alcoholic fermentation of wheat mash by yeast. The lowest concentration of virginiamycin tested (0.5 mg Lactrol ^TMkg⁻¹ mash), was effective against most of the lactic acid bacteria under study, but Lactobacillus plantarum was not significantly inhibited at this concentration. The use of virginiamycin prevented or reduced potential yield losses of up to 11% of the produced ethanol due to the growth and metabolism of lactobacilli. However, when the same concentration of virginiamycin was added to mash not inoculated with yeast, Lactobacillus rhamnosus and L. paracasei grew after an extensive lag of 48 h and L. plantarum grew after a similar lag even in the presence of 2 mg virginiamycin kg⁻¹ mash. Results showed a variation in sensitivity to virginiamycin between the different strains tested and also a possible reduction in effectiveness of virginiamycin over prolonged incubation in wheat mash, especially in the absence of yeast. Received 05 August 1996/ Accepted in revised form 18 December 1996     

The ratio of L-form to D-form of lactic acid as a criteria for the identification of lactic acid bacteria

Stereoisomers of lactic acid produced by lactic acid bacteria were determined by HPLC by using an enantiomeric resolution column. In general, the ratios of L-form to D-form (the type of stereoisomer) obtained were compared with those in references. Values of the type of stereoisomer of lactic acid were discussed from the viewpoint of identification of lactic acid bacteria.     

Addition of a surfactant to tryptic soy broth allows growth of a lactic acid bacteria food antimicrobial, Escherichia coli O157:H7, and Salmonella enterica

Aims: This study aimed to determine the survival and growth of Escherichia coli O157:H7 and Salmonella enterica subsp. enterica in a medium supporting the growth of a Lactic Acid Bacteria (LAB) food antimicrobial culture. Methods and Results: Foodborne pathogens and LAB were cultured individually in tryptic soy broth (TSB), tryptic soy broth supplemented with one g l^?1 Tween 80^® (TSB‐T80), and de Man, Rogosa and Sharpe (MRS) broth. Growth of E. coli O157:H7 and Salmonella was similar in TSB and TSB‐T80 but was significantly less in MRS. Conversely, LAB growth was similar in MRS and TSB‐T80 but was significantly less in TSB. Conclusions: Supplementation of TSB with Tween 80^® allows growth of LAB to levels similar to that observed with MRS but does not inhibit the growth of E. coli O157:H7 and Salmonella. We present the formulation of a medium useful in studies useful for evaluating competitive inhibition of foodborne pathogens by LAB in vitro. Significance and Impact of the Study: This study reports the utility of TSB‐T80 for the completion of in vitro competitive inhibition assays incorporating a Lactic Acid Bacteria food safety culture.     

Lactobacillus ruminis is a predominant lactic acid producing bacterium in the caecum and rectum of the pig

AIMS: To identify the predominant lactic acid producing bacteria in the small intestine, caecum and the rectum of the healthy pig. METHODS AND RESULTS: Samples obtained from the large intestine of healthy pigs post-mortem were cultured using a modified agar-MRS medium in roll tubes. Thirteen isolates were selected on the basis of their morphological characteristics and Gram stain reaction for gene sequencing. These isolates were characterized by DNA sequence analysis of 16S rDNA. Eight isolates were identified as Lactobacillus ruminis, two as Enterococcus faecium, one as Mitsuokella multiacidus and two as Escherichia coli. CONCLUSION: This is the first report of Lact. ruminis as the dominant lactic acid bacteria in the large intestine of the pig. SIGNIFICANCE AND IMPACT OF THE STUDY: The results suggest that Lact. ruminis is a dominant bacterium in the large intestine of the healthy pig. Future work should focus on the role of this bacterium in relation to the physiological function of the intestine and the health of the animal.     

Growth and arginine metabolism of the wine lactic acid bacteria Lactobacillus buchneri and Oenococcus oeni at different pH values and arginine concentrations

During malolactic fermentation (MLF) in grape must and wine, heterofermentative lactic acid bacteria may degrade arginine, leading to the formation of ammonia and citrulline, among other substances. This is of concern because ammonia increases the pH and thus the risk of growth by spoilage bacteria, and citrulline is a precursor to the formation of carcinogenic ethyl carbamate (EC). Arginine metabolism and growth of Lactobacillus buchneri CUC-3 and Oenococcus oeni strains MCW and Lo111 in wine were investigated. In contrast to L. buchneri CUC-3, both oenococci required a higher minimum pH for arginine degradation, and arginine utilization was delayed relative to the degradation of malic acid, the main aim of MLF. This allows the control of pH increase and citrulline formation from arginine metabolism by carrying out MLF with pure oenococcal cultures and inhibiting cell metabolism after malic acid depletion. MLF by arginine-degrading lactobacilli should be discouraged because arginine degradation may lead to the enhanced formation of acids from sugar degradation. A linear relationship was found between arginine degradation and citrulline excretion rates. From this data, strain-specific arginine-to-citrulline conversion ratios were calculated that ranged between 2.2 and 3.9% (wt/wt), and these ratios can be used to estimate the contribution of citrulline to the EC precursor pool from a given amount of initial arginine. Increasing arginine concentrations led to higher rates of growth of L. buchneri CUC-3 but did not increase the growth yield of either oenococcus. These results suggest the use of non-arginine-degrading oenococci for inducing MLF.     

Anti-proliferative effect of two lactic acid bacteria strains of human origin on the growth of a myeloma cell line

AIMS: Twenty lactic acid bacteria strains were isolated from human faeces and tested by MTT assay for stimulation or inhibition of the proliferation of Vero and myeloma cells. METHODS AND RESULTS: None of the strains significantly affected the proliferation of Vero cells. However, two isolates (HN1 and HA8) showed a strong inhibition of myeloma cell proliferation (16.7 and 5.0%, respectively) by MTT assay. CONCLUSION: Both strains have an anti-proliferative effect on a tumoral cell line. SIGNIFICANCE AND IMPACT OF THE STUDY: The beneficial effect of LAB cancer therapy has been linked to their ability for immunomodulation.     

Cytokine secretion by stimulated monocytes depends on the growth phase and heat treatment of bacteria: a comparative study between lactic acid bacteria and invasive pathogens

The consumption of food containing lactic acid bacteria (LAB) has been shown to exert immunomodulatory effects in humans. The specific cellular interaction of these bacteria with immuno-competent cells has not yet been fully understood. Since the TNF-alpha secretion of stimulated monocytes is an important initial response to a bacterial challenge, we investigated the potential of LAB originating from the human intestine or fermented food in comparison to the effect of invasive pathogens. The challenge of monocytes with three LAB strains, Listeria monocytogenes or enterohaemorrhagic Escherichia coli (EHEC) elicited a strain specific, dose-dependent biphasic TNF-alpha secretion. The concentration (EDmax) of bacteria or bacterial cell wall components necessary to induce maximal TNF-alpha secretion (TNFmax) by monocytes was mathematically approximated. It was shown for exponentially growing LAB strains that the maximal TNF-alpha secretion (TNFmax) was stronger (57 to 78%) upon stimulation with living bacteria than with heat killed cells. In contrast to log-phase bacteria, the maximal TNF-alpha secretion of monocytes (TNFmax) was higher (15 to 55%) after the stimulation with heat killed, stationary-phase bacteria when compared to that of live LAB. Thus, monocyte stimulation was clearly affected by the growth phase of bacteria. Purified cell walls of LAB strains revealed only a limited potential for monocyte stimulation. LPS exhibited a higher capacity to stimulate monocytes than purified gram positive cell walls or muramyldipeptide. In comparison to pathogenic bacteria, the maximal secretory TNF-alpha response (TNFmax) was up to 2 fold higher with LAB strains. In general, the amount of bacteria (EDmax) necessary to induce maximal TNF-alpha secretion (TNFmax) was approximately 1 to 3 log higher for heat killed bacteria when compared to live bacterial cells illustrating the significant lower potential of heat killed bacteria to activate monocytes.