Oxygen Metabolism in Lactobacillus plantarum

Lactobacillus plantarum, although able to grow in the presence of oxygen, was found to retain a completely anaerobic metabolism. Thus, L. plantarum did not consume detectable amounts of oxygen and did not contain measureable amounts of those enzyme activities which serve to protect anaerobic cells against the lethality of O(2) (-) and of H(2)O(2). Superoxide dismutase, catalase, and peroxidase appeared to be absent from these cells. L. plantarum was unusually resistant towards hyperbaric oxygen, indicating that it did not reduce oxygen even when exposed to high concentrations of this gas. A photochemical reaction mixture, known to generate O(2) (-), did kill L. plantarum. The lethality was diminished by superoxide dismutase, catalase, or mannitol and was augmented by H(2)O(2). This suggests that the lethal agent generated in the photochemical system was primarily OH., generated from the reaction of O(2) (-) with H(2)O(2).     

Oxygen utilization by Lactobacillus plantarum

Cell-free extracts of Lactobacillus plantarum contain non-proteinaceous compounds which mimic superoxide dismutase activity. Using the test system in which O ₂ ^– is generated by xanthine oxidase, superoxide dismutase activity is found in cell-free extracts, where proteins are removed by precipitation. This activity is strongly decreased after dialysis of cell-free extracts. Superoxide dismutase activity was also investigated by means of pulse radiolysis. Cell-free extracts of Escherichia coli were also investigated as a comparison, which were known to contain superoxide dismutase. With cell-free extracts of both L. plantarum and E. coli the decay of O ₂ ^– was markedly increased. However, the type of reaction of the O ₂ ^– decay was of first order in the presence of E. coli extracts due to superoxide dismutase(s), and of second order in the presence of L. plantarum extracts, indicating that O ₂ ^– elimination is not an enzymic reaction. Mn²⁺ phosphate(s) might be responsible for the observed elimination of O ₂ ^– . The production of O ₂ ^– is not detectable during NADH-, lactate- or pyruvate oxidase reactions in L. plantarum extracts.     

Citrate metabolism in Lactobacillus casei and Lactobacillus plantarum

Information on the factors influencing citrate metabolism in lactobacilli is limited and could be useful in understanding the growth of lactobacilli in ripening cheese. Citrate was not used as an energy source by either Lactobacillus casei ATCC 393 or Lact. plantarum 1919 and did not affect the growth rate when co-metabolized with glucose or galactose. In growing cells, metabolism of citrate was minimal at pH 6 but significant at pH 4·5 and was greater in cells co-metabolizing galactose than in those co-metabolizing glucose or lactose. In non-growing cells, optimum utilization of citrate also occurred at pH 4·5 and was not increased substantially by the presence of fermentable sugars. In both growing and non-growing cells, acetate and acetoin were the major products of citrate metabolism; pyruvate was also produced by non-growing cells and was transformed to acetoin once the citrate was exhausted. Citrate was metabolized more rapidly than sugar by non-growing cells; the reverse was true of growing cells. Citrate metabolism by Lact. plantarum 1919 and Lact. casei ATCC 393 increased six- and 22-fold, respectively, when the cells were pre-grown on galactose plus citrate than when pre-grown on galactose only. This was probably due to induction of citrate lyase by growth on citrate plus sugar. These results imply that lactobacilli, if present in large enough numbers, can metabolize citrate in ripening cheese in the absence of an energy source.     

Oxygen dependent lactate utilization by Lactobacillus plantarum

Lactobacillus plantarum P5 grew aerobically in rich media at the expense of lactate; no growth was observed in the absence of aeration. The oxygen-dependent growth was accompanied by the conversion of lactate to acetate which accumulated in the growth medium. Utilization of oxygen with lactate as substrate was observed in buffered suspensions of washed whole cells and in cell-free extracts. A pathway which accounts for the generation of adenosine triphosphate during aerobic metabolism of lactate to acetate via pyruvate and acetyl phosphate is proposed. Each of the enzyme activities involved, nicotinamide adenine dinucleotide independent lactic dehydrogenase, nicotinamide adenine dinucleotide dependent lactic dehydrogenase, pyruvate oxidase, acetate kinase and NADH oxidase were demonstrated in cell-free extracts. The production of pyruvate, acetyl phosphate and acetate was demonstrated using cell-free extracts and cofactors for the enzymes of the proposed pathway.Abbreviations MRS Man, Rogosa and Sharpe (1960) medium modified as in Materials and methods - TY Tryptone Yeast Extract broth - OUL Oxygen uptake with lactate as substrate - DCPIP 2,6-Dichlorophenolindophenol - LDH Lactic dehydrogenase     

Manganese and Defenses against Oxygen Toxicity in Lactobacillus plantarum

Lactobacillus plantarum is aerotolerant during log-phase growth on glucose, but is an obligate aerobe on polyols. Respiration was cyanide resistant and under certain conditions was associated with the accumulation of millimolar concentrations of H(2)O(2). On glucose, optimal growth was observed in the absence of O(2). Extracts of L. plantarum did not catalyze the reduction of paraquat by reduced nicotinamide adenine dinucleotide, but plumbagin (5-hydroxy-2-methyl-1,4-naphthoquinone) was readily reduced. Such extracts produced O(2) (-) in the presence of NADH plus plumbagin. Plumbagin caused a 10-fold increase in the rate of respiration of intact cells in the presence of glucose and also imposed a loss of viability which was dependent upon both glucose and O(2). Although extracts of L. plantarum were devoid of true superoxide dismutase activity, this organism was comparable to superoxide dismutase-containing species in its resistance toward hyperbaric O(2) and toward the oxygen-dependent lethality of plumbagin. L. plantarum required Mn-rich media and actively accumulated Mn(II). Soluble extracts were found to contain approximately 9 mug of Mn per mg of protein and 75 to 90% of this Mn was dialyzable. Such extracts exhibited a dialyzable and ethylenediaminetetraacetic acid-inhibitable ability to scavenge O(2) (-). This O(2) (-)-scavenging activity was due to the dialyzable Mn(II) present in these extracts and could be mimicked by MnCl(2). Cells grown in Mn-rich media were enriched in dialyzable Mn and were more resistant toward oxygen toxicity and toward the oxygen-dependent plumbagin toxicity than were cells grown in Mn-deficient media. L. plantarum exhibited no nutritional requirement for iron and little or no iron was present in these cells, even when they were grown in iron-rich media. L. plantarum thus appears to use millimolar levels of Mn(II) to scavenge O(2) (-), much as most other organisms use micromolar levels of superoxide dismutases.     

Plasmid profiles of ten strains of Lactobacillus plantarum

Abstract The presence of extrachromosomal DNA elements has been investigated in 10 strains of Lactobacillus plantarum .
8 of the strains contained from 1 to 6 plasmids of different M _r values spanning from 1.35 · 10⁶ to 15.4 · 10⁶.
6 of the strains are commonly used as starter cultures in dry sausage and all these strains contained plasmids. The remaining 4 strains were obtained from the American Type Culture Collection and only 2 of these strains were found to harbour plasmids.     

Polyphasic investigation of the diversity within Lactobacillus plantarum related strains revealed two L. plantarum subgroups

The diversity of 140 strains related to Lactobacillus plantarum was investigated using a polyphasic approach combining two molecular techniques: randomly amplified polymorphic DNA fingerprinting (RAPD) and Southern hybridisation with a pyr probe on BglI digests of chromosomal DNA, as well as phenotypic characterization. The RAPD technique allowed us to classify a subset of 60 representative strains into four groups. One group belonged to Lactobacillus paraplantarum, the second to Lactobacillus pentosus and the two remaining groups to L. plantarum (G(L)p1 and G(L)p2). The Southern hybridisation technique (F. Bringel, M.-C. Curk and J.-C. Hubert, Int. J. Syst. Bacteriol. 46: 588-594, 1996) revealed nine groups of profiles (I to IX). Results indicated an excellent convergence between RAPD and hybridisation classifications for more than 93% (56/60) of the strains studied. When we compared the fermentation patterns of the L. plantarum strains, three differences were found. Melezitose fermentation was not fermented by the G(L)p2 RAPD group, unlike the G(L)p1 RAPD group which included L. plantarum type strain NCIMB11974T. Second, alpha-methyl-D-mannoside was fermented by a majority of the strains of the G(L)p1 RAPD group but by none of the strains in the G(L)p2 RAPD group. Third, dulcitol was catabolized by nearly half of the strains of the G(L)p2 RAPD group but by none of the strains in the G(L)p1 RAPD group. Molecular diversity within L. plantarum was confirmed using Southern profiles, PCR amplification and subsequent sequencing of these PCR products. A 773 bp sequence overlapping the pyrDF genes showed high homology: at least 97% identical in L. plantarum strains (V to IX) and 99.9% identical in hybridisation groups VII and VIII. The same G-T transversion which destroyed the pyrF BglI site was found in 11 strains (hybridisation groups VI, VII and VIII). DNA rearrangements were identified downstream from the pyr genes, by PCR amplification and Southern hybridisation profile analysis in three strains of hybridisation groups VIII and IX, two of which also harboured the G-T transversion.     

Characterization of wine Lactobacillus plantarum by PCR-DGGE and RAPD-PCR analysis and identification of Lactobacillus plantarum strains able to degrade arginine

Summary Screening of strains isolated from red wine undergoing malolactic fermentation allowed the identification of lactic acid bacteria able to degrade arginine. A denaturing gradient gel electrophoresis approach, using the rpoB gene as the molecular target, was developed in order to characterize the isolated strains. Several strains were identified as Lactobacillus plantarum and were typed by RAPD-PCR with several randomly designed primers. Almost all of the␣L. plantarum strains identified were able to produce citrulline and ammonia, suggesting that the ability of␣L.␣plantarum to degrade arginine is a common feature in wine. During the characterization of the newly identified L.␣plantarum strains, the presence of genes coding for the arginine deiminase (ADI) pathway was observed in the strains able to produce citrulline, while the lack of this genes was observed in strain unable to produce citrulline. These results suggest that the degradation of arginine in L. plantarum is probably strain-dependent.     

Effect of sodium chloride on metabolism of two strains of Lactobacillus plantarum isolated from fermenting green olives

Metabolism of two strains of Lactobacillus plantarum isolated from fermenting olive brines has been compared. One strain (221) produces a bacteriocin, the other (H4) does not. Experiments showed that the non-producing strain (H4) was more salt tolerant than the bacteriocin producer, and was also able to utilize a wider range of metabolic pathways. Particularly noticeable was the inability of the producing strain to use, in aerobic conditions, the lactate which accumulated during glucose metabolism. Both strains showed similar behaviour on prolonged incubation in anaerobic media in the presence and absence of salt.     

Determining potential probiotic properties of human originated Lactobacillus plantarum strains

In this study, twenty Lactobacillus plantarum strains which were isolated from the fecal samples of humans were investigated in vitro for their characteristics as potential new probiotic strains. The L. plantarum strains were examined for resistance to gastric acidity in simulated gastric juice at pH 2.0, 2.5, 3.0, and 3.5. The growth of test cultures with different pH was monitored after 0, 10, 30, 60, 90, and 120 min of incubation using a spectrophotometer at 550 nm. At the same time, samples were serially diluted in sterile PBS, and counts of viable bacteria were determined by plate counts using MRS agar for each pH and time parameter. The strains were also examined for resistance to 0.4% phenol, production of H₂O₂, adhesion to Caco-2 cell line and antimicrobial activity. It was determined that the artificial gastric juice, even at pH 2.0, did not significantly change the viability of the cultures. Except L. plantarum AA1-2, all strains were detected at 8 ～ 9 log₁₀ CFU/g. It was found that all L. plantarum strains showed good resistance to 0.4% phenol, and only one strain (AC18-82) produced H₂O₂. Good adhesion of L. plantarum strains to Caco-2 cells was observed in this experiment. These selected strains also showed antimicrobial activity.     

Citrate metabolism by Lactobacillus plantarum isolated from orange juice

The behaviour of Strains of Lactobacillus plantarum isolated from fermented orange juice and Lact. plantarum DSM 20174 was studied in the presence of citrate. When used as sole carbon source, citrate scarcely supported the growth of the bacteria. It was shown to enhance the growth of Lact. plantarum in glucose media. Under acid conditions (pH 4·0–5·0), 1 mol of citrate yielded 1·7 mol of acetate as sole major final metabolite with release of CO₂ in the gas phase.     

Physiological role of pyruvate oxidase in the aerobic metabolism of Lactobacillus plantarum.

Under aerobic growth conditions Lactobacillus plantarum produced acetic acid in addition to lactic acid. It was found that lactic acid was predominantly produced at first, and then when the carbohydrate was nearly exhausted, lactic acid was metabolized further to acetic acid. The most likely enzyme involved in the aerobic metabolism of L. plantarum is pyruvate oxidase. Its activity is enhanced in the presence of oxygen and is reduced in the presence of glucose. The specific activity of pyruvate oxidase is highest at the beginning of the stationary-growth phase, where a strong increase in acetic acid production was also observed.     

Effect of inhibition of protein synthesis on lipid metabolism in Lactobacillus plantarum.

In Lactobacillus plantarum 17-5, lipid synthesis appears to be correlated with protein synthesis. Inhibition of protein synthesis by chloramphenicol (50 mug/ml) caused the nearly simultaneous inhibition of incorporation of radioactive oleic acid into polar lipids before the cessation of growth. In addition, de novo fatty acid synthesis, as determined by the incorporation of radioactive acetate into cellular lipids, was also inhibited. Removal of the antibiotic resulted in the resumption of growth, protein synthesis, and polar lipid synthesis. Inhibition of protein synthesis by leucine deprivation also produced a marked reduction in the incorporation of radioactive oleic acid into the total polar lipids at about the same time that growth stopped (30 to 60 min after the removal of leucine). However, the different classes of lipids behaved differently. For example, the incorporation of oleic acid into cardiolipin was inhibited immediately upon removal of leucine from the cultures, whereas incorporation into phosphatidyl-glycerol was maintained at near normal rates for 60 min after the removal of leucine and then ceased. In contrast, the accumulation of radioactive oleic acid in a neutral lipid identified as diglyceride occurred to a much greater extent in leucine-deprived cultures than in control (+ leucine) cultures. Upon addition of leucine to leucine-deprived cultures, the rates of synthesis of phosphatidyl-glycerol and cardiolipin returned to normal; the amount of radioactivity in the diglyceride fraction decreased to normal levels concomitantly with increased phospholipid synthesis.     

Aerobic metabolism and oxidative stress tolerance in the Lactobacillus plantarum group

Aerobic metabolism and response to oxidative stress and starvation were studied in 11 Lactobacillus plantarum, L. paraplantarum and L. pentosus strains in order to assess the impact of aerobic metabolism on the growth and on the stress response. The strains were grown in aerobiosis without supplementation (AE), with hemin (AEH) or with hemin and menaquinone (AEHM) supplementation and in anaerobiosis (AN) in a complex buffered substrate. Growth rate, biomass yield, glucose and O₂ consumption, production of lactic acid and H₂O₂, catalase activity, oxidative and starvation stress tolerance were evaluated. Aerobic growth increased biomass yield in late stationary phase. Further increase in yield was obtained with both hemin (H) and menaquinone (M) addition. With few exceptions, the increase in biomass correlated with the decrease of lactic acid which, however, decreased in anaerobic conditions as well in some strains. Addition of H or H + M increased growth rate for some strains but reduced the duration of the lag phase. H₂O₂ production was found only for aerobic growth with no supplementation due to catalase production when hemin was supplemented. To our knowledge this is the first study in which the advantages of aerobic growth with H or H + M in improving tolerance of oxidative stress and long-term survival is demonstrated on several strains of the L. plantarum group. The results may have significant technological consequences for both starter and probiotic production.     

Comparative studies of the degradation of grass fructan and inulin by strains of Lactobacillus paracasei subsp. paracasei and Lactobacillus plantarum

Four strains of Lactobacillus paracasei subsp. paracasei and Lact. plantarum are investigated within 16 d in order to determine the formation of metabolites during the degradation of grass fructan and inulin as well as the subsequent fermentation to lactic acid. The decrease of the total content of fructans throughout the entire time of investigation shows differences specific for strains as for either fructan substrate. The strain Lact. plantarum V 54/6 completely degrades the grass fructan and inulin within no longer than 13 d. The utilization of fructan by the other strains is temporally delayed, and in a smaller degree of degradation, especially remarkable for inulin cleavage. The structural modifications of decomposed fructans are characterized by a noticeable shift of the mean DP from approximately 80 to the oligomeric range analysed by anion exchange chromatography. Additionally, a newly formed series of peaks of oligomeric saccharides was detected during the degradation of grass fructan and inulin. Part of the fructose that is derived from cleavage of fructans is fermented immediately by the LAB strains into differently high amounts of lactic acid. The abundance of formed fructose is enriched in the medium to a varying extent, depending on the strain as well as the substrate used. From these results a number of fructan degradative enzymes in lactobacilli have been concluded to possibly vary their modes of regulation: strain specific exo- and endohydrolases with different activities against β-2,1 and β-2,6 linked fructan.     

Technological and molecular diversity of Lactobacillus plantarum strains isolated from naturally fermented sourdoughs

Thirty Lactobacillus (L.) plantarum strains, isolated from sourdough, were identified by biochemical tests as well as 16S rDNA sequencing and differentiated on the basis of technological properties, such as amylase, protease, phytase and antirope activities. These properties were shown to be widely differing among the strains, indicating a significant technological diversity. Genetic differentiation was achieved by restriction endonuclease analysis-pulsed field gel electrophoresis (REA-PFGE) that allowed the L. plantarum strains to be divided into 10 different genomic groups. Moreover, 32 different starters were employed in dough making experiments; each starter consisted of a single strain of L. plantarum associated with a maltose positive or a maltose negative yeast. The technological properties of the doughs were greatly influenced by the type of strain included in the starter. The time of leavening and the acidification activities detected in the dough were enhanced by the presence of L. plantarum strains. The bacterial and yeast contents and fermentation properties were statistically treated by principal component analysis (PCA), which allowed the discrimination of different typologies of dough. The study of the peculiar characteristics of different strains of L. plantarum is fundamental for a better understanding of their potential in affecting the nutritional value, quality and stability of the baked goods. L. plantarum strains are able to differentially influence the dough quality when employed as starters.     

Plasmid profiles and curing of plasmids in Lactobacillus plantarum strains isolated from green olive fermentations.

Plasmid profiles of 35 Lactobacillus plantarum strains isolated from different green olive fermentors were obtained. A large number of plasmids in the CCC form (from 5 to 16) were present in all the tested strains as confirmed by a second dimension electrophoresis of DNA. These plasmids, all of which remain cryptic, ranged from 2.0 to 68 kb in size. Novobiocin, sodium dodecyl sulphate and ethidium bromide were used as plasmid-curing agents but only novobiocin induced loss of extrachromosomal DNA at a high frequency in these strains.