Citric acid metabolism in hetero- and homofermentative lactic acid bacteria.

The effect of citrate on production of diacetyl and acetoin by four strains each of heterofermentative and homofermentative lactic acid bacteria capable of utilizing citrate was studied. Acetoin was quantitatively the more important compound. The heterofermentative bacteria produced no acetoin or diacetyl in the absence of citrate, and two strains produced traces of acetoin in its presence. Citrate stimulated the growth rate of the heterofermentative lactobacilli. Acidification of all heterofermentative cultures with citric acid resulted in acetoin production. Destruction of accumulated acetoin appeared to coincide with the disappearance of citrate. All homofermentative bacteria produced more acetoin and diacetyl in the presence of citrate than in its absence. Citrate utilization was begun immediately by the streptococci but was delayed until at least the middle of the exponential phase in the case of the lactobacilli.     

A survey of lactic acid bacteria in Italian silage

G razia , L. & S uzzi , G. 1984. A survey of lactic acid bacteria in Italian silage. Journal of Applied Bacteriology 56 , 373–379.
Lactic acid bacteria, isolated from Italian ensiled products, were represented by strains of the genera Lactobacillus and Leuconostoc . The predominant strains were heterofermentative lactobacilli, with Lactobacillus buchneri being the most frequent. Among homofermentative lactic acid bacteria, strains of Lact. plantarum and Lact. casei were recovered. Almost all strains utilized malic acid and showed good acid-tolerance, but only some of them were able to metabolize malic acid at extremely low pH; these were five homofermentative lactobacilli (4 Lact. plantarum and 1 Lacr. casei var. casei ) and two heterofermentative lactobacilli ( Lact. cellobiosus and Lactobacillus sp.).     

The aerobic growth and product formation of Lactobacillus,Leuconostoc, Brochothrix,and Carnobacterium in batch cultures

Summary The aerobic growth and metabolism of eleven homofermentative and three heterofermentative Lactobacillus strains, three Leuconostoc strains, two Brochothrix thermosphacta strains and two Carnobacterium strains were studied in batch cultures at pH 6.0 and 25°C on a complex substrate containing 10.0 g glucose per litre. All strains, except Carnobacterium divergens 69, grew well aerobically. An oxygen consumption was registered for 18 of the strains—the exceptions being Lactobacillus alimentarius DSM 20249^T, Lactobacillus farciminis DSM 20284^T and Lactobacillus sharpeae DSM 20505^T. The homofermentative lactobacilli showed a maximal oxygen consumption during the stationary growth phase and this was coupled with a low final viable count. Leuconostoc strains, heterofermentative lactobacilli, Brochothrix thermosphacta and Carnobacterium strains showed a maximal oxygen consumption during the exponential growth phase together with a high final viable count. The maximum specific growth rate varied from 0.19 to 0.54 h^-1 while the growth yield varied from 19 to 86 g dry weight per mol glucose consumed. In general, homofermentative lactobacilli produced dl-lactic acid, acetic acid and acetoin. The three heterofermentative lactobacilli produced dl-lactic acid and acetic acid, two strains also produced ethanol Leuconostoc spp. formed d-lactic acid, acetic acid, and ethanol. B. thermosphacta produced acetoin, acetic acid, formic acid, isobutyric acid and isovaleric acid but no lactic acid. Carnobacterium produced l-lactic acid, acetic acid and acetoin. All strains accumulated hydrogen peroxide except L. alimentarius DSM 20249^T, Carnobacterium piscicola 3 and B. thermosphacta.née Blickstad     

Diacetyl, Acetoin, and Acetaldehyde Production by Mixed-Species Lactic Starter Cultures

Citrate utilization and acetoin, diacetyl, acetaldehyde, and lactic acid production in milk at 21 C by five different mixed-strain starters, containing Streptococcus diacetilactis (D type), Leuconostoc (B type), and S. diacetilactis and Leuconostoc (BD type), were measured. BD and D cultures utilized citrate more rapidly and produced more diacetyl, acetoin, and acetaldehyde than B types. All cultures produced much more acetoin than diacetyl, with the BD and D cultures producing four to five times larger amounts of acetoin than the B cultures. Reduction of diacetyl and acetoin toward the end of the normal incubation period was characteristic of BD and D cultures, whereas a similar reduction of acetaldehyde was characteristic of BD and especially of B cultures. Continued incubation of B cultures beyond 17 h also resulted in reduction of diacetyl and acetoin. Addition of citrate to the milk retarded diacetyl and acetoin reduction. Mn²⁺ had no effect on diacetyl production by a BD culture but increased citrate utilization and, as a consequence, caused greater diacetyl destruction in one of the B cultures.     

Citrate utilization by homo- and heterofermentative lactobacilli

Citrate utilization by several homo- and heterofermentative lactobacilli was determined in Kempler and McKay and in calcium citrate media. The last medium with glucose permitted best to distinguish citrate-fermenting lactobacilli. Lactobacillus rhamnosus ATCC 11443, Lactobacillus zeae ATCC 15820 and Lactobacillus plantarum ATCC 8014 used citrate as sole energy source, whereas in the other strains, glucose and citrate were cometabolized. Some lactobacilli strains produced aroma compounds from citrate. Citrate transport experiments suggested that all strains studied presented a citrate transport system inducible by citrate. The levels of induction were variable between several strains. Dot blot experiment showed that lactobacilli do not present an equivalent plasmid coding for citrate permease.     

Citrate permease gene expression in Lactococcus lactis subsp. lactis strains IL1403 and MG1363

Abstract Citrate permease gene expression in the plasmid-free Lactococcus lactis strains IL1403 and MG1363 was studied. The ability to transport citrate results in diacetyl and acetoin production in IL1403 but not in MG1363. Citrate lyase, α-acetolactate decarboxylase, diacetyl and acetoin reductase were detected in IL1403. These data show that L. lactis ssp. lactis strain IL1403 is a citrate permease mutant of the biovar. diacetylactis . Immunological analysis revealed the α-and β-subunits of citrate lyase not only in IL1403 but also in MG1363 where no citrate lyase activity was found.     

Citrate metabolism by Enterococcus faecium and Enterococcus durans isolated from goat's and ewe's milk: influence of glucose and lactose

Citrate metabolism by Enterococcus faecium ET C9 and Enterococcus durans Ov 421 was studied as sole energy source and in presence of glucose or lactose. Both strains utilized citrate as the sole energy source. Enterococcus faecium ET C9 showed diauxic growth in the presence of a limiting concentration of glucose. Neither strain used citrate until glucose was fully metabolized. The strains showed co-metabolism of citrate and lactose. Lactate, acetate, formate, and flavour compounds (diacetyl, acetoin, and 2,3-butanediol) were detected in both strains. The highest production of flavour compounds was detected during growth of E. durans Ov 421 in media supplemented with citrate-glucose and citrate-lactose. Citrate lyase was inducible in both strains. Acetate kinase activities presented the highest values in LAPTc medium, with E. faecium ET C9 displaying a specific activity 2.4-fold higher than E. durans. The highest levels of alpha-acetolactate synthase specific activity were detected in E. durans grown in LAPTc+g, in accordance with the maximum production of flavour compounds detected in this medium. Diacetyl and acetoinreductases displayed lower specific activity values in the presence of citrate. Enterococcus faecium and E. durans displayed citrate lyase, acetate kinase, alpha-acetolactate synthase, and diacetyl and acetoin reductase activities. These enzymes are necessary for conversion of citrate to flavour compounds that are important in fermented dairy products.     

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.     

Effect of varying citrate levels on C4 compound formation and on enzyme levels in Leuconostoc mesenteroides subsp. cremoris grown in continuous culture

Summary The effects of citrate on diacetyl, acetoin and 2,3-butylene glycol (2,3-BG) production by Leuconostoc mesenteroides subsp. cremoris grown in continuous culture at pH 5.2 were studied. In glucose alone end-product production agreed with the theoretical stoichiometry. In the presence of citrate, lactate and acetate production was higher than the theoretical stoichiometry from glucose. Lactate production was constant when the initial citrate concentration was increased whereas ethanol production strongly decreased. In the absence of citrate, citrate lyase (CL) exhibited weak activity. Diacetyl reductase (DR) and acetoin reductase (AR) exhibited basal activity. When varying citrate concentrations ranging from 10 to 75 mm were added to glucose broth, DR, AR, lactate dehydrogenase, NADH oxidase and alcohol dehydrogenase decreased as the initial citrate concentration increased suggesting that they were partly repressed by citrate. In contrast, CL increased and the specific citrate utilization rate also increased in the same way, indicating no saturation of the first step of citrate metabolism. Acetate kinase (AK) was slightly higher in the presence of citrate and increased when the initial citrate concentration increased. This result was correlated with an increase of acetate from the acetyl phosphate pathway. More ATP was produced in the presence of citrate, which could explain the increase in biomass formation. Citrate bioconversion into diacetyl, acetoin and 2,3-BG increased as the initial citrate increased. Correspondence to: C. Diviès     

Genetic organization and expression of citrate permease in lactic acid bacteria

Citrate is present in many natural substrates, such as milk, vegetables and fruits, and its metabolism by lactic acid bacteria (LAB) plays an important role in food fermentation. The industrial importance of LAB stems mainly from their ability to convert carbohydrates into lactic acid and, in some species, like Lactococcus lactis and Leuconostoc mesenteroides, to produce C4 flavor compounds (diacetyl, acetoin) through citrate metabolism. Three types of genetic organization and gene locations, involving citrate metabolism, have been found in LAB. Citrate uptake is mediated by a citrate permease, which leads to a membrane potential upon electrogenic exchange of divalent citrate and monovalent lactate. The internal citrate is cleaved into acetate and oxaloacetate by a citrate lyase, and oxaloacetate is decarboxylated into pyruvate by an oxaloacetate decarboxylase, yielding a pH gradient through the consumption of scalar protons.     

Nucleoside deoxyribosyltransferase and inosine phosphorylase activity in lactic acid bacteria

Phosphate-independent nucleoside deoxyribosyltransferase activity was detected in Aerococcus viridans, Leuconostoc mesenteroides, two species of Pediococcus, eight obligately homofermentative and three obligately heterofermentative lactobacilli. In cellfree extracts of one strain of Lactococcus, one strain of Streptococcus and three strains of facultatively heterofermentative lactobacilli no phosphate-independent nucleoside deoxyribosyltransferase could be detected and inosine nucleoside phosphorylase was the only enzyme catalysing pentosyl transfer to purines. A classification based on the presence or absence of these enzymes separates Streptococcus and Lactococcus from the remaining genera which is in agreement with studies using anti-aldolase sera and 16S rRNA oligonucleotide catalogues.Abbreviations NCIMB National Collection of Industrial and Marine bacteria - NCDO National Collection of Dairy organisms - MRS deMan Rogosa Sharpe - Pipes Piperazine-N,N-bis[2-ethanesulphonic acid]     

Citrate metabolism in 16 Leuconostoc mesenteroides subsp. mesenteroides and subsp. dextranicum strains

Citrate metabolism was studied in non-growing cells of Leuconostoc mesenteroides subsp. mesenteroides and subsp. dextranicum with respect to energetics, formation of degradation products and stoichiometry. The use of selective ionophores and uncoupler showed that citrate utilization was coupled to the proton motive force generated by ATP hydrolysis. Differences in citrate metabolism observed in 20 Leuconostoc strains were related to strains but not to the species or subspecies studied. Citrate metabolism was stimulated by glucose up to a concentration of 25 mmol 1^-1 and decreased at higher concentrations. The main degradation products resulting from the co-metabolism of citrate (10 mmol 1^-1) and glucose (2 mmol 1^-1) were acetate, lactate and pyruvate. Only four Leuconostoc strains produced low levels of acetoin and diacetyl. No strains produced ethanol or acetaldehyde. Citrate degradation ability was stable for at least 130 generations in 81% of the Leuconostoc strains.     

Genetic manipulation of the pathway for diacetyl metabolism in Lactococcus lactis.

Diacetyl is an important food flavor compound produced by certain strains of citrate-metabolizing lactic acid bacteria. Citrate is converted to pyruvate, from which diacetyl is produced via intermediate alpha-acetolactate. This paper reports the cloning and analysis of the gene (aldB) encoding alpha-acetolactate decarboxylase from Lactococcus lactis MG1363. Deletion of the MG1363 chromosomal aldB gene was achieved by double crossover homologous recombination. The mutant strain was found to produce diacetyl; alpha-acetolactate decarboxylase activity was eliminated. Overexpression of the cloned ilvBN genes (encoding an alpha-acetolactate synthase) in the aldB deletion strain produced even higher levels of alpha-acetolactate, acetoin, and diacetyl.     

Transformation of Citric Acid to Acetic Acid,Acetoin and Diacetyl by Wine Making Lactic Acid Bacteria

A decrease in citric acid and increases in acetic acid, acetoin and diacetyl were found in the test red wine after inoculation of intact cells of Leuconostoc mesenteroides subsp. lactosum ATCC 27307. a malo-lactic bacterium, grown on the malate plus citrate-medium. Citric acid in the buffer solution was transformed to acetic acid, acetoin and diacetyl in the pH range of 2 to 6 after inoculation with intact cells of this bacterial species. It was concluded that citric acid in wine making involving malolactic fermentation, at first, was converted by citrate lyase to acetic and oxaloacetic acids, and the latter was successively transformed by decarboxylation to pyruvic acid which was subsequently converted to acetoin, diacetyl and acetic acid.

Both the activities of citrate lyase and acetoin formation from pyruvic acid in the dialyzed cell-free extract were optimal at pH 6.0. Divalent cations such as Mn²⁺, Mg²⁺, Co²⁺ and Zn²⁺ activated the citrate lyase. The citrate lyase was completely inhibited by EDTA, Hg²⁺ and Ag²⁺ . The acetoin formation from pyruvic acid was significantly stimulated by thiamine pyrophosphate and CoCl₂, and inhibited by oxaloacetic acid. Specific activities of the citrate lyase and acetoin formation were considerably variable among the six strains of malo-lactic bacteria examined. Some activities of irreversible reduction of diacetyl to acetoin were found in the cell-free extracts of four of the malo-lactic bacteria strains and the optimal pH was 6.0 for this activity of Leu. mesenteroides.     

Nicotinamide adenine dinucleotide-dependent and nicotinamide adenine dinucleotide-independent lactate dehydrogenases in homofermentative and heterofermentative lactic acid bacteria

Three homofermentative (Lactobacillus plantarum B38, L. plantarum B33, Pediococcus pentosaceus B30) and three heterofermentative (Leuconostoc mesenteroides 39, L. oenos B70, Lactobacillus brevis) lactic acid bacteria were examined for the presence or absence of nicotinamide adenine dinucleotide (NAD)-dependent and NAD-independent d- and l-lactate dehydrogenases. Two of the six strains investigated, P. pentosaceus and L. oenos, did not exhibit an NAD-independent enzyme activity capable of reducing dichlorophenol indophenol. The pH optima of the lactic dehydrogenases were determined. The NAD-dependent enzymes from homofermentative strains exhibited optima at pH 7.8 to 8.8, whereas values from 9.0 to 10.0 were noted for these enzymes from heterofermentative organisms. The optima for the NAD-independent enzymes were between 5.8 and 6.6. The apparent Michaelis-Menten constants determined for both NAD and the substrates demonstrated the existence of a greater affinity for d- than l-lactic acid. A comparison of the specific NAD-dependent and NAD-independent lactate dehydrogenase activities revealed a direct correlation of the d/l ratios of these activities with the type of lactic acid produced during the growth of the organism.     

Influence of citrate on the diacetyl and acetoin production by fully grown cells ofStreptococcus lactis subsp.diacetylactis

The effects of citrate on diacetyl and acetoin level by fully grown cells ofStreptococcus lactis subsp.diacetylactis CNRZ 124 were studied. In the absence of citrate, diacetyl synthase as well as acetolactate synthase and acetoin and diacetyl reductases exhibited a basal activity confirming their constitutive nature. However, when initial citrate concentration ranged from 8.8 to 59 mM, the enzyme levels increased in the same way, indicating no saturation rate of citrate metabolism. These results were reflected by a similar enhancement in acetoin and diacetyl production. When citrate was added in fed-batch conditions, its utilization by the fully grown cells led to a twofold increase in diacetyl yield over batch conditions.     

Pressure measurement to evaluate ethanol or lactic acid production during glucose fermentation by yeast or heterofermentative bacteria in pure and mixed culture

A rapid and simple technique to follow CO2 release during fermentation of glucose by heterofermentative bacteria or yeasts was used in order to evaluate ethanol and lactate production in pure and mixed cultures of yeast and bacteria. In pure cultures, good correlations were found between gas pressure variations (deltaP) and ethanol or lactate production by yeasts or heterofermentative bacteria, and ratios between deltaP and ethanol or lactate produced could be established. In mixed cultures, ratios between maximal deltaP and total amount of glucose consumed were determined. It was thus possible to evaluate the amount of glucose that was consumed by each strain and then deduce the bacterial lactate production. Good results were obtained for mixed cultures of yeast and homofermentative bacteria. This technique may be useful to evaluate the activity of strains in mixed cultures of yeast and lactic acid bacteria.     

Characterization of intestinal lactobacilli as putative probiotic candidates

AIMS: To use antioxidative activity and antagonistic properties of lactobacilli against selected pathogens and members of the normal microflora as a basis for screening probiotic candidates. METHODS AND RESULTS: Antagonistic activity of lactobacilli against target bacteria in both microaerobic and anaerobic environments was tested. Production of antagonistic metabolites (ethanol, hydrogen peroxide (H2O2), acetic, lactic and succinic acid) by lactobacilli as well as their total antioxidative activity were assessed. In general, the lactobacilli tested were most effective against Gram-negative bacteria and their antagonistic activity was strain-specific. However, obligately heterofermentative lactobacilli had the strongest activity when tested in a microaerobic environment. Additionally, facultatively heterofermentative lactobacilli were equally effective in either milieu and produced significant levels of acetic and lactic acid. Moreover, obligately homofermentative lactobacilli had high H2O2 production and total antioxidative activity but weak antagonistic activity. CONCLUSIONS: Antioxidative and antagonistic activity of intestinal lactobacilli is strain-specific but typically can be related to their fermentation type which may be used for rapidly screening large numbers of lactobacilli for probiotic candidates. SIGNIFICANCE AND IMPACT OF THE STUDY: This study represents the first report on the utilization of group characteristics to screen lactobacilli intended for specific probiotic use. Such uses include the targeting of particular gut niches and pathogens as well as allowing for long-term benefits to the host.     

Cometabolism of Citrate and Glucose by Enterococcus faecium FAIR-E 198 in the Absence of Cellular Growth

Citrate metabolism by Enterococcus faecium FAIR-E 198, an isolate from Greek Feta cheese, was studied in modified MRS (mMRS) medium under different pH conditions and glucose and citrate concentrations. In the absence of glucose, this strain was able to metabolize citrate in a pH range from constant pH 5.0 to 7.0. At a constant pH 8.0, no citrate was metabolized, although growth took place. The main end products of citrate metabolism were acetate, formate, acetoin, and carbon dioxide, whereas ethanol and diacetyl were present in smaller amounts. In the presence of glucose, citrate was cometabolized, but it did not contribute to growth. Also, more acetate and less acetoin were formed compared to growth in mMRS medium and in the absence of glucose. Most of the citrate was consumed during the stationary phase, indicating that energy generated by citrate metabolism was used for maintenance. Experiments with cell-free fermented mMRS medium indicated that E. faecium FAIR-E 198 was able to metabolize another energy source present in the medium.     

Influence of temperature on flavour compound production from citrate by Lactobacillus rhamnosus ATCC 7469

The citrate utilization by Lactobacillus rhamnosus ATCC 7469 was found to be temperature-dependent. The maximum citrate utilization and incorporation of [1,5-14C]citrate rate were observed at 37 degreesC. At this temperature, maximum citrate lyase activity and specific diacetyl and acetoin production (Y(DA%)) were observed. The high levels of alpha-acetolactate synthase and low levels of diacetyl reductase, acetoin reductase and L-lactate dehydrogenase found at 37 degreesC led to an accumulation of diacetyl and acetoin. Optimum lactic acid production was observed at 45 degreesC, according to the high lactate dehydrogenase activity. The NADH oxidase activity increased with increasing culture temperature from 22 degreesC to 37 degreesC. Thus there are greater quantities of pyruvate available for the production of alpha-acetolactate, diacetyl and aceotin, and less diacetyl and acetoin are reduced.